R123

Carrasco S et al., Cross-linkable linear copolymer with double functionality: resist for electron beam nanolithography and molecular imprinting.
Journal of Materials Chemistry C, 2, (8), 1400-1403, (2014)
   

R123

Urraca JL et al., Molecular recognition with nanostructures fabricated by photopolymerization within metallic subwavelength apertures.
Nanoscale, 6, (15), 8656-8663, (2014)
   

R1

Hou SY et al., Multi-templates Molecularly Imprinted Polymer for the Specific Solid-Phase Extraction of Saponins from Panax notoginseng Herbal Extract.
Current Pharmaceutical Analysis, 11, (4), 292-299, (2015)
   

R1

Sun CH et al., The Multi-Template Molecularly Imprinted Polymer Based on SBA-15 for Selective Separation and Determination of Panax notoginseng Saponins Simultaneously in Biological Samples.
Polymers, 9, (12), ArticleNo653-(2017)
   

R123

Urraca JL et al., Magnetic Field-Induced Polymerization of Molecularly Imprinted Polymers.
The Journal of Physical Chemistry C, 122, (18), 10189-10196, (2018)
   

RA

Alipour S et al., Determination of Rosmarinic acid in plant extracts using a modified sensor based on magnetic imprinted polymeric nanostructures.
Sensors and Actuators B: Chemical, 323, Article128668-(2020)
   

RA

Saad EM et al., Molecularly imprinted polymers for selective extraction of rosmarinic acid from Rosmarinus officinalis L.
Food Chemistry, 335, Article127644-(2021)
   

RA

Zahara S et al., Molecular imprinting-based extraction of rosmarinic acid from Salvia hypoleuca extract.
Reactive and Functional Polymers, 166, Article104984-(2021)
   

rabbit adipose derived mesenchymal stem cells

Mahmoudi M et al., Cell-Imprinted Substrates Direct the Fate of Stem Cells.
ACS Nano, 7, (10), 8379-8384, (2013)
   

rabbit immunoglobulin

Mohapatra S et al., Fabrication of flexible and economical plasmonic biosensor using gold nanograting imprinted on hot-melt adhesive film for label-free sensing of immunoglobulin proteins.
Sensors and Actuators B: Chemical, 301, Article127070-(2019)
   

RAC

Wang S et al., Molecularly imprinted polymer for the determination of trace ractopamine in pork using SPE followed by HPLC with fluorescence detection.
Journal of Separation Science, 32, (9), 1333-1339, (2009)
   

RAC

Fang GZ et al., Substitution of Antibody with Molecularly Imprinted Film in Enzyme-Linked Immunosorbent Assay for Determination of Trace Ractopamine in Urine and Pork Samples.
Food Analytical Methods, 4, (4), 590-597, (2011)
   

RAC

Tang YW et al., Covalent imprinted polymer for selective and rapid enrichment of ractopamine by a noncovalent approach.
Analytical and Bioanalytical Chemistry, 401, (7), 2275-2282, (2011)
   

RAC

Zhang QJ et al., Molecularly imprinted solid-phase extraction for the selective HPLC determination of ractopamine in pig urine.
Journal of Separation Science, 34, (23), 3399-3409, (2011)
   

RAC

Huang Y et al., Molecularly-imprinted solid phase extraction coupled with high performance liquid chromatography for the determination of ractopamine in feed samples.
Chinese Journal of Chromatography, 30, (1), 56-61, (2012)
   

RAC

Kong LJ et al., An electrochemical sensor for rapid determination of ractopamine based on a molecularly imprinted electrosynthesized o-aminothiophenol film.
Analytical and Bioanalytical Chemistry, 404, (6), 1653-1660, (2012)
   

RAC

Wang S et al., Determination of ractopamine in pork by using electrochemiluminescence inhibition method combined with molecularly imprinted stir bar sorptive extraction.
Journal of Electroanalytical Chemistry, 664, (1), 146-151, (2012)
   

RAC

Zhang HC et al., A Novel Electrochemical Sensor Based on Molecularly Imprinted Solid-Phase Extraction for Rapid Determination of Ractopamine in Pig Urine.
Analytical Letters, 45, (12), 1736-1748, (2012)
   

RAC

Du W et al., Dummy-template molecularly imprinted solid phase extraction for selective analysis of ractopamine in pork.
Food Chemistry, 139, (1-4), 24-30, (2013)
   

RAC

Liu HL et al., A novel dual-function molecularly imprinted polymer on CdTe/ZnS quantum dots for highly selective and sensitive determination of ractopamine.
Analytica Chimica Acta, 762, 76-82, (2013)
   

RAC

Tang YZ et al., Preparation of ractopamine molecularly imprinted polymers and its chromatographic characterization.
Chinese Journal of Analysis Laboratory, 32, (5), 15-19, (2013)
   

RAC

Wang PL et al., Synthesis of ractopamine molecularly imprinted membrane and its application in the rapid determination of three β-agonists in porcine urine samples.
Journal of Separation Science, 36, (8), 1455-1462, (2013)
   

RAC

Kong LJ et al., Molecularly imprinted quartz crystal microbalance sensor based on poly(o-aminothiophenol) membrane and Au nanoparticles for ractopamine determination.
Biosensors and Bioelectronics, 51, 286-292, (2014)
   

RAC

Lei RL et al., A Novel Electrochemical Sensor for β2-Agonists with High Sensitivity and Selectivity Based on Surface Molecularly Imprinted Sol-gel Doped with Antimony-Doped Tin Oxide.
Electroanalysis, 26, (5), 1004-1012, (2014)
   

RAC

Liu HL et al., Molecularly imprinted optosensing material based on hydrophobic CdSe quantum dots via a reverse microemulsion for specific recognition of ractopamine.
Biosensors and Bioelectronics, 55, 127-132, (2014)
   

RAC

Li TF et al., Electrochemical detection of ractopamine based on a molecularly imprinted poly-o-phenylenediamine/gold nanoparticle-ionic liquid-graphene film modified glass carbon electrode.
RSC Advances, 6, (71), 66949-66956, (2016)
   

RAC

Liu YX et al., The detection method for small molecules coupled with a molecularly imprinted polymer/quantum dot chip using a home-built optical system.
Analytical and Bioanalytical Chemistry, 408, (19), 5261-5268, (2016)
   

RAC

Ma M et al., A disposable molecularly imprinted electrochemical sensor based on screen-printed electrode modified with ordered mesoporous carbon and gold nanoparticles for determination of ractopamine.
Journal of Electroanalytical Chemistry, 775, 171-178, (2016)
   

RAC

Tang YW et al., Determination of ractopamine in pork using a magnetic molecularly imprinted polymer as adsorbent followed by HPLC.
Food Chemistry, 201, 72-79, (2016)
   

RAC

Wang PL et al., An aptamer based assay for the β-adrenergic agonist ractopamine based on aggregation of gold nanoparticles in combination with a molecularly imprinted polymer.
Microchimica Acta, 183, (11), 2899-2905, (2016)
   

RAC

Yao T et al., Enhancement of surface plasmon resonance signals using a MIP/GNPs/rGO nano-hybrid film for the rapid detection of ractopamine.
Biosensors and Bioelectronics, 75, 96-100, (2016)
   

RAC

Li Y et al., Electrochemical sensors based on molecularly imprinted polymers on Fe3O4/graphene modified by gold nanoparticles for highly selective and sensitive detection of trace ractopamine in water.
Analyst, 143, (21), 5094-5102, (2018)
   

RAC

Pan MF et al., Reproducible Molecularly Imprinted Piezoelectric Sensor for Accurate and Sensitive Detection of Ractopamine in Swine and Feed Products.
Sensors, 18, (6), ArticleNo1870-(2018)
   

RAC

Wu HY et al., A comprehensive theoretical study of structural optimization, interaction energies calculations and solvent effects between ractopamine and functional monomers in molecular imprinting polymers.
Polymer Bulletin, 75, (5), 1981-1996, (2018)
   

RAC

Li X et al., A high sensitivity electrochemical sensor based on a dual-template molecularly imprinted polymer for simultaneous determination of clenbuterol hydrochloride and ractopamine.
Analyst, 146, (20), 6323-6332, (2021)
   

Ract

Fiori M et al., Evaluation of two different clean-up steps, to minimise ion suppression phenomena in ion trap liquid chromatography-tandem mass spectrometry for the multi-residue analysis of β-agonists in calves urine.
Analytica Chimica Acta, 529, (1-2), 207-210, (2005)
   

RACT

Wang PL et al., Determination of β2-Agonists in Porcine Urine by Molecularly Imprinted Solid Phase Extraction Followed Ultra-Performance Liquid Chromatography-Tandem Mass Spectrometry Detection.
Analytical Letters, 46, (5), 734-744, (2013)
   

ractopamine

Fiori M et al., Evaluation of two different clean-up steps, to minimise ion suppression phenomena in ion trap liquid chromatography-tandem mass spectrometry for the multi-residue analysis of β-agonists in calves urine.
Analytica Chimica Acta, 529, (1-2), 207-210, (2005)
   

ractopamine

Kootstra PR et al., The analysis of β-agonists in bovine muscle using molecular imprinted polymers with ion trap LCMS screening.
Analytica Chimica Acta, 529, (1-2), 75-81, (2005)
   

ractopamine

Wang S et al., Molecularly imprinted polymer for the determination of trace ractopamine in pork using SPE followed by HPLC with fluorescence detection.
Journal of Separation Science, 32, (9), 1333-1339, (2009)
   

ractopamine

Hu YL et al., Investigation of ractopamine-imprinted polymer for dispersive solid-phase extraction of trace β-agonists in pig tissues.
Journal of Separation Science, 33, (13), 2017-2025, (2010)
   

ractopamine

Xu ZG et al., Investigation of ractopamine molecularly imprinted stir bar sorptive extraction and its application for trace analysis of β2-agonists in complex samples.
Journal of Chromatography A, 1217, (22), 3612-3618, (2010)
   

ractopamine

Fang GZ et al., Substitution of Antibody with Molecularly Imprinted Film in Enzyme-Linked Immunosorbent Assay for Determination of Trace Ractopamine in Urine and Pork Samples.
Food Analytical Methods, 4, (4), 590-597, (2011)
   

ractopamine

He JX et al., Preparation, characterization and application of organic-inorganic hybrid ractopamine multi-template molecularly imprinted capillary monolithic column.
Analytica Chimica Acta, 692, (1-2), 57-62, (2011)
   

ractopamine

Hu YL et al., Magnetic molecularly imprinted polymer beads prepared by microwave heating for selective enrichment of β-agonists in pork and pig liver samples.
Talanta, 84, (2), 462-470, (2011)
   

ractopamine

Tang YW et al., Covalent imprinted polymer for selective and rapid enrichment of ractopamine by a noncovalent approach.
Analytical and Bioanalytical Chemistry, 401, (7), 2275-2282, (2011)
   

ractopamine

Zhang QJ et al., Molecularly imprinted solid-phase extraction for the selective HPLC determination of ractopamine in pig urine.
Journal of Separation Science, 34, (23), 3399-3409, (2011)
   

ractopamine

Huang Y et al., Molecularly-imprinted solid phase extraction coupled with high performance liquid chromatography for the determination of ractopamine in feed samples.
Chinese Journal of Chromatography, 30, (1), 56-61, (2012)
   

ractopamine

Kong LJ et al., An electrochemical sensor for rapid determination of ractopamine based on a molecularly imprinted electrosynthesized o-aminothiophenol film.
Analytical and Bioanalytical Chemistry, 404, (6), 1653-1660, (2012)
   

ractopamine

Li Y et al., Separation and enrichment of trace ractopamine in biological samples by uniformly-sized molecularly imprinted polymers.
Journal of Pharmaceutical Analysis, 2, (6), 395-402, (2012)
   

ractopamine

Wang LQ et al., Matrix Effects in Analysis of β-Agonists with LC-MS/MS: Influence of Analyte Concentration, Sample Source, and SPE Type.
Journal of Agricultural and Food Chemistry, 60, (25), 6359-6363, (2012)
   

ractopamine

Wang PL et al., Determination of Four Kinds of β-Agonists in Swine Urine by Molecularly Imprinted Solid Phase Extraction Followed Gas Chromatography Coupled Mass Spectrometry.
Chinese Journal of Analytical Chemistry, 40, (3), 470-473, (2012)
   

ractopamine

Wang S et al., Determination of ractopamine in pork by using electrochemiluminescence inhibition method combined with molecularly imprinted stir bar sorptive extraction.
Journal of Electroanalytical Chemistry, 664, (1), 146-151, (2012)
   

ractopamine

Zhang HC et al., A Conductometric Sensor Based on Screen Printed Electrode Modified with Multi-walled Carbon Nanotubes and Molecularly Imprinted Membrane for Determination of Ractopamine in Pig Urine.
Chinese Journal of Analytical Chemistry, 40, (1), 95-100, (2012)
   

ractopamine

Zhang HC et al., A Novel Electrochemical Sensor Based on Molecularly Imprinted Solid-Phase Extraction for Rapid Determination of Ractopamine in Pig Urine.
Analytical Letters, 45, (12), 1736-1748, (2012)
   

ractopamine

Zhang HC et al., A novel amperometric sensor based on screen-printed electrode modified with multi-walled carbon nanotubes and molecularly imprinted membrane for rapid determination of ractopamine in pig urine.
Sensors and Actuators B: Chemical, 168, (1), 103-110, (2012)
   

ractopamine

Cho YJ et al., Improvement of an simultaneous determination for clenbuterol and ractopamine in livestock products using LC-MS/MS.
Korean Journal of Food Science and Technology, 45, (1), 25-33, (2013)
   

ractopamine

Du W et al., Dummy-template molecularly imprinted solid phase extraction for selective analysis of ractopamine in pork.
Food Chemistry, 139, (1-4), 24-30, (2013)
   

ractopamine

Lin XY et al., A novel electrochemical sensor for the analysis of β-agonists: The poly(acid chrome blue K)/graphene oxide-nafion/glassy carbon electrode.
Journal of Hazardous Materials, 260, 508-517, (2013)
   

ractopamine

Liu HL et al., A novel dual-function molecularly imprinted polymer on CdTe/ZnS quantum dots for highly selective and sensitive determination of ractopamine.
Analytica Chimica Acta, 762, 76-82, (2013)
   

ractopamine

Tang YZ et al., Preparation of ractopamine molecularly imprinted polymers and its chromatographic characterization.
Chinese Journal of Analysis Laboratory, 32, (5), 15-19, (2013)
   

ractopamine

Wang PL et al., Synthesis of ractopamine molecularly imprinted membrane and its application in the rapid determination of three β-agonists in porcine urine samples.
Journal of Separation Science, 36, (8), 1455-1462, (2013)
   

ractopamine

Wang PL et al., Determination of β2-Agonists in Porcine Urine by Molecularly Imprinted Solid Phase Extraction Followed Ultra-Performance Liquid Chromatography-Tandem Mass Spectrometry Detection.
Analytical Letters, 46, (5), 734-744, (2013)
   

ractopamine

Wang YR et al., Preparation and Characteristic Analysis of Ractopamine Molecularly Imprinted Polymers.
Spectroscopy and Spectral Analysis, 33, (10), 2629-2632, (2013)
   

Ractopamine

Xu W et al., Electrochemical sensor based on a carbon nanotube-modified imprinted sol-gel for selective and sensitive determination of β2-agonists.
Microchimica Acta, 180, (11-12), 1005-1011, (2013)
   

ractopamine

Yang T et al., Preparation and Characterization of Ractopamine-Imprinted Material Using Surface-Molecular Imprinting Method and Its Adsorption Characteristics.
Scientia Agricultura Sinica, 46, (6), 1256-1262, (2013)
   

ractopamine

Kong LJ et al., Molecularly imprinted quartz crystal microbalance sensor based on poly(o-aminothiophenol) membrane and Au nanoparticles for ractopamine determination.
Biosensors and Bioelectronics, 51, 286-292, (2014)
   

ractopamine

Lei RL et al., A Novel Electrochemical Sensor for β2-Agonists with High Sensitivity and Selectivity Based on Surface Molecularly Imprinted Sol-gel Doped with Antimony-Doped Tin Oxide.
Electroanalysis, 26, (5), 1004-1012, (2014)
   

ractopamine

Liu HL et al., Molecularly imprinted optosensing material based on hydrophobic CdSe quantum dots via a reverse microemulsion for specific recognition of ractopamine.
Biosensors and Bioelectronics, 55, 127-132, (2014)
   

ractopamine

Mi JB et al., Determination of Clenbuterol and Ractopamine in Animal Origin Food by LC-MS/MS Based on a Restricted Access Imprinted Polymer Cartridge for Online Cleanup.
Journal of Instrumental Analysis, 33, (12), 1356-1361, (2014)
   

ractopamine

Wan DH et al., A microfluidic chip-chemiluminescence sensor based on molecular imprinted recognition for determination of ractopamine.
Journal of Food Safety and Quality, 5, (5), 1391-1397, (2014)
   

ractopamine

Wang PL et al., Sensitive detection of β-agonists in pork tissue with novel molecularly imprinted polymer extraction followed liquid chromatography coupled tandem mass spectrometry detection.
Food Chemistry, 184, 72-79, (2015)
   

ractopamine

Xiao XH et al., Rapid analysis of ractopamine in pig tissues by dummy-template imprinted solid-phase extraction coupling with surface-enhanced Raman spectroscopy.
Talanta, 138, 40-45, (2015)
   

ractopamine

Li TF et al., Electrochemical detection of ractopamine based on a molecularly imprinted poly-o-phenylenediamine/gold nanoparticle-ionic liquid-graphene film modified glass carbon electrode.
RSC Advances, 6, (71), 66949-66956, (2016)
   

Ractopamine

Liu HC et al., Magnetic molecularly imprinted polymers for the determination of β-agonist residues in milk by ultra high performance liquid chromatography with tandem mass spectrometry.
Journal of Separation Science, 39, (18), 3594-3601, (2016)
   

ractopamine

Liu YX et al., The detection method for small molecules coupled with a molecularly imprinted polymer/quantum dot chip using a home-built optical system.
Analytical and Bioanalytical Chemistry, 408, (19), 5261-5268, (2016)
   

ractopamine

Ma M et al., A disposable molecularly imprinted electrochemical sensor based on screen-printed electrode modified with ordered mesoporous carbon and gold nanoparticles for determination of ractopamine.
Journal of Electroanalytical Chemistry, 775, 171-178, (2016)
   

ractopamine

Qiu XZ et al., Fabrication of a molecularly imprinted polymer immobilized membrane with nanopores and its application in determination of β2-agonists in pork samples.
Journal of Chromatography A, 1429, 79-85, (2016)
   

ractopamine

Tang YW et al., Determination of ractopamine in pork using a magnetic molecularly imprinted polymer as adsorbent followed by HPLC.
Food Chemistry, 201, 72-79, (2016)
   

ractopamine

Wang PL et al., An aptamer based assay for the β-adrenergic agonist ractopamine based on aggregation of gold nanoparticles in combination with a molecularly imprinted polymer.
Microchimica Acta, 183, (11), 2899-2905, (2016)
   

ractopamine

Yao T et al., Enhancement of surface plasmon resonance signals using a MIP/GNPs/rGO nano-hybrid film for the rapid detection of ractopamine.
Biosensors and Bioelectronics, 75, 96-100, (2016)
   

ractopamine

Tang YW et al., Upconversion Nanoparticles Capped with Molecularly Imprinted Polymer as Fluorescence Probe for the Determination of Ractopamine in Water and Pork.
Food Analytical Methods, (2017)
   

ractopamine

Li Y et al., Electrochemical sensors based on molecularly imprinted polymers on Fe3O4/graphene modified by gold nanoparticles for highly selective and sensitive detection of trace ractopamine in water.
Analyst, 143, (21), 5094-5102, (2018)
   

ractopamine

Pan MF et al., Reproducible Molecularly Imprinted Piezoelectric Sensor for Accurate and Sensitive Detection of Ractopamine in Swine and Feed Products.
Sensors, 18, (6), ArticleNo1870-(2018)
   

ractopamine

Tang JW et al., Determination of β-Agonist Residues in Animal-Derived Food by a Liquid Chromatography-Tandem Mass Spectrometric Method Combined with Molecularly Imprinted Stir Bar Sorptive Extraction.
Journal of Analytical Methods in Chemistry, 2018, ArticleID9053561-(2018)
   

ractopamine

Wu HY et al., A comprehensive theoretical study of structural optimization, interaction energies calculations and solvent effects between ractopamine and functional monomers in molecular imprinting polymers.
Polymer Bulletin, 75, (5), 1981-1996, (2018)
   

ractopamine

Li X et al., A high sensitivity electrochemical sensor based on a dual-template molecularly imprinted polymer for simultaneous determination of clenbuterol hydrochloride and ractopamine.
Analyst, 146, (20), 6323-6332, (2021)
   

radionucleide

Bahraini N et al., Molecularly Imprinted Polymers for 90Sr Urine Bioassay.
Health Physics, 101, (2), 128-135, (2011)
   

radioyttrium

Sarabadani P et al., Ion-imprinted polymeric nanoparticles as a novel sorbent to separate radioyttrium from Sr target.
Radiochimica Acta, 101, (11), 725-731, (2013)
   

radioyttrium

Sarabadani P et al., Solid phase extraction of radioyttrium from irradiated strontium target using nanostructure ion imprinted polymer formed with 1-hydroxy-4-(prop-2-enyloxy)-9,10-anthraquinone.
Applied Radiation and Isotopes, 90, 8-14, (2014)
   

raffinose

Okutucu B et al., Molecularly imprinted polymers for separation of various sugars from human urine.
Talanta, 87, (1), 74-79, (2011)
   

raffinose

Zhang Z et al., Synthesis of dummy-template molecularly imprinted polymer adsorbents for solid phase extraction of aminoglycosides antibiotics from environmental water samples.
Talanta, 208, Article120385-(2020)
   

raffinose

Cao XL et al., Preparation of Magnetic Dummy Template Molecularly Imprinted Polymers for the Determination of Aminoglycosides Antibiotics in Milk.
Food Analytical Methods, 14, (10), 2111-2120, (2021)
   

R-aminoglutethimide

Kadhirvel P et al., Recognitive nano-thin-film composite beads for the enantiomeric resolution of the metastatic breast cancer drug aminoglutethimide.
Journal of Chromatography A, 1358, 93-101, (2014)
   

ranitidine

Rezaei B et al., Modified Au nanoparticles-imprinted sol-gel, multiwall carbon nanotubes pencil graphite electrode used as a sensor for ranitidine determination.
Materials Science and Engineering: C, 37, 113-119, (2014)
   

ranitidine hydrochloride

Wang W et al., Preparation of novel ranitidine hydrochloride electrode based on films of molecularly imprinted polymers.
Chemical Research and Application, 22, (4), 440-443, (2010)
   

rare earth ions

Li XZ et al., Evaluation of ionic imprinted polymers by electrochemical recognition of rare earth ions.
Hydrometallurgy, 87, (1-2), 63-71, (2007)
   

rare earth metals

Gao BJ et al., Study on recognition and separation of rare earth ions at picometre scale by using efficient ion-surface imprinted polymer materials.
Hydrometallurgy, 150, 83-91, (2014)
   

rare earth metals

Varshini JSC et al., Enhanced uptake of rare earth metals using surface molecular imprinted biosorbents of animal origin: Equilibrium, Kinetic and Thermodynamic studies.
International Journal of ChemTech Research, 7, (4), 1913-1919, (2015)
   

raspberry flavonoids

Proceeding, Xie YH et al, Preparation of Fe3O4 Magnetic Surface Imprinted Microspheres and the Ethyl Acetate Extract Flavonoids Raspberry Concentration of Active Ingredient Applied, 
ArticleNo06081, (2016)
   

raspberry flavonoids

Proceeding, Xie YH et al, Preparation of mixed molecularly imprinted polymer magnetic nanoparticles and its application in separation of Chinese traditional medicine, 
In: AIP Conference Proceedings, ArticleNo020209, (2017)
   

R(+)-atenolol

Iacob BC et al., Simultaneous Enantiospecific Recognition of Several β-Blocker Enantiomers Using Molecularly Imprinted Polymer-Based Electrochemical Sensor.
Analytical Chemistry, 87, (5), 2755-2763, (2015)
   

RB5

Chen AH et al., Adsorption of Remazol Black 5 from aqueous solution by the templated crosslinked-chitosans.
Journal of Hazardous Materials, 177, (1-3), 668-675, (2010)
   

Rb1

Hou SY et al., Multi-templates Molecularly Imprinted Polymer for the Specific Solid-Phase Extraction of Saponins from Panax notoginseng Herbal Extract.
Current Pharmaceutical Analysis, 11, (4), 292-299, (2015)
   

Rb1

Sun CH et al., The Multi-Template Molecularly Imprinted Polymer Based on SBA-15 for Selective Separation and Determination of Panax notoginseng Saponins Simultaneously in Biological Samples.
Polymers, 9, (12), ArticleNo653-(2017)
   

RB

Zhai HY et al., Chip-based molecularly imprinted monolithic capillary array columns coated GO/SiO2 for selective extraction and sensitive determination of rhodamine B in chili powder.
Food Chemistry, 214, 664-669, (2017)
   

RB

Hashemi SH et al., Application of response surface methodology to optimize pipette tip micro-solid phase extraction of dyes from seawater by molecularly imprinted polymer and their determination by HPLC.
Journal of the Iranian Chemical Society, 16, (12), 2613-2627, (2019)
   

RB

Parnianchi F et al., Highly selective and sensitive molecularly imprinting electrochemical sensing platform for bilirubin detection in saliva.
Microchemical Journal, 168, Article106367-(2021)
   

(5R)-5-benzylhydantoin

Zhou J et al., An acrylamide-based molecularly imprinted polymer for the efficient recognition of optical amino acid hydantoins.
Analytical Communications, 36, (6), 243-246, (1999)
   

(5R)-5-benzylhydantoin

Zhou J et al., A molecularly imprinted polymer receptor for the enantiomeric recognition of amino acid hydantoins mimicking cooperative hydrogen bonds between nucleotide bases.
Chinese Journal of Chemistry, 18, (4), 482-488, (2000)
   

5R-5-Benzylhydantoin

Wang H et al., Study of enantioselective binding and transportation properties of molecularly imprinted membrane for amino acid hydantoins.
Chemical Research and Application, 18, (3), 261-265, (2006)
   

Rb(I)

Wang YY et al., Calix[4]arenes functionalized dual-imprinted mesoporous film for the simultaneous selective recovery of lithium and rubidium.
Applied Organometallic Chemistry, 32, (10), ArticleNoe4511-(2018)
   

Rb(I)

Xu XC et al., A facile strategy toward ion-imprinted hierarchical mesoporous material via dual-template method for simultaneous selective extraction of lithium and rubidium.
Journal of Cleaner Production, 171, 264-274, (2018)
   

Rb(I)

Liu XW et al., Extraction of Rb(I) Ions from Aqueous Solution Using Novel Imprinting Materials.
Industrial & Engineering Chemistry Research, 58, (13), 5269-5279, (2019)
   

Rb(I)

Xu JC et al., Simultaneous adsorption of Li(I) and Rb(I) by dual crown ethers modified magnetic ion imprinting polymers.
Applied Organometallic Chemistry, 33, (3), Article_e4778-(2019)
   

Rb(I)

Zheng XD et al., Dual-Functional Mesoporous Films Templated by Cellulose Nanocrystals for the Selective Adsorption of Lithium and Rubidium.
Journal of Chemical & Engineering Data, 64, (3), 926-933, (2019)
   

Rb(I)

Zhou ZY et al., Facile preparation of a rubidium ion-imprinted polymer by bulk polymerization for highly efficient separation of rubidium ions from aqueous solution.
New Journal of Chemistry, 45, (21), 9582-9590, (2021)
   

(R)-1,1’-binaphthalene-2-naphthol

Dong HX et al., A surface molecularly imprinted polymer as chiral stationary phase for chiral separation of 1,1’-binaphthalene-2-naphthol racemates.
Chirality, 29, (7), 340-347, (2017)
   

(R)-(+ )-1, 1’-bi-2-naphthol

Li LH et al., Resolution of Racemic 1,1’-Bi-2-Naphthol and Its Derivatives by Molecularly Imprinted Polymers.
Chinese Journal of Chromatography, 24, (6), 574-577, (2006)
   

(R)-(+)-1,1-Bi-2-naphthol

LeJeune J et al., Analyte separation by OMNiMIPs imprinted with multiple templates.
Biosensors and Bioelectronics, 25, (3), 604-608, (2009)
   

(R)-(+)-1,1’-bi (2-naphthol)

Proceeding, Dong HX et al, Chiral resolution of racemic (±)-1,1’-Bi (2-naphthol) by use of molecularly imprinted polymers, 
In: Advanced Materials Research, Liu XH, Jiang ZY, Han JT (Eds.), 150-159, (2010)
   

RBS

Zheng LF et al., Core-shell magnetic molecularly imprinted polymers used rhodamine B hydroxyproline derivate as template combined with in situ derivatization for the specific measurement of L-hydroxyproline.
Journal of Chromatography A, 1532, 30-39, (2018)
   

RBV

Chen MN et al., Design of self-cleaning molecularly imprinted membrane with antibacterial ability for high-selectively separation of ribavirin.
Journal of Membrane Science, 642, Article119994-(2022)
   

R-BZH

Lu CY et al., Molecularly imprinted polymer with bi-functional monomers of calix arene derivative and acrylamide for selective recognition of hydantoin-based compounds.
Chemical Journal of Chinese Universities, 26, (10), 1820-1824, (2005)
   

R(+)-cathinone

Saputra A et al., Determination of Effective Functional Monomer and Solvent for R(+)-Cathinone Imprinted Polymer Using Density Functional Theory and Molecular Dynamics Simulation Approaches.
Indonesian Journal of Chemistry, 17, (3), 516-522, (2017)
   

RCT

Wang LQ et al., Matrix Effects in Analysis of β-Agonists with LC-MS/MS: Influence of Analyte Concentration, Sample Source, and SPE Type.
Journal of Agricultural and Food Chemistry, 60, (25), 6359-6363, (2012)
   

rctt-tetrakis(4-pyridyl)cyclobutane

Wu XY et al., Development of molecularly imprinted polymers as tailored templates for the solid-state [2+2] photodimerization.
Biosensors and Bioelectronics, 25, (3), 640-646, (2009)
   

RDX

Johnson-White B et al., Detection of organics using porphyrin embedded nanoporous organosilicas.
Biosensors and Bioelectronics, 22, (6), 1154-1162, (2007)
   

RDX

Riskin M et al., Imprinted Au-Nanoparticle Composites for the Ultrasensitive Surface Plasmon Resonance Detection of Hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX).
Advanced Materials, 22, (12), 1387-1391, (2010)
   

RDX

Wang J et al., Simultaneous selective extraction of nitramine explosives using molecularly imprinted polymer hollow spheres from post blast samples.
New Journal of Chemistry, 41, (3), 1129-1136, (2017)
   

RDX

Alizadeh T et al., Molecularly imprinted polymer nano-sphere/multi-walled carbon nanotube coated glassy carbon electrode as an ultra-sensitive voltammetric sensor for picomolar level determination of RDX.
Talanta, 194, 415-421, (2019)
   

RDX

Fan J et al., Colorimetric screening of nitramine explosives by molecularly imprinted photonic crystal array.
Microchemical Journal, 158, Article105143-(2020)
   

Re

Zhang W et al., Mechanism Analysis of Selective Adsorption and Specific Recognition by Molecularly Imprinted Polymers of Ginsenoside Re.
Polymers, 10, (2), ArticleNo216-(2018)
   

reactive brilliant blue KN-R

Li JX et al., Preparation and characterization of molecularly imprinted CA/PVDF blend membrane specific for reactive brilliant blue KN-R.
Membrane Science and Technology, 29, (1), 8-12, (2009)
   

Reactive Red

Kyzas GZ et al., Selective separation of basic and reactive dyes by molecularly imprinted polymers (MIPs).
Chemical Engineering Journal, 149, (1-3), 263-272, (2009)
   

recombinant human Erythropoietin

Nadim AH et al., Optimization of polydopamine imprinted polymer for label free sensitive potentiometric determination of proteins: Application to recombinant human erythropoietin sensing in different matrices.
Microchemical Journal, 167, Article106333-(2021)
   

recombinant human neutrophil gelatinase-associated lipocalin

Iskierko Z et al., Molecularly Imprinted Polymer (MIP) Film with Improved Surface Area Developed by Using Metal-Organic Framework (MOF) for Sensitive Lipocalin (NGAL) Determination.
ACS Applied Materials & Interfaces, 8, (31), 19860-19865, (2016)
   

Rectraction notice

Roy E et al., Retraction notice to Single cell imprinting on the surface of Ag-ZnO bimetallic nanoparticle modified graphene oxide sheets for targeted detection, removal and photothermal killing of E. Coli Biosensors and Bioelectronics Volume 89, Part 1, 15 March 2017, Pages 620-626.
Biosensors and Bioelectronics, 112, 216-(2018)
   

red blood cells

Lieberzeit PA et al., Softlithography in chemical sensing - Analytes from molecules to cells.
Sensors, 5, (12), 509-518, (2005)
   

red blood cells

Hayden O et al., Biomimetic ABO Blood-Group Typing.
Angewandte Chemie International Edition, 45, (16), 2626-2629, (2006)
   

red blood cells

Seifner A et al., Synthetic receptors for selectively detecting erythrocyte ABO subgroups.
Analytica Chimica Acta, 651, (2), 215-219, (2009)
   

red blood cells

Dickert FL et al., Blood Typing with Synthetic Receptors - Development of a Flow System for Continuous Measurement.
Tm-Technisches Messen, 79, (11), 509-515, (2012)
   

reduced glutathione

Proceeding, Fang G et al, Study on the interaction between glutathione and functional monomers, 
(2010)
   

reduced glutathione

Santos ACF et al., Development of magnetic nanoparticles modified with new molecularly imprinted polymer (MIPs) for selective analysis of glutathione.
Sensors and Actuators B: Chemical, 344, Article130171-(2021)
   

reducing sugars

Wang QA et al., An Electrochemical Sensor for Reducing Sugars Based on a Glassy Carbon Electrode Modified with Electropolymerized Molecularly Imprinted Poly-o-phenylenediamine Film.
Electroanalysis, 26, (7), 1612-1622, (2014)
   

REG1

Lee MH et al., Epitope recognition of peptide-imprinted polymers for Regenerating protein 1 (REG1).
Separation and Purification Technology, 192, 213-219, (2018)
   

REG1B

Lee MH et al., Polymers imprinted with three REG1B peptides for electrochemical determination of Regenerating Protein 1B, a urinary biomarker for pancreatic ductal adenocarcinoma.
Microchimica Acta, 184, (6), 1773-1780, (2017)
   

regenerating protein 1

Lee MH et al., Epitope recognition of peptide-imprinted polymers for Regenerating protein 1 (REG1).
Separation and Purification Technology, 192, 213-219, (2018)
   

regenerating protein 1B

Lee MH et al., Polymers imprinted with three REG1B peptides for electrochemical determination of Regenerating Protein 1B, a urinary biomarker for pancreatic ductal adenocarcinoma.
Microchimica Acta, 184, (6), 1773-1780, (2017)
   

Remazol Black5 dye

Chen AH et al., Adsorption of Remazol Black 5 from aqueous solution by the templated crosslinked-chitosans.
Journal of Hazardous Materials, 177, (1-3), 668-675, (2010)
   

Remazol Red 3BS

Kyzas GZ et al., Optimization of chitosan and β-cyclodextrin molecularly imprinted polymer synthesis for dye adsorption.
Carbohydrate Polymers, 91, (1), 198-208, (2013)
   

ReO4-

Zhao SY et al., Selective identification and separation of ReO4- by biomimetic flexible temperature-sensitive imprinted composite membranes.
Talanta, 235, Article122791-(2021)
   

repaglinide

Roushani M et al., Development of Electrochemical Sensor Based on Glassy Carbon Electrode Modified with a Molecularly Imprinted Copolymer and its Application for Detection of Repaglinide.
Electroanalysis, 30, (11), 2712-2718, (2018)
   

RES

Shi XZ et al., Development and characterisation of molecularly imprinted polymers based on methacrylic acid for selective recognition of drugs.
Biomaterials, 28, (25), 3741-3749, (2007)
   

RES

Xiang HY et al., Preparation of resveratrol molecularly imprinted composite membranes and its selectivity to the template.
Chinese Journal of Applied Chemistry, 26, (7), 786-790, (2009)
   

RES

Xiang HY et al., Electrochemical Sensor for trans-Resveratrol Determination Based on Indium Tin Oxide Electrode Modified with Molecularly Imprinted Self-Assembled Films.
Electroanalysis, 21, (10), 1207-1210, (2009)
   

Res

Wang DY et al., Novel electrochemical sensing platform based on integration of molecularly imprinted polymer with Au@Ag hollow nanoshell for determination of resveratrol.
Talanta, 196, 479-485, (2019)
   

reserpine

Shi XZ et al., Development and characterisation of molecularly imprinted polymers based on methacrylic acid for selective recognition of drugs.
Biomaterials, 28, (25), 3741-3749, (2007)
   

resorcinol

Urraca JL et al., Effect of the template and functional monomer on the textural properties of molecularly imprinted polymers.
Biosensors and Bioelectronics, 24, (1), 155-161, (2008)
   

resorcinol

Book chapter, Weetall HH, Electrochemical Polymerization for Preparation of Electrochemical Sensors, 
In: Handbook of Biosensors and Biochips, Marks RS, Cullen DC, Karube I, Lowe CR, Weetall HH (Eds.) Wiley: (2008)
   

resorcinol

Dubey L et al., Selective Recognition of Bifunctional Molecules by Synthetic Polymers Prepared by Covalent Molecular Imprinting.
The Open Analytical Chemistry Journal, 6, 15-21, (2012)
   

resorcinol

Qiu HM et al., A chemiluminescence array sensor based on graphene-magnetite-molecularly imprinted polymers for determination of benzenediol isomers.
Analytica Chimica Acta, 744, 75-81, (2012)
   

resorcinol

Zhang WL et al., Novel surface molecularly imprinted polymers as solid-phase extraction sorbents for selective extraction of dihydroxybenzenes from environmental water samples.
Fresenius Environmental Bulletin, 22, (8), 2324-2333, (2013)
   

resorcylic acid

Urraca JL et al., Effect of the template and functional monomer on the textural properties of molecularly imprinted polymers.
Biosensors and Bioelectronics, 24, (1), 155-161, (2008)
   

resveratrol

Xiang HY et al., Synthesis of Resveratrol Imprinted Polymer and Its Application in Separation of Active Ingredent in Polygonum cuspidatum Sieb. et Zucc. Extracts.
Chinese Journal of Applied Chemistry, 22, (7), 739-743, (2005)
   

resveratrol

Cao H et al., Evaluation of new selective molecularly imprinted polymers for the extraction of resveratrol from Polygonum cuspidatum.
Macromolecular Research, 14, (3), 324-330, (2006)
   

resveratrol

Xiang HY et al., Electrochemical Sensor for trans-Resveratrol Determination Based on Indium Tin Oxide Electrode Modified with Molecularly Imprinted Self-Assembled Films.
Electroanalysis, 21, (10), 1207-1210, (2009)
   

resveratrol

Hong MH et al., Preparation and Characterization of Resveratrol Molecularly Imprinted Polymeric Microspheres.
Natural Product Research and Development, 22, (4), 559-563, (2010)
   

resveratrol

Zhang ML et al., Preparation and Evaluation of Core-Shell Resveratrol Molecularly Imprinted Microspheres.
Chinese Journal of Analytical Chemistry, 38, (1), 129-132, (2010)
   

resveratrol

Zhang ZH et al., Novel Layer-by-layer Assembly Multi-walled Carbon Nanotube/Resveratrol Imprinted Sol-gel Electrochemical Sensor.
Acta Chimica Sinica, 68, (5), 431-436, (2010)
   

Resveratrol

Schwarz LJ et al., Preparation of molecularly imprinted polymers for the selective recognition of the bioactive polyphenol, (E)-resveratrol.
Journal of Chromatography A, 1218, (16), 2189-2195, (2011)
   

resveratrol

Schwarz LJ et al., Enrichment of (E)-Resveratrol from Peanut Byproduct with Molecularly Imprinted Polymers.
Journal of Agricultural and Food Chemistry, 59, (8), 3539-3543, (2011)
   

resveratrol

Shi ZL et al., Molecularly imprinted on-line solid-phase extraction combined with chemiluminescence for the determination of resveratrol.
Chinese Journal of Analysis Laboratory, 30, (3), 5-8, (2011)
   

resveratrol

Duan YQ et al., Preparation and Adsorption Characteristics of Resveratrol-Imprinted Polymer on Nano-Silica Surface.
Food Science, 33, (9), 6-10, (2012)
   

resveratrol

Lee MH et al., Extraction of resveratrol from polygonum cuspidatum with magnetic orcinol-imprinted poly(ethylene-co-vinyl alcohol) composite particles and their in vitro suppression of human osteogenic sarcoma (HOS) cell line.
Journal of Materials Chemistry, 22, (47), 24644-24651, (2012)
   

resveratrol

Chen FF et al., Preparation of magnetic molecularly imprinted polymer for selective recognition of resveratrol in wine.
Journal of Chromatography A, 1300, 112-118, (2013)
   

resveratrol

Hashim SNNS et al., Rapid solid-phase extraction and analysis of resveratrol and other polyphenols in red wine.
Journal of Chromatography A, 1313, 284-290, (2013)
   

resveratrol

Danylec B et al., The Application of Template Selectophores for the Preparation of Molecularly Imprinted Polymers.
Molecules, 20, (9), 17601-17613, (2015)
   

resveratrol

Mugo SM et al., An integrated carbon entrapped molecularly imprinted polymer (MIP) electrode for voltammetric detection of resveratrol in wine.
Analytical Methods, 7, (21), 9092-9099, (2015)
   

resveratrol

Qiu XZ et al., Determination of Resveratrol in Peanut Root Using Molecularly Imprinted Polymers Multiplug Filtration Clean up Column Coupled with Fluorescence Spectrometry.
Journal of Instrumental Analysis, 34, (12), 1403-1407, (2015)
   

resveratrol

Schwarz LJ et al., Microwave-assisted synthesis of resveratrol imprinted polymers with enhanced selectivity.
Analytical Methods, 7, (1), 150-154, (2015)
   

resveratrol

Luo JP et al., Determination of active ingredients in Chinese medicine Danning Tablets using dispersion solid-phase extraction by molecular imprinting nanomaterials coupled with HPLC-DAD.
Analytical Methods, 9, (17), 2585-2589, (2017)
   

resveratrol

Gomes CP et al., Preparation of Molecularly Imprinted Adsorbents with Improved Retention Capability of Polyphenols and Their Application in Continuous Separation Processes.
Chromatographia, 82, (6), 893-916, (2019)
   

resveratrol

Wang DY et al., Novel electrochemical sensing platform based on integration of molecularly imprinted polymer with Au@Ag hollow nanoshell for determination of resveratrol.
Talanta, 196, 479-485, (2019)
   

resveratrol

Wu ZL et al., Effective recovery of trans-resveratrol from the leaching solution of muscat grape pomace by developing a novel technology of foam fractionation.
Journal of Food Engineering, 241, 41-50, (2019)
   

resveratrol

Le Goff N et al., Renewable Plant Oil-Based Molecularly Imprinted Polymers as Biopesticide Delivery Systems.
ACS Sustainable Chemistry & Engineering, 8, (42), 15927-15935, (2020)
   

resveratrol

Huang SQ et al., Highly sensitive molecular imprinted voltammetric sensor for resveratrol assay in wine via polyaniline/gold nanoparticles signal enhancement and polyacrylamide recognition.
Journal of Electroanalytical Chemistry, 895, Article115455-(2021)
   

retinoic acid

Kim K et al., High-performance liquid chromatography separation characteristics of molecular-imprinted poly(methacrylic acid) microparticles prepared by suspension polymerization.
Journal of Applied Polymer Science, 96, (1), 200-212, (2005)
   

retinoids

Nam KH et al., Preparation of molecularly imprinted poly(methacrylic acid) and its HPLC separation characteristics of retinoids.
Polymer-Korea, 26, (6), 710-717, (2002)
   

retinoids

Kim K et al., High-performance liquid chromatography separation characteristics of molecular-imprinted poly(methacrylic acid) microparticles prepared by suspension polymerization.
Journal of Applied Polymer Science, 96, (1), 200-212, (2005)
   

retracted paper

Gupta R et al., Molecular imprinting in sol-gel matrix.
Biotechnology Advances, 26, (6), 533-547, (2008)
   

retraction

Keltie S, Retraction: A battle between spherical and cube-shaped Ag/AgCl nanoparticle modified imprinted polymer to achieve femtogram detection of alpha-feto protein.
Journal of Materials Chemistry B, 6, (48), 8238-8238, (2018)
   

retraction

Patra S et al., Retraction of "Removal and Recycling of Precious Rare Earth Element from Wastewater Samples Using Imprinted Magnetic Ordered Mesoporous Carbon".
ACS Sustainable Chemistry & Engineering, 6, (7), 9520-9520, (2018)
   

retraction

Patra S et al., Retraction notice to "Graphene quantum dots decorated CdS doped graphene oxide sheets in dual action mode: as initiator and platform for designing of nimesulide imprinted polymer " [BIOS 89P1 (2017) 627-635].
Biosensors and Bioelectronics, 114, 89-(2018)
   

retraction

Patra S et al., Retracted: Imprinted ZnO nanostructure-based electrochemical sensing of calcitonin: A clinical marker for medullary thyroid carcinoma.
Analytica Chimica Acta, 1023, 121-121, (2018)
   

retraction

Karfa P et al., Retraction to "A Fluorescent molecularly-imprinted polymer gate with temperature and pH as inputs for detection of alpha-fetoprotein", [Biosensors and Bioelectronics, 78 (2016) 454-463].
Biosensors and Bioelectronics, 124-125, 268-268, (2019)
   

retraction

Tiwari A et al., Retraction notice to "Detection of p53 gene point mutation using sequence-specific molecularly imprinted PoPD electrode" [Biosens. Bioelectron. 35 (1) (2012) 224-229].
Biosensors and Bioelectronics, 154, Article112076-(2020)
   

Retraction notice

Gupta R et al., Retraction notice to "Molecular imprinting in sol-gel matrix" [Biotech Adv. 26 (2008) 533-547].
Biotechnology Advances, 28, (6), 939-939, (2010)
   

retraction notice

Patra S et al., RETRACTED: Bimetallic magnetic nanoparticle as a new platform for fabrication of pyridoxine and pyridoxal-5’-phosphate imprinted polymer modified high throughput electrochemical sensor.
Biosensors and Bioelectronics, 73, 234-244, (2015)
   

retraction notice

Patra S et al., Retraction notice to "Size-specific imprinted polymer embedded carbon nanodots modified magnetic nanoparticle for specific recognition of titanium nanoparticle: The round versus round", [Biosensors and Bioelectronics, 86 (2016) 818-826].
Biosensors and Bioelectronics, 124-125, 269-(2019)
   

Review

Wang YT et al., Surface-imprinted biosensors for the detection of proteins, cancer markers and viruses.
Current Trends in Polymer Science, 18, 1-13, (2018)
   

review

Book chapter, Ahmad Ret al., Molecularly Imprinted Polymeric Nanomaterials for Environmental Analysis, 
In: Environmental Chemistry for a Sustainable World, Dasgupta N, Ranjan S, Lichtfouse E (Eds.) Springer: Cham, 143-168, (2019)
   

review

Boysen RI, Advances in the development of molecularly imprinted polymers for the separation and analysis of proteins with liquid chromatography.
Journal of Separation Science, 42, (1), 51-71, (2019)
   

Review - aanalysis of terpene indole alkaloids

Book chapter, Goldhaber-Pasillas GDet al., New Methods of Analysis and Investigation of Terpenoid Indole Alkaloids, 
In: New Light on Alkaloid Biosynthesis and Future Prospects, Giglioli-Guivarc’h N (Ed.) Academic Press: 233-272, (2013)
   

Review - ABO blood group typing methods

Mujahid A et al., Blood Group Typing: From Classical Strategies to the Application of Synthetic Antibodies Generated by Molecular Imprinting.
Sensors, 16, (1), ArticleNo51-(2016)
   

Review - acoustic (bio)sensors

Cooper MA et al., A survey of the 2001 to 2005 quartz crystal microbalance biosensor literature: applications of acoustic physics to the analysis of biomolecular interactions.
Journal of Molecular Recognition, 20, (3), 154-184, (2007)
   

Review - acoustic resonant sensors

Lucklum R et al., Acoustic microsensors - the challenge behind microgravimetry.
Analytical and Bioanalytical Chemistry, 384, (3), 667-682, (2006)
   

Review - acoustic wave sensors

Book chapter, Banica FG, Acoustic-Wave Sensors, 
In: Chemical Sensors and Biosensors, John Wiley & Sons, Ltd: 473-506, (2012)
   

Review - Adsorbents for arsenic remediation

Balouch A et al., Review: Arsenic Remediation by Synthetic and Natural Adsorbents.
Pakistan Journal of Analytical & Environmental Chemistry, 18, (1), 18-36, (2017)
   

Review - adsorbents for desulfurization of fuel

Li WL et al., Research advances in adsorption removal of aromatic sulfur-containing compounds.
Modern Chemical Industry, 26, (SUPPL. 1), 16-20, (2006)
   

Review - adsorbents for nickel(II)

Bello OS et al., Sequestering Nickel (II) Ions from Aqueous Solutions Using Various Adsorbents: A Review.
Pakistan Journal of Analytical and Environmental Chemistry, 15, (1), 1-17, (2014)
   

Review - adsorbents for PAHs

Ncube S et al., Recent advances in the adsorbents for isolation of polycyclic aromatic hydrocarbons (PAHs) from environmental sample solutions.
TrAC Trends in Analytical Chemistry, 99, 101-116, (2018)
   

Review - adsorbents for parabens

Piao CY et al., A review of the extraction and chromatographic determination methods for the analysis of parabens.
Journal of Chromatography B, 969, 139-148, (2014)
   

Review - adsorbents for perfluorinated compounds

Du ZW et al., Adsorption behavior and mechanism of perfluorinated compounds on various adsorbents - A review.
Journal of Hazardous Materials, 274, 443-454, (2014)
   

Review - Advanced polymer membranes

Ulbricht M, Advanced functional polymer membranes.
Polymer, 47, (7), 2217-2262, (2006)
   

Review - advances in chiral separation

Ali I et al., Advances in chiral separations of small peptides by capillary electrophoresis and chromatography.
Journal of Separation Science, 37, (18), 2447-2466, (2014)
   

Review - affinity-based drug delivery systems

Wang NX et al., Affinity-Based Drug Delivery.
Macromolecular Bioscience, 11, (3), 321-332, (2011)
   

Review - affinity chromatography

Zhang J et al., Advances in affinity chromatography.
Chinese Journal of Chromatography, 17, (3), 253-256, (1999)
   

Review - affinity chromatography

Book chapter, Urh Met al., Affinity Chromatography: General Methods, 
In: Guide to Protein Purification, Burgess RR, Deutscher MP (Eds.) Academic Press: 417-438, (2009)
   

Review - affinity chromatography

Hage DS et al., Pharmaceutical and biomedical applications of affinity chromatography: Recent trends and developments.
Journal of Pharmaceutical and Biomedical Analysis, 69, 93-105, (2012)
   

Review - affinity cryogels for protein depletion

Andaç M et al., Affinity-recognition-based polymeric cryogels for protein depletion studies.
RSC Advances, 4, (59), 31130-31141, (2014)
   

Review - affinity material for SPE

Haginaka J, Selectivity of affinity media in solid-phase extraction of analytes.
TrAC Trends in Analytical Chemistry, 24, (5), 407-415, (2005)
   

Review - affinity membranes

Book chapter, Saranya Ret al., Affinity Membranes for Capture of Cells and Biological Substances, 
In: Filtering Media by Electrospinning: Next Generation Membranes for Separation Applications, Focarete ML, Gualandi C, Ramakrishna S (Eds.) Springer International Publishing: Cham, 175-195, (2018)
   

Review - affinity sorbents

Piletska E et al., Rational design and development of affinity adsorbents for analytical and biopharmaceutical applications.
Journal of the Chinese Advanced Materials Society, 1, (3), 229-244, (2013)
   

Review - affinity tools

Ruigrok VJB et al., Alternative affinity tools: more attractive than antibodies?
Biochemical Journal, 436, (1), 1-13, (2011)
   

Review - alternatives to antibodies in immunoassays

Ngundi MM et al., Nonantibody-based recognition: Alternative molecules for detection of pathogens.
Expert Review of Proteomics, 3, (5), 511-524, (2006)
   

Review - analysis for estrogens in food

Adamusova H et al., Analysis of estrogens and estrogen mimics in edible matrices - A review.
Journal of Separation Science, 37, (8), 885-905, (2014)
   

Review - analysis for explosives

Brown KE et al., Advances in explosives analysis-part I: animal, chemical, ion, and mechanical methods.
Analytical and Bioanalytical Chemistry, 408, (1), 35-47, (2016)
   

Review - analysis methods for melamine

Ritota M et al., Melamine Detection in Milk and Dairy Products: Traditional Analytical Methods and Recent Developments.
Food Analytical Methods, 11, (1), 128-147, (2018)
   

Review - analysis of acidic drugs

Book chapter, Quintana JBet al., Analysis of acidic drugs by gas chromatography, 
In: Analysis, Fate and Removal of Pharmaceuticals in the Water Cycle, Petrovic M (Ed.) Elsevier: 185-218, (2007)
   

Review - analysis of β-agonists

Zhang W et al., Current advancement in analysis of β-agonists.
TrAC Trends in Analytical Chemistry, 85, (Part C), 1-16, (2016)
   

Review - Analysis of antibacterial residues in food

Marazuela MD et al., A review of novel strategies of sample preparation for the determination of antibacterial residues in foodstuffs using liquid chromatography-based analytical methods.
Analytica Chimica Acta, 645, (1-2), 5-17, (2009)
   

Review - Analysis of antibiotics in water

Book chapter, Díaz-Cruz MSet al., Analysis of antibiotics in aqueous samples, 
In: Analysis, Fate and Removal of Pharmaceuticals in the Water Cycle, Petrovic M (Ed.) Elsevier: 61-93, (2007)
   

Review - analysis of antimicrobials

Bogialli S et al., Recent applications of liquid chromatography–mass spectrometry to residue analysis of antimicrobials in food of animal origin.
Analytical and Bioanalytical Chemistry, 395, (4), 947-966, (2009)
   

Review - analysis of atypical neuroleptics

Baimeeva NV et al., Analytical Methods for the Determination of Atypical Neuroleptics (Review).
Pharmaceutical Chemistry Journal, 50, (5), 339-345, (2016)
   

Review - analysis of beta-blockers

Ma YH et al., Recent developments in chiral analysis of β-blocker drugs by capillary electromigration techniques.
Electrophoresis, 35, (23), 3345-3354, (2014)
   

Review - analysis of chemical pollutants

Liu Q et al., Nanomaterials for analysis and monitoring of emerging chemical pollutants.
TrAC Trends in Analytical Chemistry, 58, 10-22, (2014)
   

Review - analysis of chiral drugs

Izake EL, Chiral discrimination and enantioselective analysis of drugs: An overview.
Journal of Pharmaceutical Sciences, 96, (7), 1659-1676, (2007)
   

Review - analysis of chloramphenicol

Zaidi SA, Recent Advancement in Various Electrochemical and Immunosensing Strategies for Detection of Chloramphenicol.
International Journal of Electrochemical Science, 8, (7), 9936-9955, (2013)
   

Review - analysis of drugs in hair

Vogliardi S et al., Sample preparation methods for determination of drugs of abuse in hair samples: A review.
Analytica Chimica Acta, 857, 1-27, (2015)
   

Review - analysis of environmental contaminants

Book chapter, Gros Met al., Analysis of Emerging Contaminants of Municipal and Industrial Origin, 
In: Emerging Contaminants from Industrial and Municipal Waste, Barceló D, Petrovic M (Eds.) Springer: 37-104, (2008)
   

Review - analysis of environmental estrogens

Zhao MP et al., The analysis of phenolic environmental estrogens.
Chinese Journal of Analytical Chemistry, 31, (1), 103-109, (2003)
   

Review - analysis of estrogens

Ricanyova J et al., Estrogens and Their Analytics by Hyphenated Separation Techniques.
Critical Reviews in Analytical Chemistry, 39, (1), 13-31, (2009)
   

Review - analysis of estrogens in the aquatic environment

Czarny K et al., The impact of estrogens on aquatic organisms and methods for their determination.
Critical Reviews in Environmental Science and Technology, 47, (11), 909-963, (2017)
   

Review - analysis of estrogens in the environment

Book chapter, Kuster Met al., Analysis of steroid estrogens in the environment, 
In: Analysis, Fate and Removal of Pharmaceuticals in the Water Cycle, Petrovic M (Ed.) Elsevier: 219-264, (2007)
   

Review - analysis of food contaminants

Farré M et al., Analysis of emerging contaminants in food.
TrAC Trends in Analytical Chemistry, 43, 240-253, (2013)
   

Review - analysis of herbal medicines

Tang F et al., Sample preparation for analyzing traditional Chinese medicines.
TrAC Trends in Analytical Chemistry, 28, (11), 1253-1262, (2009)
   

Review - analysis of heterocyclic aromatic amines

Murkovic M, Analysis of heterocyclic aromatic amines.
Analytical and Bioanalytical Chemistry, 389, (1), 139-146, (2007)
   

Review - analysis of methylxanthines

Andreeva EYu et al., Methylxanthines: properties and determination in various objects.
Russian Chemical Reviews, 81, (5), 397-414, (2012)
   

Review - Analysis of microcystins

Singh S et al., Recent trends in development of biosensors for detection of microcystin.
Toxicon, 60, (5), 878-894, (2012)
   

Review - analysis of mycotoxins

Prieto-Simón B et al., Emerging biotools for assessment of mycotoxins in the past decade.
TrAC Trends in Analytical Chemistry, 26, (7), 689-702, (2007)
   

Review - analysis of mycotoxins

Urusov AE et al., Immunochemical methods of mycotoxin analysis (review).
Applied Biochemistry and Microbiology, 46, (3), 253-266, (2010)
   

Review - analysis of NSIADs

Olives AI et al., Isolation and quantitative methods for analysis of non-steroidal anti-inflammatory drugs.
Anti-Inflammatory and Anti-Allergy Agents in Medicinal Chemistry, 11, (1), 65-95, (2012)
   

Review - analysis of ochratoxin A

Visconti A et al., Fitness for purpose - Ochratoxin A analytical developments.
Food Additives and Contaminants, 22, (Suppl. 1), 37-44, (2005)
   

Review - analysis of organics

Farré M et al., Achievements and future trends in the analysis of emerging organic contaminants in environmental samples by mass spectrometry and bioanalytical techniques.
Journal of Chromatography A, 1259, 86-99, (2012)
   

Review - analysis of pharmaceutical residues

Book chapter, Petrovic Met al., Multi-residue analysis of pharmaceuticals using LC-tandem MS and LC-hybrid MS, 
In: Analysis, Fate and Removal of Pharmaceuticals in the Water Cycle, Petrovic M (Ed.) Elsevier: 157-183, (2007)
   

Review - analysis of phenoxy acid herbicides

Mei XY et al., Review on Analysis Methodology of Phenoxy Acid Herbicide Residues.
Food Analytical Methods, 9, (6), 1532-1561, (2016)
   

Review - analysis of phthalate esters in food

Yang JL et al., Recent advances in analysis of phthalate esters in foods.
TrAC Trends in Analytical Chemistry, 72, 10-26, (2015)
   

Review - analysis of plant hormones

Du FY et al., Analytical methods for tracing plant hormones.
Analytical and Bioanalytical Chemistry, 403, (1), 55-74, (2012)
   

Review - analysis of steroidal estrogen residues in food and the environment

Gunatilake SR et al., Recent advancements in analytical methods for the determination of steroidal estrogen residues in environmental and food matrices.
Analytical Methods, 8, (28), 5556-5568, (2016)
   

Review - analysis of steroid hormones

Aufartová J et al., Determination of steroid hormones in biological and environmental samples using green microextraction techniques: An overview.
Analytica Chimica Acta, 704, (1-2), 33-46, (2011)
   

Review - analysis of steroids

Yadav SK et al., A review on determination of steroids in biological samples exploiting nanobio-electroanalytical methods.
Analytica Chimica Acta, 762, 14-24, (2013)
   

Review - analysis of tetracylines in soil

O’Connor S et al., Analysis of tetracycline antibiotics in soil: Advances in extraction, clean-up, and quantification.
TrAC Trends in Analytical Chemistry, 26, (6), 456-465, (2007)
   

Review - analysis of trace organics in wastewater

Lindholm PC et al., Analysis of Trace Pharmaceuticals and Related Compounds in Municipal Wastewaters by Preconcentration, Chromatography, Derivatization, and Separation Methods.
BioResources, 9, (2), 3688-3732, (2014)
   

Review - analysis of urea pesticides

Book chapter, Morais Set al., Urea pesticides, 
In: Pesticides - Strategies for Pesticides Analysis, Stoytcheva M (Ed.) InTech: Rikeka, Croatia, 241-262, (2011)
   

Review - analyte-responsive hydrogels

Culver HR et al., Analyte-Responsive Hydrogels: Intelligent Materials for Biosensing and Drug Delivery.
Accounts of Chemical Research, 50, (2), 170-178, (2017)
   

Review - analytical applications of nanoparticles

Willner I et al., Electroanalytical Applications of Metallic Nanoparticles and Supramolecular Nanostructures.
Electroanalysis, 23, (1), 13-28, (2011)
   

Review - Analytical chemistry and society

Hennion MC et al., Analytical chemistry and society.
Actualité Chimique, (338-39), 55-63, (2010)
   

Review - analytical methods for giberellins

Pan CZ et al., Progress and development of analytical methods for gibberellins.
Journal of Separation Science, 40, (1), 346-360, (2017)
   

Review - anion recognition

Gimeno N et al., Anions as templates in coordination and supramolecular chemistry.
Coordination Chemistry Reviews, 250, (23-24), 3161-3189, (2006)
   

Review - application of NMR to chromatography

Uccello-Barretta G et al., Nuclear magnetic resonance approaches to the rationalization of chromatographic enantiorecognition processes.
Journal of Chromatography A, 1217, (7), 928-940, (2010)
   

Review - applications of magnetic nanoparticles

Faraji M, Recent analytical applications of magnetic nanoparticles.
Nanochemistry Research, 1, (2), 264-290, (2016)
   

Review - applications of monoliths

Svec F, Less common applications of monoliths: Preconcentration and solid-phase extraction.
Journal of Chromatography B, 841, (1-2), 52-64, (2006)
   

Review - applications of polydopamine

Liu YL et al., Polydopamine and Its Derivative Materials: Synthesis and Promising Applications in Energy, Environmental, and Biomedical Fields.
Chemical Reviews, 114, (9), 5057-5115, (2014)
   

Review - artificial antibodies in enzyme-linked assays

He YP et al., Application of Artificial Antibody in Enzyme-Linked Assay for Food Safety Detection.
Food Science, 38, (23), 313-317, (2017)
   

Review - artificial protein sensors

Schrader T et al., Artificial protein sensors.
Molecular BioSystems, 3, (4), 241-248, (2007)
   

Review - artificial receptors for ochratoxin A

Baggiani C et al., Man-Made Synthetic Receptors for Capture and Analysis of Ochratoxin A.
Toxins, 7, (10), 4083-4098, (2015)
   

Review - artificial receptors for oxidoreductase substrates

Borzenkova NV et al., Opportunities to improve selectivity of determining oxidoreductase substrate using artificial receptors.
Moscow University Chemistry Bulletin, 67, (5), 211-228, (2012)
   

Review - Artificial selenoenzymes

Huang X et al., Design of Artificial Selenoenzymes Based on Macromolecular Scaffolds.
Macromolecular Bioscience, 10, (12), 1385-1396, (2010)
   

Review - artificial selenoenzymes

Huang X et al., Artificial selenoenzymes: Designed and redesigned.
Chemical Society Reviews, 40, (3), 1171-1184, (2011)
   

Review - aryl diazonium modified surfaces

Book chapter, Gam-Derouich Set al., Polymer Grafting to Aryl Diazonium-Modified Materials: Methods and Applications, 
In: Aryl Diazonium Salts: New Coupling Agents in Polymer and Surface Science, Chehimi MM (Ed.) Wiley-VCH Verlag GmbH & Co.: 125-158, (2012)
   

Review - aryl diazonium salts as coupling agents

Mahouche-Chergui S et al., Aryl diazonium salts: a new class of coupling agents for bonding polymers, biomacromolecules and nanoparticles to surfaces.
Chemical Society Reviews, 40, (7), 4143-4166, (2011)
   

Review - assays and sensors for cyanobacterial toxins

Weller M, Immunoassays and Biosensors for the Detection of Cyanobacterial Toxins in Water.
Sensors, 13, (11), 15085-15112, (2013)
   

Review - assays for pharmaceuticals in the environment

Book chapter, Salvador JPet al., Application of bioassays/biosensors for the analysis of pharmaceuticals in environmental samples, 
In: Analysis, Fate and Removal of Pharmaceuticals in the Water Cycle, Petrovic M (Ed.) Elsevier: 279-334, (2007)
   

Review - assays for spectrometric analysis

Wu P et al., Exploration of Displacement Reaction/Sorption Strategies in Spectrometric Analysis.
Applied Spectroscopy Reviews, 48, (8), 629-653, (2013)
   

Review -- asymmetric reactions

Book chapter, Bogliotti Net al., Shape- and Site-Selective Asymmetric Reactions, 
In: Enantioselective Organocatalysis: Reactions and Experimental Procedures, Dalko PI (Ed.) Wiley-VCH Verlag GmbH & Co.: Weinheim, 425-449, (2007)
   

Review - Au nanoparticle-based MIP sensors

Book chapter, Tel-Vered Ret al., Molecularly Imprinted Au Nanoparticle Composites for Selective Sensing Applications, 
In: Designing Receptors for the Next Generation of Biosensors, Piletsky SA, Whitcombe MJ (Eds.) Springer: Berlin, Heidelberg, 189-212, (2013)
   

Review - bacterial detection

Lopez-Roldan R et al., On-line bacteriological detection in water.
TrAC Trends in Analytical Chemistry, 44, 46-57, (2013)
   

Review - binding isotherms

Book chapter, Shimizu KD, Binding isotherms, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 419-434, (2005)
   

Review - bioactive surfaces and immunity

Ekdahl KN et al., Innate immunity activation on biomaterial surfaces: A mechanistic model and coping strategies.
Advanced Drug Delivery Reviews, 63, (12), 1042-1050, (2011)
   

Review - bioactive surfaces with bacteriophage

Hosseinidoust Z et al., Going viral: Designing bioactive surfaces with bacteriophage.
Colloids and Surfaces B: Biointerfaces, 124, 2-16, (2014)
   

Review - Bioelectroanalysis of pharmaceuticals

Cavalheiro ÉTG et al., Bioelectroanalysis of pharmaceutical compounds.
Bioanalytical Reviews, 4, (1), 31-53, (2012)
   

Review - bioimprinting

Book chapter, Baggiani Cet al., Bioimprinting, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 12-25, (2006)
   

Review - bioimprinting of lipase

Dong B et al., Advances in Study on Lipase Bio-imprinting.
China Biotechnology, 26, (3), 78-82, (2006)
   

Review - biomedical applications of hyperbranched polymers

Pedrón S et al., Bioapplications of Networks Based on Photo-Cross-Linked Hyperbranched Polymers.
Macromolecular Symposia, 291-292, (1), 307-313, (2010)
   

Review - biomedical applications of virus and virus-based structures

van Rijn P et al., Viruses, Artificial Viruses and Virus-Based Structures for Biomedical Applications.
Advanced Healthcare Materials, 5, (12), 1386-1400, (2016)
   

Review - biomedical polymers

Xiao CS et al., Recent developments in intelligent biomedical polymers.
Science in China Series B: Chemistry, 52, (2), 117-130, (2009)
   

Review - biomimetic catalysis

Marchetti L et al., Biomimetic Catalysis.
ACS Catalysis, 1090-1118, (2011)
   

Review - biomimetic catalysts

Yin YZ et al., Biomimetic catalysts designed on macromolecular scaffolds.
Progress in Polymer Science, 37, (11), 1476-1509, (2012)
   

Review - biomimetic chemistry in sensors

Scognamiglio V et al., Synthetic biology and biomimetic chemistry as converging technologies fostering a new generation of smart biosensors.
Biosensors and Bioelectronics, 74, 1076-1086, (2015)
   

Review - biomimetic materials for sensing

Bajwa S et al., Nanostructured materials with biomimetic recognition abilities for chemical sensing.
Nanoscale Research Letters, 7, (1), 328-(2012)
   

Review - biomimetic materials in detection

Book chapter, Boehm RDet al., Biomimetic Materials and Surfaces in Detection, 
In: Advanced Synthetic Materials in Detection Science, Reddy SM (Ed.) The Royal Society of Chemistry: Cambridge, 26-74, (2014)
   

Review - biomimetic nanoparticles

Weber A et al., Biomimesis by Nanoparticles: Concept, Design and Applications in Biotechnology and Biomedicine.
Sitzungsberichte der Leibniz-Sozietät, 90, 157-167, (2007)
   

Review - biomimetic polymers

Book chapter, Medina DDet al., Biomimetic Polymers for Chiral Resolution and Antifreeze Applications, 
In: On Biomimetics, Pramatarova LD (Ed.) InTech: 321-354, (2011)
   

Review - biomimetic polymers at the nanoscale

Book chapter, Chiono Vet al., Biomimetic Tailoring of the Surface Properties of Polymers at the Nanoscale: Medical Applications, 
In: Scanning Probe Microscopy in Nanoscience and Nanotechnology, Volume 2, Bhushan B (Ed.) Springer: Heidelberg, 645-689, (2011)
   

Review - Biomimetic Sensors

Book chapter, Dickert FLet al., Biomimetic Sensors in Medicine and Biology - Detection of Bioparticles, 
In: IFMBE Proceedings: 5th European Conference of the International Federation for Medical and Biological Engineering, Jobbágy Á (Ed.) Springer Berlin Heidelberg: 1004-1006, (2012)
   

Review - biomimetic sensors

Dickert FL, Biomimetic Receptors and Sensors.
Sensors, 14, (12), 22525-22531, (2014)
   

Review - biomimetic systems for drug delivery

Venkatesh S et al., Applications of biomimetic systems in drug delivery.
Expert Opinion on Drug Delivery, 2, (6), 1085-1096, (2005)
   

Review - biomimetic systems in drug delivery

Sabu C et al., Bioinspired and biomimetic systems for advanced drug and gene delivery.
Journal of Controlled Release, 287, 142-155, (2018)
   

Review - biomolecule responsive hydrogels

Book chapter, Miyata T, Target Biomolecule-responsive Hydrogels, 
In: Chemoresponsive Materials: Stimulation by Chemical and Biological Signals, Schneider HJ (Ed.) The Royal Society of Chemistry: 408-443, (2015)
   

Review - biosensing with nanomaterials on cellulose paper

Ge SG et al., Nanomaterials-modified cellulose paper as a platform for biosensing applications.
Nanoscale, 9, (13), 4366-4382, (2017)
   

Review - Biosensors

Chambers JP et al., Biosensor Recognition Elements.
Current Issues in Molecular Biology, 10, (1-2), 1-12, (2008)
   

Review - biosensors

Arora RK et al., Biosensor: Way of Diagnostics.
International Journal of Pharmaceutical Sciences and Research, 4, (7), 2517-2527, (2013)
   

Review - biosensors

Hussain M et al., Biomimetic Strategies for Sensing Biological Species.
Biosensors, 3, (1), 89-107, (2013)
   

Review - biosensors

Soldatkin AP et al., Biosensors. A quarter of a century of R&D experience.
Biopolymers and Cell, 29, (3), 188-206, (2013)
   

Review - biosensors

Turner APF, Biosensors: sense and sensibility.
Chemical Society Reviews, 42, (8), 3184-3196, (2013)
   

Review - Biosensors

Book chapter, Scheller FWet al., Future of Biosensors: A Personal View, 
In: Biosensors Based on Aptamers and Enzymes, Gu MB, Kim HS (Eds.) Springer: Berlin,Heidelberg, 1-28, (2014)
   

Review - biosensors based on poly(o-aminophenol)

Tucceri R, Non-Conducting Poly(O-Aminophenol) Films in the Field of the Bioelectrochemistry.
American Journal of Analytical Chemistry, 4, 13-26, (2013)
   

Review - biosensors for antibiotics in mlk

Book chapter, Kivirand Ket al., Biosensors for the detection of antibiotic residues in milk, 
In: Biosensors - Micro and Nanoscale Applications, Rinken T (Ed.) InTech: 425-456, (2015)
   

Review - biosensors for bacteria

Templier V et al., Ligands for label-free detection of whole bacteria on biosensors: A review.
TrAC Trends in Analytical Chemistry, 79, 71-79, (2016)
   

Review - biosensors for detection of antibiotic residues

Gaudin V, Advances in biosensor development for the screening of antibiotic residues in food products of animal origin - A comprehensive review.
Biosensors and Bioelectronics, 90, 363-377, (2017)
   

Review - biosensors for detection of carcinogens in food

Li ZM et al., A review of biosensing techniques for detection of trace carcinogen contamination in food products.
Analytical and Bioanalytical Chemistry, 407, (10), 2711-2726, (2015)
   

Review - biosensors for detection of organophosphorus pesticides

Hassani S et al., Biosensors and their applications in detection of organophosphorus pesticides in the environment.
Archives of Toxicology, 91, (1), 109-130, (2017)
   

Review - biosensors for marine toxins

Campàs M et al., Biosensors to detect marine toxins: Assessing seafood safety.
Talanta, 72, (3), 884-895, (2007)
   

Review - biosensors for monitoring pesticides

Book chapter, Rapini Ret al., Biosensor Potential in Pesticide Monitoring, 
In: Biosensors for Sustainable Food - New Opportunities and Technical Challenges, Scognamiglio V, Rea G, Arduini F, Palleschi G (Eds.) Elsevier: 3-31, (2016)
   

Review - biosensors for pesticide detection

Sassolas A et al., Biosensors for Pesticide Detection: New Trends.
American Journal of Analytical Chemistry, 3, (3), 210-232, (2012)
   

Review - Biosensors for pesticides

Verma N et al., Biosensor Technology for Pesticides-A review.
Applied Biochemistry and Biotechnology, 175, (6), 3093-3119, (2015)
   

Review - biosensors for pesticides

Bansal BN et al., Biosensor Design Aspects for Pesticide Monitoring.
International Journal of Advanced Research in Electronics and Communication Engineering, 7, (4), 403-407, (2018)
   

Review - biosensors for prostate specific antigen

Damborska D et al., Nanomaterial-based biosensors for detection of prostate specific antigen.
Microchimica Acta, 184, (9), 3049-3067, (2017)
   

Review - biosensors for toxins

Bazin I et al., New biorecognition molecules in biosensors for the detection of toxins.
Biosensors and Bioelectronics, 87, 285-298, (2017)
   

Review - Biosensors in cancer diagnosis

Tothill IE, Biosensors for cancer markers diagnosis.
Seminars in Cell & Developmental Biology, 20, (1), 55-62, (2009)
   

Review - biosensors in food safety

Rotariu L et al., Electrochemical biosensors for fast detection of food contaminants - trends and perspective.
TrAC Trends in Analytical Chemistry, 79, 80-87, (2016)
   

Review - biosensors in food science

Thakur MS et al., Biosensors in food processing.
Journal of Food Science and Technology, 50, (4), 625-641, (2013)
   

Review - biosensors in medicine

Book chapter, Cherré Set al., Polymer Based Biosensors for Medical Applications, 
In: Advanced Polymers in Medicine, Puoci F (Ed.) Springer International Publishing: Heidelberg, New York, Dordrecht, London, 513-537, (2015)
   

Review - biosensors in medicine

Kozitsina AN et al., Sensors Based on Bio and Biomimetic Receptors in Medical Diagnostic, Environment, and Food Analysis.
Biosensors, 8, (2), ArticleNo35-(2018)
   

Review - bisphenol A removal

Bhatnagar A et al., Adsorptive removal of bisphenol A (BPA) from aqueous solution: A review.
Chemosphere, 168, 885-902, (2017)
   

Review - boronate affinity materials

Li DJ et al., Boronate affinity materials for separation and molecular recognition: structure, properties and applications.
Chemical Society Reviews, 44, (22), 8097-8123, (2015)
   

Review - boronate affinity materials

Liu Z et al., Synthesis and Applications of Boronate Affinity Materials: From Class Selectivity to Biomimetic Specificity.
Accounts of Chemical Research, 50, (9), 2185-2193, (2017)
   

Review - boron chemistry and nucleic acids

Martin AR et al., Boron and nucleic acid chemistries: merging the best of both worlds.
Chemical Society Reviews, 42, (13), 5684-5713, (2013)
   

Review - boronic acids in sensing

Lacina K et al., Boronic acids for sensing and other applications - a mini-review of papers published in 2013.
Chemistry Central Journal, 8, (1), Article No 60-(2014)
   

Review - boronic acids in sensing

Li M et al., Electrochemical sensing using boronic acids.
Chemical Communications, 51, (78), 14562-14573, (2015)
   

Review - boronic acids in supramolecular chemistry

Book chapter, Kanekiyo Yet al., Supramolecular Chemistry of Boronic Acids, 
In: Boron: Sensing, Synthesis and Supramolecular Self-Assembly, Li M, Fossey JS, James TD (Eds.) The Royal Society of Chemistry: Cambridge, 1-43, (2015)
   

Review - capacitive biosensors

Mattiasson B et al., Capacitive biosensors for ultra-sensitive assays.
TrAC Trends in Analytical Chemistry, 79, 233-238, (2016)
   

Review - capillary electrochromatography

Fujimoto C, Recent developments in column technology for fritless packed capillary electrochromatography.
Chromatography, 22, (3), 145-150, (2001)
   

Review - capillary electrochromatography

Lu H et al., Recent advances of enantioseparations in capillary electrophoresis and capillary electrochromatography.
Analytical Methods, 3, (3), 488-508, (2011)
   

Review - capillary electrochromatography of pharmaceuticals

Declerck S et al., Enantioseparations of pharmaceuticals with capillary electrochromatography: A review.
Journal of Pharmaceutical and Biomedical Analysis, 130, (Review Issue 2016), 81-99, (2016)
   

Review - capillary microextraction

Bagheri H et al., Recent advances in capillary microextraction.
TrAC Trends in Analytical Chemistry, 73, 64-80, (2015)
   

Review - capillary solid-phase microextraction

Queiroz MEC et al., Selective capillary coating materials for in-tube solid-phase microextraction coupled to liquid chromatography to determine drugs and biomarkers in biological samples: A review.
Analytica Chimica Acta, 826, 1-11, (2014)
   

Review - carbon dots in polymers

Zhou YQ et al., Polymers in Carbon Dots: A Review.
Polymers, 9, (2), ArticleNo67-(2017)
   

Review - carbon molecular sieves

de Oliviera EC et al., Why are carbon molecular sieves interesting?
Journal of the Brazilian Chemical Society, 17, (1), 16-29, (2006)
   

Review - carbon nanotube-based adsorbents

Liang XJ et al., Carbon-based sorbents: Carbon nanotubes.
Journal of Chromatography A, 1357, 53-67, (2014)
   

Review - carbon nanotubes in sensors

Gao C et al., The new age of carbon nanotubes: An updated review of functionalized carbon nanotubes in electrochemical sensors.
Nanoscale, 4, (6), 1948-1963, (2012)
   

Review - carbon nanotubes in separation science

Herrera-Herrera AV et al., Carbon nanotubes applications in separation science: A review.
Analytica Chimica Acta, 734, (1), 1-30, (2012)
   

Review - carbon nanotubes in SPE of metals

Herrero Latorre C et al., Carbon nanotubes as solid-phase extraction sorbents prior to atomic spectrometric determination of metal species: A review.
Analytica Chimica Acta, 749, 16-35, (2012)
   

Review - catalyst design

Corma A, Attempts to fill the gap between enzymatic, homogeneous, and heterogeneous catalysis.
Catalysis Reviews - Science and Engineering, 46, (3-4), 369-417, (2004)
   

Review - catalyst design

Kung HH et al., Synthesis Strategies to Design Structures for Catalytic Applications.
Chinese Journal of Catalysis, 29, (11), 1187-1192, (2008)
   

Review - catalysts at oxide surfaces

Tada M, Surface-mediated design and catalytic properties of active metal complexes for advanced catalysis creation.
Bulletin of the Chemical Society of Japan, 83, (8), 855-876, (2010)
   

Review - Catalysts for organic synthesis

Ikegami S et al., Novel Recycling System for Organic Synthesis via Designer Polymer-Gel Catalysts.
Chemical Reviews, 109, (2), 583-593, (2009)
   

Review - catalytic polymers in water purification

Julkapli NM et al., Polymers for catalysis in water purification.
Polymers for Advanced Technologies, 29, (2), 701-707, (2018)
   

Review - chemical sensors

Reinbold J et al., Sensors for gases, odours and organic solvent vapours.
GIT Labor-Fachzeitschrift, 42, (4), 396-400, (1998)
   

Review - chemical sensors for heavy metal ions

Jose J et al., Fabrication of Anchored Complexes as Electrodes for Sensing Heavy Metal Ions by Electrochemical Method.
Oriental Journal of Chemistry, 33, (3), 1438-1446, (2017)
   

Review - chemiluminescence-carbon nanostructures in analysis

Iranifam M, Analytical applications of chemiluminescence systems assisted by carbon nanostructures.
TrAC Trends in Analytical Chemistry, 80, 387-415, (2016)
   

Review - chemiluminescent detection systems

Iranifam M, Analytical applications of chemiluminescence-detection systems assisted by magnetic microparticles and nanoparticles.
TrAC Trends in Analytical Chemistry, 51, 51-70, (2013)
   

Review - chemiluminescent sensors

Zhang ZY et al., Recent developments and applications of chemiluminescence sensors.
Analytica Chimica Acta, 541, (1-2), 37-46, (2005)
   

Review - chemistries for SPE

Majors RE, Advanced topics in solid-phase extraction: Chemistries.
Lc Gc North America, 25, (1), 16-(2007)
   

Review - Chemomechanical polymers

Schneider HJ et al., Supramolecular Interactions in Chemomechanical Polymers.
Accounts of Chemical Research, 42, (10), 1489-1500, (2009)
   

Review - chiral affinity membranes

Zhang GJ et al., Chiral separation with affinity membrane technology and chiral selective solid membrane.
Chemical Industry and Engineering Progress, 27, (6), 797-803, (2008)
   

Review - chiral analysis

Trojanowicz M et al., Flow methods in chiral analysis.
Analytica Chimica Acta, 801, 59-69, (2013)
   

Review - chiral analysis by QCM

Guo HS, Progress of Quartz Crystal Microbalance in Chiral Analysis.
Journal of Nanoscience and Nanotechnology, 14, (2), 1884-1897, (2014)
   

Review - chiral CEC

Book chapter, Zheng Jet al., Chiral Analysis in Capillary Electrochromatography (CEC) and CEC Coupled to Mass Spectrometry, 
In: Chiral Separation Techniques, Subramanian G (Ed.) WILEY-VCH Verlag GmbH & Co.: Weinheim, 441-504, (2007)
   

Review - chiral chromatography

Tang Y et al., Application of chiral selectors in chromatographic analysis.
Journal of Analytical Science, 17, (4), 327-333, (2001)
   

Review - chiral chromatography

Gübitz G et al., Chiral separation principles in chromatographic and electromigration techniques.
Molecular Biotechnology, 32, (2), 159-179, (2006)
   

Review - chiral chromatography

Asnin L, Adsorption models in chiral chromatography.
Journal of Chromatography A, 1269, 3-25, (2012)
   

Review - chiral chromatography

Tang ML et al., Development of chiral stationary phases for high-performance liquid chromatographic separation.
TrAC Trends in Analytical Chemistry, 39, 180-194, (2012)
   

Review - Chiral chromatography with poysaccharides

Ikai T et al., Structure Control of Polysaccharide Derivatives for Efficient Separation of Enantiomers by Chromatography.
Chemical Reviews, 109, (11), 6077-6101, (2009)
   

Review - chiral HPLC

Cavazzini A et al., Recent applications in chiral high performance liquid chromatography: A review.
Analytica Chimica Acta, 706, (2), 205-222, (2011)
   

Review - chiral imprinting in silica

Book chapter, Levi G, Imprinting Chirality in Mesoporous Silica Structures, 
In: Advanced Topics in Crystallization, Mastai Y (Ed.) Intech Open: (2015)
   

Review - chiral mesoporous silicas

Qiu HB et al., Chiral mesoporous silica: Chiral construction and imprinting via cooperative self-assembly of amphiphiles and silica precursors.
Chemical Society Reviews, 40, (3), 1259-1268, (2011)
   

Review - chiral metal surfaces

Wattanakit C, Chiral metals as electrodes.
Current Opinion in Electrochemistry, 7, 54-60, (2018)
   

Review - chiral nanotechnology

Zhang J et al., Chiral nanotechnology.
Chirality, 17, (7), 404-418, (2005)
   

Review - chiral polymers in enantioseparation

Shen J et al., Efficient Separation of Enantiomers Using Stereoregular Chiral Polymers.
Chemical Reviews, 116, (3), 1094-1138, (2016)
   

Review - chiral sensing

Ariga K et al., Intelligent Chiral Sensing Based on Supramolecular and Interfacial Concepts.
Sensors, 10, (7), 6796-6820, (2010)
   

Review - chiral sensors and biosensors

Trojanowicz M et al., Electrochemical Chiral Sensors and Biosensors.
Electroanalysis, 21, (3-5), 229-238, (2009)
   

Review - chiral separation

Scriba GKE, Chiral recognition in separation science - an update.
Journal of Chromatography A, 1467, 56-78, (2016)
   

Review - chiral separation in capillary electromigration

Gübitz G et al., Chiral separation by capillary electromigration techniques.
Journal of Chromatography A, 1204, (2), 140-156, (2008)
   

Review - chiral separation mechanisms

Scriba GKE, Chiral Recognition Mechanisms in Analytical Separation Sciences.
Chromatographia, 75, (15), 815-838, (2012)
   

Review - chiral separations

Book chapter, Wang XDet al., Chiral separations, 
In: Separation Science and Technology: HPLC Method Development for Pharmaceuticals, Ahuja S, Rasmussen H (Eds.) Academic Press: 111-144, (2007)
   

Review - chiral separations

Ward TJ et al., Chiral Separations: Fundamental Review 2010.
Analytical Chemistry, 82, (12), 4712-4722, (2010)
   

Review - chiral separations

Ward TJ et al., Chiral Separations: A Review of Current Topics and Trends.
Analytical Chemistry, 84, (2), 626-635, (2012)
   

Review - chiral silica-based monoliths for separations

Wistuba D, Chiral silica-based monoliths in chromatography and capillary electrochromatography.
Journal of Chromatography A, 1217, (7), 941-952, (2010)
   

Review - chiral sol-gels

Marx S et al., The Induction of Chirality in Sol-Gel Materials.
Accounts of Chemical Research, 40, (9), 768-776, (2007)
   

Review - chiral stationary phases

Ravelet C et al., Recent developments in the HPLC enantiomeric separation using chiral selectors identified by a combinatorial strategy.
Journal of Separation Science, 29, (10), 1322-1331, (2006)
   

Review - chiral stationary phases

Lourenco TD et al., Chiral Stationary Phases for High-Performance Liquid Chromatography.
Quimica Nova, 33, (10), 2155-2164, (2010)
   

Review - chiral stationary phases

Gus’kov VY et al., New Chiral Stationary Phases: Preparation, Properties, and Applications in Gas Chromatography.
Journal of Analytical Chemistry, 73, (10), 937-945, (2018)
   

Review - chiral supercritical fluid chromatography

Kaláková K et al., Supercritical fluid chromatography as a tool for enantioselective separation; A review.
Analytica Chimica Acta, 821, 1-33, (2014)
   

Review - chiral supercritical fluid chromatography

Plotka JM et al., Pharmaceutical and forensic drug applications of chiral supercritical fluid chromatography.
TrAC Trends in Analytical Chemistry, 56, 74-89, (2014)
   

Review - chitin and chitosan

Aranaz I et al., Functional characterization of chitin and chitosan.
Current Chemical Biology, 3, (2), 203-230, (2009)
   

Review - chitosan-based adsorbents

Liu BJ et al., Adsorption of heavy metal ions, dyes and proteins by chitosan composites and derivatives - A review.
Journal of Ocean University of China, 12, (3), 500-508, (2013)
   

Review - chitosan-based adsorbents

Liu CK et al., Recent advances in chitosan and its derivatives as adsorbents for removal of pollutants from water and wastewater.
Current Opinion in Chemical Engineering, 4, 62-70, (2014)
   

Review - chitosan-based hydrogels in water treatment

Mohammadzadeh Pakdel P et al., Review on recent progress in chitosan-based hydrogels for wastewater treatment application.
Carbohydrate Polymers, 201, 264-279, (2018)
   

Review - chlorogenic acids

Upadhyay R et al., An Outlook on Chlorogenic Acids - Occurrence, Chemistry, Technology, and Biological Activities.
Critical Reviews in Food Science and Nutrition, 53, (9), 968-984, (2012)
   

Review - cholesterol removal with β-cyclodextrin

Jiang HM et al., Removal of Cholesterol by β-Cyclodextrin.
Asian Journal of Chemistry, 23, (9), 3783-3786, (2011)
   

Review - chromatographic techniques

Book chapter, Baggiani C, Chromatographic techniques, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 517-552, (2005)
   

Review - chromatography

Majors RE, Shaping the future: Part 2.
The Column, 3, (6), 26-30, (2007)
   

Review - chromatography and sample preparation

Nováková L et al., A review of current trends and advances in modern bio-analytical methods: Chromatography and sample preparation.
Analytica Chimica Acta, 656, (1-2), 8-35, (2009)
   

Review - combinatorial chemistry in artificial receptor selection

Book chapter, Díaz-García MEet al., Combinatorial Chemistry for Optical Sensing Applications, 
In: Combinatorial Methods for Chemical and Biological Sensors, Potyrailo RA, Mirsky VM (Eds.) Springer: New York, 373-391, (2009)
   

Review - combinatorial methods in the synthesis of molecular recognition materials

Díaz-García ME et al., Combinatorial solid-phase organic synthesis for developing materials with molecular recognition properties.
TrAC Trends in Analytical Chemistry, 25, (2), 112-121, (2006)
   

Review - combinatorial polyeric sensor materials

Potyrailo RA, Polymeric sensor materials: Toward an alliance of combinatorial and rational design tools?
Angewandte Chemie International Edition, 45, (5), 702-723, (2006)
   

Review - computational design of MIPs

Book chapter, Subrahmanyam Set al., Computational Approaches in the Design of Synthetic Receptors, 
In: Designing Receptors for the Next Generation of Biosensors, Piletsky SA, Whitcombe MJ (Eds.) Springer: Berlin, Heidelberg, 131-165, (2013)
   

Review - conducting polymer coatings in microextraction

Szultka-Mlynska M et al., Nanoporous Conducting Polymer-Based Coatings in Microextraction Techniques for Environmental and Biomedical Applications.
Critical Reviews in Analytical Chemistry, 46, (3), 236-247, (2016)
   

review - conducting polymers

Anantha-Iyengar G et al., Functionalized conjugated polymers for sensing and molecular imprinting applications.
Progress in Polymer Science, 88, 1-129, (2019)
   

Review - conducting polymers in analysis

Book chapter, El Kaoutit M, Application of Conducting Polymers in Electroanalysis, 
In: Aspects on Fundaments and Applications of Conducting Polymers, de Jesus Motheo A (Ed.) InTech Open: 43-66, (2011)
   

Review - conducting polymers in biosensors

Malhotra BD et al., Prospects of conducting polymers in biosensors.
Analytica Chimica Acta, 578, (1), 59-74, (2006)
   

Review - conducting polymers in sensors

Book chapter, Lange Uet al., Conducting Polymers as Artificial Receptors in Chemical Sensors, 
In: Artificial Receptors for Chemical Sensors, Mirsky VM, Yatsimirsky AK (Eds.) Wiley-VCH Verlag GmbH & Co. KGaA: Weinheim, 361-390, (2010)
   

Review - conducting polymers in sensors

Ramanavicius A et al., Conducting and Electrochemically Generated Polymers in Sensor Design (Mini Review).
Procedia Engineering, 47, 825-828, (2012)
   

Review - Contact lenses and drug delivery

Das PS et al., Contact lenses: A development towards ocular drug delivery system.
World Journal of Pharmaceuticla Research, 6, (9), 207-216, (2017)
   

Review - contact lenses for drug delivery

El Shaer A et al., Contact lenses as drug reservoirs & delivery systems: the successes & challenges.
Therapeutic Delivery, 5, (10), 1085-1100, (2014)
   

Review - contact lenses in ocular delivery

Gupta H et al., Contact lenses in ocular therapeutics.
Drug Discovery Today, 17, (9-10), 522-527, (2012)
   

Review - controlled drug release

Rambhia KJ et al., Controlled drug release for tissue engineering.
Journal of Controlled Release, 219, 119-128, (2015)
   

Review - controlled radical polymerization at surfaces

Book chapter, Zhao YLet al., Reversible Addition-Fragmentation Chain Transfer Polymerization from Surfaces, 
In: Controlled Radical Polymerization at and from Solid Surfaces, Vana P (Ed.) 77-106, (2016)
   

Review - controlled radical polymerization systems in analytical chemistry

Wang HS et al., Functional Interfaces Constructed by Controlled/Living Radical Polymerization for Analytical Chemistry.
ACS Applied Materials & Interfaces, 8, (5), 2881-2898, (2016)
   

Review - Controlled release from contact lenses

White CJ et al., Controlled drug release from contact lenses: a comprehensive review from 1965-present.
Journal of Drug Delivery Science and Technology, 21, (5), 369-384, (2011)
   

Review - Cooperative catalysts

Prins LJ et al., Multivalent Cooperative Catalysts.
Current Organic Chemistry, 13, (11), 1050-1064, (2009)
   

Review - core-shell microspheres

Yuan H et al., The Fabrication and Application of Bio-Functional Microspheres.
Current Organic Chemistry, 18, (17), 2270-2279, (2014)
   

Review - coupled SPE-CE

Ramautar R et al., Recent developments in coupled SPE-CE.
Electrophoresis, 31, (1), 44-54, (2010)
   

Review - creatinine measurement

Mohabbati-Kalejahi E et al., A review on creatinine measurement techniques.
Talanta, 97, 1-8, (2012)
   

Review - cross-linked enzyme aggregates

Wang MF et al., Advances in Cross-Linked Enzyme Aggregates.
Progress In Chemistry, 22, (1), 173-178, (2010)
   

Review - cryogels

Gun’ko VM et al., Cryogels: Morphological, structural and adsorption characterisation.
Advances in Colloid and Interface Science, 187-188, 1-46, (2013)
   

Review - cryogels

Book chapter, Mattiasson B, Cryogels for Biotechnological Applications, 
In: Polymeric Cryogels, Okay O (Ed.) Springer International Publishing: 245-281, (2014)
   

Review - cryogels in bioseparation

Ertürk G et al., Cryogels-versatile tools in bioseparation.
Journal of Chromatography A, 1357, 24-35, (2014)
   

Review - custom-made solid phase extraction materials

Lashgari M et al., An overview of the most common lab-made coating materials in solid phase microextraction.
Talanta, 191, 283-306, (2019)
   

Review - cyclodextrin-based hydrogels

Concheiro A et al., Chemically cross-linked and grafted cyclodextrin hydrogels: From nanostructures to drug-eluting medical devices.
Advanced Drug Delivery Reviews, 65, (9), 1188-1203, (2013)
   

Review - cyclodextrin-based polymers

Folch-Cano C et al., Inclusion and Functionalization of Polymers with Cyclodextrins: Current Applications and Future Prospects.
Molecules, 19, (9), 14066-14079, (2014)
   

Review - cyclodextrin glycosyltransferase

Han RZ et al., Recent advances in discovery, heterologous expression, and molecular engineering of cyclodextrin glycosyltransferase for versatile applications.
Biotechnology Advances, 32, (2), 415-428, (2014)
   

Review - cyclodextrin nanosponges

Caldera F et al., Evolution of Cyclodextrin Nanosponges.
International Journal of Pharmaceutics, 531, (2), 470-479, (2017)
   

Review - cyclodextrin nanosystems in drug delivery

Adeoye O et al., Cyclodextrin nanosystems in oral drug delivery: A mini review.
International Journal of Pharmaceutics, 531, (2), 521-531, (2017)
   

Review - cyclodextrins and metal catalysts

Hapiot F et al., Cyclodextrins and their applications in aqueous-phase metal-catalyzed reactions.
Comptes Rendus Chimie, 14, (2-3), 149-166, (2011)
   

Review - cyclodextrins and proteins

Yamamoto T et al., The Effects of Cyclodextrins on the Conformation of Proteins.
Current Organic Chemistry, 15, (6), 831-838, (2011)
   

Review - cyclodextrins in sensing

Shahgaldian P et al., Cyclodextrin derivatives as chiral supramolecular receptors for enantioselective sensing.
Sensors, 6, (6), 593-615, (2006)
   

Review - cytochrome enzyme mimics

Yarman A et al., Sensors based on cytochrome P450 and CYP mimicking systems.
Electrochimica Acta, 110, 63-72, (2013)
   

Review - demetallization of petroleum

Jenifer AC et al., A Review of the Unconventional Methods Used for the Demetallization of Petroleum Fractions over the Past Decade.
Energy & Fuels, 29, (12), 7743-7752, (2015)
   

Review - dendritic biomimetics

Liang C et al., Applying key concepts from nature: transition state stabilization, pre-concentration and cooperativity effects in dendritic biomimetics.
Progress in Polymer Science, 30, (3-4), 385-402, (2005)
   

Review - derivatives of chitosan

Book chapter, Rahangdale Det al., Derivatized Chitosan: Fundamentals to Applications, 
In: Biopolymer Grafting, Thakur VK (Ed.) Elsevier: 251-284, (2018)
   

Review - designed catalysts

Book chapter, Tada Met al., Chemical design and in situ characterization of active surfaces for selective catalysis, 
In: The Materials Design and Chemistry of Environmentally Acceptable Catalysts, Clarke DR, Rühle M (Eds.) Annual Reviews: Palo Alto, 397-426, (2005)
   

Review - detection methods for contaminants in milk

Xu F et al., Immunoassay of chemical contaminants in milk: A review.
Journal of Integrative Agriculture, 14, (11), 2282-2295, (2015)
   

Review - detection of Allura Red AC in food

Rovina K et al., Extraction, Analytical and Advanced Methods for Detection of Allura Red AC (E129) in Food and Beverages Products.
Frontiers in Microbiology, 7, ArticleNo798-(2016)
   

Review - detection of bisphenol A

Sun FX et al., Recent advances and progress in the detection of bisphenol A.
Analytical and Bioanalytical Chemistry, 408, (25), 6913-6927, (2016)
   

Review - detection of drugs of abuse

Book chapter, Wallace KJet al., Supramolecular Approach in Detecting Drugs of Abuse: Optical Sensors, 
In: Light in Forensic Science: Issues and Applications, Miolo G, Stair JL, Zloh M (Eds.) The Royal Society of Chemistry: 333-370, (2018)
   

Review - detection of melamine

Rovina K et al., A review of recent advances in melamine detection techniques.
Journal of Food Composition and Analysis, 43, 25-38, (2015)
   

Review - detection of melamine in complex samples

Wang TT et al., Analysis of melamine and analogs in complex matrices: Advances and trends.
Journal of Separation Science, 40, (1), 170-182, (2017)
   

Review - detection of microcystins

McElhiney J et al., Detection of the cyanobacterial hepatotoxins microcystins.
Toxicology and Applied Pharmacology, 203, (3), 219-230, (2005)
   

Review - detection of mycotoxins

Cao JL et al., Research progress on rapid detection methods of mycotoxins.
Chinese Journal of Pharmaceutical Analysis, 33, (1), 159-164, (2013)
   

Review - detection of nerve agents

Giordano BC et al., Synthetic methods applied to the detection of chemical warfare nerve agents.
Current Organic Chemistry, 11, (3), 255-265, (2007)
   

Review - detection of neurotransmitters

Si B et al., Recent Advances in the Detection of Neurotransmitters.
Chemosensors, 6, (1), ArticleNo1-(2018)
   

Review - detection of ochratoxin A

Hayat A et al., Recent advances in ochratoxin A-producing fungi detection based on PCR methods and ochratoxin A analysis in food matrices.
Food Control, 26, (2), 401-415, (2012)
   

Review - detection of stress biomarkers

Book chapter, Hepel Met al., Detection of Oxidative Stress Biomarkers Using Functional Gold Nanoparticles, 
In: Fine Particles in Medicine and Pharmacy, Matijevic E (Ed.) Springer US: 241-281, (2012)
   

Review - detection of viruses

Altintas Z et al., Biosensors for waterborne viruses: Detection and removal.
Biochimie, 115, 144-154, (2015)
   

Review - determination of ee

Leung D et al., Rapid determination of enantiomeric excess: a focus on optical approaches.
Chemical Society Reviews, 41, (1), 448-479, (2012)
   

Review - determination of ochratoxin A in foods

Huertas-Pérez JF et al., Solid phase extraction as sample treatment for the determination of Ochratoxin A in foods: A review.
Critical Reviews in Food Science and Nutrition, 57, (16), 3405-3420, (2017)
   

Review - developments in solid phase extraction

Li Z et al., Recent development and application of solid phase extraction materials.
Reviews on Advanced Materials Science, 49, (1), 87-111, (2017)
   

Review - diagnosis of Dengue using sensors

Teles FSRR, Biosensors and rapid diagnostic tests on the frontier between analytical and clinical chemistry for biomolecular diagnosis of dengue disease: A review.
Analytica Chimica Acta, 687, (1), 28-42, (2011)
   

Review - dispersive liquid-liquid extraction

Leong MI et al., Beyond dispersive liquid-liquid microextraction.
Journal of Chromatography A, 1335, 2-14, (2014)
   

Review - disulphide links in polymers

Gyarmati B et al., Reversible disulphide formation in polymer networks: A versatile functional group from synthesis to applications.
European Polymer Journal, 49, (6), 1268-1286, (2013)
   

Review - 3D optical crystal sensors

Zhang Q et al., Stimuli Responsive Polymer-Based 3D Optical Crystals for Sensing.
Polymers, 9, (11), ArticleNo436-(2017)
   

Review - downstream processing in biotechnology

Book chapter, Hatti-Kaul R, Downstream Processing in Industrial Biotechnology, 
In: Industrial Biotechnology, Soetaert W, Vandamme EJ (Eds.) Wiley-VCH: Weinheim, 279-321, (2010)
   

Review - drug analysis

Book chapter, Maier NAet al., Stereoselective Chromatographic Methods for Drug Analysis, 
In: Chirality in Drug Research, Francotte E, Lindner W (Eds.) Wiley-VCH Verlag GmbH & Co. KGaA: 189-260, (2006)
   

Review - drug analysis

Book chapter, Lord Het al., Drug Analysis by SPME, 
In: Handbook of Solid Phase Microextraction, Pawliszyn J (Ed.) Elsevier: Oxford, 335-382, (2012)
   

Review - drug-delivering contact lenses

Hui A et al., In Vivo Studies Evaluating the Use of Contact Lenses for Drug Delivery.
Optometry & Vision Science, 93, (4), 367-376, (2016)
   

Review - drug delivery from conact lenses

Gohel P H et al., Drug Eluting Therapeutic Contact Lens.
International Journal of Pharmaceutical Research & Allied Sciences, 1, (4), 1-6, (2012)
   

Review - drug delivery from contact lenses

Hu XH et al., Hydrogel Contact Lens for Extended Delivery of Ophthalmic Drugs.
International Journal of Polymer Science, 2011, Article ID 814163-(2011)
   

Review - drug delivery from contact lenses

Singh K et al., Novel Approaches in Formulation and Drug Delivery using Contact Lenses.
Journal of Basic and Clinical Pharmacy, 2, (2), 87-101, (2011)
   

Review - drug delivery from contact lenses

Maulvi FA et al., A review on therapeutic contact lenses for ocular drug delivery.
Drug Delivery, 23, (8), 3017-3026, (2016)
   

Review - drug delivery systems

Alvarez-Lorenzo C et al., Intelligent Drug Delivery Systems: Polymeric Micelles and Hydrogels.
Mini-Reviews in Medicinal Chemistry, 8, (11), 1065-1074, (2008)
   

Review - drug delivery systems

Alvarez-Lorenzo C et al., Bioinspired drug delivery systems.
Current Opinion in Biotechnology, 24, (6), 1167-1173, (2013)
   

Review - drug discovery tools for Chinese medicine

Xu XJ, New concepts and approaches for drug discovery based on traditional Chinese medicine.
Drug Discovery Today: Technologies, 3, (3), 247-253, (2006)
   

Review - drug eluting contact lenses

Alvarez-Lorenzo C et al., Contact lenses for drug delivery: Achieving sustained release with novel systems.
American Journal of Drug Delivery, 4, (3), 131-151, (2006)
   

Review - drug-eluting contact lenses

Bengani LC et al., Contact lenses as a platform for ocular drug delivery.
Expert Opinion on Drug Delivery, 10, (11), 1483-1496, (2013)
   

Review - drug-eluting contact lenses

Guzman-Aranguez A et al., Contact Lenses: Promising Devices for Ocular Drug Delivery.
Journal of Ocular Pharmacology and Therapeutics, 29, (2), 189-199, (2013)
   

Review - drug residue analysis

Kinsella B et al., Current trends in sample preparation for growth promoter and veterinary drug residue analysis.
Journal of Chromatography A, 1216, (46), 7977-8015, (2009)
   

Review - drugs sensors using polymeric membranes and ionic liquids

Faridbod F et al., Ionic Liquids Based Polymeric Membrane Drug Sensors.
Current Analytical Chemistry, 13, (1), 52-61, (2017)
   

Review - Electrically conducting polymers

Book chapter, Chianella Iet al., Conductive Polymers for Plastic Electronics, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 275-301, (2012)
   

Review - electroanalysis and membranes

Bakker E, Electroanalysis with Membrane Electrodes and Liquid-Liquid Interfaces.
Analytical Chemistry, 88, (1), 395-413, (2016)
   

Review - electrochemical affinity sensors

Warsinke A et al., Towards Separation-Free Electrochemical Affinity Sensors by Using Antibodies, Aptamers, and Molecularly Imprinted Polymers - A Review.
Analytical Letters, 39, (13), 2507-2556, (2006)
   

Review - electrochemical detection for diagnostics

Labib M et al., Electrochemical Methods for the Analysis of Clinically Relevant Biomolecules.
Chemical Reviews, 116, (16), 9001-9090, (2016)
   

Review - electrochemical detection of chemical weapons

Singh VV, Recent Advances in Electrochemical Sensors for Detecting Weapons of Mass Destruction. A Review.
Electroanalysis, 28, (5), 920-935, (2016)
   

Review - electrochemical detection of glycoproteins

Akiba U et al., Recent Progress in Electrochemical Biosensors for Glycoproteins.
Sensors, 16, (12), ArticleNo2045-(2016)
   

Review - electrochemical detection of HbA1c

Wang BZ et al., Recent Progress in Electrochemical HbA1c Sensors: A Review.
Materials, 8, (3), 1187-1203, (2015)
   

Review - electrochemical detection of hemoglobin

Hussain KK et al., Electrochemical Detection of Hemoglobin: A Review.
Electroanalysis, 29, (10), 2190-2199, (2017)
   

Review - electrochemical detection of mercury

Gao C et al., Voltammetric determination of mercury(II).
TrAC Trends in Analytical Chemistry, 51, 1-12, (2013)
   

Review - electrochemical detection of organophosphates

Kaur N et al., Current scenario in organophosphates detection using electrochemical biosensors.
TrAC Trends in Analytical Chemistry, 92, 62-85, (2017)
   

Review - electrochemical determination of caffeine

Svorc L, Determination of Caffeine: A Comprehensive Review on Electrochemical Methods.
International Journal of Electrochemical Science, 8, 5755-5773, (2013)
   

Review - electrochemical determination of mercury

Martín-Yerga D et al., Electrochemical determination of mercury: A review.
Talanta, 116, 1091-1104, (2013)
   

Review - electrochemically prepared SPME materials

Aziz-Zanjani MO et al., Electrochemically prepared solid-phase microextraction coatings - A review.
Analytica Chimica Acta, 781, 1-13, (2013)
   

Review - electrochemical nanosensors

Shiigi H et al., Placement of Nanospace on an Electrode for Biosensing.
Analytical Sciences, 28, (11), 1037-1048, (2012)
   

Review - electrochemical sensing of cardiac biomarkers

Hasanzadeh M et al., Electrochemical nano-immunosensing of effective cardiac biomarkers for acute myocardial infarction.
TrAC Trends in Analytical Chemistry, 49, 20-30, (2013)
   

Review - electrochemical sensor construction

Book chapter, Sandulescu Ret al., New Materials for the Construction of Electrochemical Biosensors, 
In: Biosensors - Micro and Nanoscale Applications, Rinken T (Ed.) InTech: 1-36, (2015)
   

Review - electrochemical sensors

Bakker E, Electrochemical sensors.
Analytical Chemistry, 76, (12), 3285-3298, (2004)
   

Review - electrochemical sensors

Bakker E et al., Electrochemical Sensors.
Analytical Chemistry, 78, (12), 3965-3984, (2006)
   

Review - electrochemical sensors

Book chapter, Fink JK, Electrochemical Sensors, 
In: Polymeric Sensors and Actuators, John Wiley & Sons, Inc.: 269-315, (2012)
   

review - electrochemical sensors

Alizadeh N et al., Ultrasensitive Bioaffinity Electrochemical Sensors: Advances and New Perspectives.
Electroanalysis, 30, (12), 2803-2840, (2018)
   

Review - electrochemical sensors for β-lactam antibiotics

Bottari F et al., Bio(inspired) strategies for the electro-sensing of β-lactam antibiotics.
Current Opinion in Electrochemistry, 10, 136-142, (2018)
   

Review - electrochemical sensors for neurochemicals

Azzouz A et al., Nanomaterial-based electrochemical sensors for the detection of neurochemicals in biological matrices.
TrAC Trends in Analytical Chemistry, 110, 15-34, (2019)
   

Review - electrochemical sensors for pesticides

Book chapter, Aránzazu Goicolea Met al., New materials in electrochemical sensors for pesticides monitoring, 
In: Pesticides - Strategies for Pesticides Analysis, Stoytcheva M (Ed.) InTech: 333-358, (2011)
   

Review - electrochemical sensors for uric acid

Lakshmi D et al., Electrochemical Detection of Uric Acid in Mixed and Clinical Samples: A Review.
Electroanalysis, 23, (2), 305-320, (2011)
   

Review - electrochemical sensors from metal oxides

Yu XY et al., Nanostructured metal oxides/hydroxides-based electrochemical sensor for monitoring environmental micropollutants.
Trends in Environmental Analytical Chemistry, 3-4, 28-35, (2014)
   

Review - electrochemical SPE

Seidi S et al., Electrochemically assisted solid based extraction techniques: A review.
Talanta, 132, 339-353, (2015)
   

Review - electrochemiluminescent sensors

Muzyka K, Current trends in the development of the electrochemiluminescent immunosensors.
Biosensors and Bioelectronics, 54, 393-407, (2014)
   

Review - electronic nose technology

Wyszynski B et al., Linking biological and artificial olfaction: biomimetic quartz crystal microbalance odor sensors.
IEEJ Transactions on Electrical and Electronic Engineering, 4, (3), 334-338, (2009)
   

Review - electronic tongue

Podrazka M et al., Electronic Tongue-A Tool for All Tastes?
Biosensors, 8, (1), ArticleNo3-(2018)
   

Review - Electrospun fibers as SPE materials

Chigome S et al., Electrospun nanofibers as sorbent material for solid phase extraction.
Analyst, 136, (14), 2879-2889, (2011)
   

Review - electrospun nanofibres in analytical chemistry

Chigome S et al., A review of opportunities for electrospun nanofibers in analytical chemistry.
Analytica Chimica Acta, 706, (1), 25-36, (2011)
   

review - electrosynthsised MIPs

Crapnell RD et al., Recent Advances in Electrosynthesized Molecularly Imprinted Polymer Sensing Platforms for Bioanalyte Detection.
Sensors, 19, (5), ArticleNo1204-(2019)
   

Review - emulsion polymers in catalysis

Striegler S, Emulsion and Miniemulsion Polymers in Catalysis.
Mini-Reviews in Organic Chemistry, 6, (3), 234-240, (2009)
   

Review - enantiomer separation by CEC

Preinerstorfer B et al., Recent accomplishments in the field of enantiomer separation by CEC.
Electrophoresis, 28, (15), 2527-2565, (2007)
   

Review - enantiomer separation by CEC

Lämmerhofer M et al., Monoliths with chiral surface functionalization for enantioselective capillary electrochromatography.
Journal of Pharmaceutical and Biomedical Analysis, 53, (5), 1091-1123, (2010)
   

Review - enantioselective CEC

Mangelings D et al., Enantioselective capillary electrochromatography: Recent developments and new trends.
Electrophoresis, 32, (19), 2583-2601, (2011)
   

Review - enantioselective chromatography

Bojarski J et al., What’s new in chromatographic enantioseparations?
Current Analytical Chemistry, 1, (1), 59-77, (2005)
   

Review - enantioselective electrochemical sensors

Trojanowicz M, Enantioselective electrochemical sensors and biosensors: A mini-review.
Electrochemistry Communications, 38, 47-52, (2014)
   

Review - enantioselective membranes

Book chapter, Yoshikawa Met al., Enantioselective Membranes, 
In: Encyclopedia of Membrane Science and Technology, Hoek EMV, Tarabara VV (Eds.) John Wiley & Sons, Inc.: (2013)
   

Review - enantioselective sensors

Aboul-Enein HY et al., Enantioselective sensors and biosensors in the analysis of chiral drugs.
Critical Reviews in Analytical Chemistry, 28, (3), 259-266, (1998)
   

Review - enantioselective sensors

Trojanowicz M et al., Electrochemical and piezoelectric enantioselective sensors and biosensors.
Analytical Letters, 38, (4), 523-547, (2005)
   

Review - enantioseparation in open-tubular electrochromatography

Kapnissi-Christodoulou CP et al., Enantioseparations in open-tubular capillary electrochromatography: Recent advances and applications.
Journal of Chromatography A, 1467, 145-154, (2016)
   

Review - enantioseparation of pharmaceuticals

Sierra I et al., Approaches for enantioselective resolution of pharmaceuticals by miniaturised separation techniques with new chiral phases based on nanoparticles and monolithis.
Electrophoresis, 37, (19), 2538-2553, (2016)
   

Review - eNose in heathcare

Book chapter, Wilson AD, Future Applications of Electronic-Nose Technologies in Healthcare and Biomedicine, 
In: Wide Spectra of Quality Control, Akyar I (Ed.) InTech: 267-290, (2011)
   

Review - entrapment of bacteria in polymers

Nagaoka T et al., Entrapment of Whole Cell Bacteria into Conducting Polymers.
Journal of Flow Injection Analysis, 29, (1), 7-10, (2012)
   

Review - environmental & food sampling

Mmualefe LC et al., Environmental and food sample handling challenges for developing countries.
Toxicological & Environmental Chemistry, 91, (5), 819-835, (2009)
   

Review - environmental sensors

Book chapter, Palchetti Iet al., Biosensor Techniques for Environmental Monitoring, 
In: Nucleic Acid Biosensors for Environmental Pollution Monitoring, Mascini M, Palchetti I (Eds.) The Royal Society of Chemistry: Cambridge, 1-16, (2011)
   

Review - environmental trace analysis

Buchberger WW, Current approaches to trace analysis of pharmaceuticals and personal care products in the environment.
Journal of Chromatography A, 1218, (4), 603-618, (2011)
   

Review - enzyme biosensors

Book chapter, Setford SJet al., Enzyme Biosensors, 
In: Microbial Enzymes and Biotransformations, Barredo JL (Ed.) 29-60, (2005)
   

Review - Enzyme inhibitors

Meggers E, From Conventional to Unusual Enyzme Inhibitor Scaffolds: The Quest for Target Specificity.
Angewandte Chemie International Edition, 50, (11), 2442-2448, (2011)
   

Review - Enzyme mimics

Book chapter, Yatsimirsky AK, Enzyme Mimics, 
In: Encyclopedia of Supramolecular Chemistry, Atwood JL, Steed JW (Eds.) Taylor and Francis: 546-553, (2001)
   

Review - enzyme mimics

Liu YQ et al., Research and progress of mimetic enzymes.
Progress In Chemistry, 17, (6), 1067-1073, (2005)
   

Review - Enzyme mimics

Book chapter, Cragg PJ, Supramolecular Enzyme Mimics, 
In: Supramolecular Chemistry, Springer Netherlands: Dordrecht, 113-151, (2010)
   

Review - enzyme mimics

Dong ZY et al., Supramolecular enzyme mimics by self-assembly.
Current Opinion in Colloid & Interface Science, 16, (6), 451-458, (2011)
   

Review - Enzymes in MIP-based sensors

Yarman A et al., Enzymes as Tools in MIP-Sensors.
Chemosensors, 5, (2), ArticleNo11-(2017)
   

Review - enzyme thermistor biosensors

Yakovleva M et al., The enzyme thermistor - A realistic biosensor concept. A critical review.
Analytica Chimica Acta, 766, 1-12, (2013)
   

Review - estrogen detection in dairy products

Socas-Rodríguez B et al., Chromatographic analysis of natural and synthetic estrogens in milk and dairy products.
TrAC Trends in Analytical Chemistry, 44, 58-77, (2013)
   

Review - evolution of recognition molecules

Book chapter, Dunn IS, Evolving and Creating Recognition Molecules, 
In: Searching for Molecular Solutions - Empirical Discovery and its Future, John Wiley & Sons Inc.: Hoboken, 234-274, (2009)
   

Review - explosives detection

Caygill JS et al., Current trends in explosive detection techniques.
Talanta, 88, (1), 14-29, (2012)
   

Review - explosive sensing

Zu BY et al., Nanostructure-based optoelectronic sensing of vapor phase explosives - a promising but challenging method.
Nanoscale, 5, (22), 10693-10701, (2013)
   

Review - extraction and analysis of tartrazine

Rovina K et al., A Review of Extraction and Analytical Methods for the Determination of Tartrazine (E 102) in Foodstuffs.
Critical Reviews in Analytical Chemistry, 47, (4), 309-324, (2017)
   

Review - extraction methods

Poliwoda A et al., Membrane extraction and solid-phase extraction as effective methods for extraction and concentration of organic compounds from samples with complex matrix composition.
Chemik, 68, (4), 312-320, (2014)
   

Review - extraction of active ingredients from chinese medicine

Ma YZ et al., Advance in Extraction and Separation of Chinese Medicine Active Ingredients.
Journal of Hebei Institute of Technology, 31, (1), 99-101, (2009)
   

Review - extraction of alkaloids

Yu ZY et al., Progress in extraction and purification of alkaloids.
Chemical Industry and Engineering Progress, 25, (3), 259-263, (2006)
   

Review - extraction of bioactives

Potterat O et al., Concepts and technologies for tracking bioactive compounds in natural product extracts: generation of libraries, and hyphenation of analytical processes with bioassays.
Natural Product Reports, 30, (4), 546-564, (2013)
   

Review - extraction of heavy metal ions with magnetic nanoparticles

Hemmati M et al., Magnetic nanoparticle based solid-phase extraction of heavy metal ions: A review on recent advances.
Microchimica Acta, 185, (3), 160-(2018)
   

Review - extraction of natural products

Zhang QW et al., Techniques for extraction and isolation of natural products: a comprehensive review.
Chinese Medicine, 13, (1), ArticleNo20-(2018)
   

Review - extraction of phenolic compounds

Moscipan M et al., Methods for extraction, preconcentration and determination of phenolic compounds in environmental and food samples.
Przemysl Chemiczny, 90, (5), 932-937, (2011)
   

Review - extraction of phenolic compounds

Book chapter, Santos-Buelga Cet al., Extraction and Isolation of Phenolic Compounds, 
In: Natural Products Isolation, Sarker SD, Nahar L (Eds.) Humana Press: 427-464, (2012)
   

Review - extraction of rare earth ions

Pyrzynska K et al., Application of solid phase extraction procedures for rare earth elements determination in environmental samples.
Talanta, 154, 15-22, (2016)
   

Review - extraction of sulfonamides from milk

Kechagia M et al., Trends in Microextraction-Based Methods for the Determination of Sulfonamides in Milk.
Separations, 4, (3), ArticleNo23-(2017)
   

Review - extraction of tin and arsenic for analysis

Dietz C et al., Current perspectives in analyte extraction strategies for tin and arsenic speciation.
Journal of Chromatography A, 1153, (1-2), 114-129, (2007)
   

Review - extraction techniques

Raynie DE, Modern Extraction Techniques.
Analytical Chemistry, 82, (12), 4911-4916, (2010)
   

Review - extraction techniques for organophosphorus pesticides

Chen J et al., Sorptive extraction techniques in sample preparation for organophosphorus pesticides in complex matrices.
Journal of Chromatography B, 878, (17-18), 1216-1225, (2010)
   

Review - fabrication of plasmonic sensors

Book chapter, Anon, Fabrication and Functionalization Method, 
In: Fiber Optic Sesors Based on Plasmonics, Gupta BD, Srivastava SK, Verma R (Eds.) World Scientific Publishing Co. Pte. Ltd.: Singapore, 119-154, (2015)
   

Review - fast LC in food analysis

Núñez O et al., New trends in fast liquid chromatography for food and environmental analysis.
Journal of Chromatography A, 1228, (1), 298-323, (2012)
   

Review - FET-based sensors with synthetic receptors

Iskierko Z et al., Molecular recognition by synthetic receptors: Application in field-effect transistor based chemosensing.
Biosensors and Bioelectronics, 109, 50-62, (2018)
   

Review - fiber optic sensors

Book chapter, Elosua Cet al., Fiber Optic Sensors Based on Nanostructured Materials, 
In: Lab-on-Fiber Technology, Cusano A, Consales M, Crescitelli A, Ricciardi A (Eds.) Springer International Publishing: Cham, 277-299, (2015)
   

Review - fiber optic sensors

Wang XD et al., Fiber-Optic Chemical Sensors and Biosensors (2013-2015).
Analytical Chemistry, 88, (1), 203-227, (2016)
   

Review - flow-through optosensors

Llorent-Martínez EJ et al., Contribution to Automation for Determination of Drugs Based on Flow-Through Optosensors.
Applied Spectroscopy Reviews, 46, (5), 339-367, (2011)
   

Review - fluorescence-based optical sensors

Benito-Peña E et al., Fluorescence based fiber optic and planar waveguide biosensors. A review.
Analytica Chimica Acta, 943, 17-40, (2016)
   

Review - fluorescence-based sensors

Basabe-Desmonts L et al., Design of fluorescent materials for chemical sensing.
Chemical Society Reviews, 36, (6), 993-1017, (2007)
   

Review - fluorescence biosensors

Altschuh D et al., Fluorescence sensing of intermolecular interactions and development of direct molecular biosensors.
Journal of Molecular Recognition, 19, (6), 459-477, (2006)
   

Review - Fluorescence detection of pesticides

Nsibande SA et al., Fluorescence detection of pesticides using quantum dot materials - A review.
Analytica Chimica Acta, 945, 9-22, (2016)
   

Review - fluorescent and colorimetric sensors

Kim HN et al., Recent progress on polymer-based fluorescent and colorimetric chemosensors.
Chemical Society Reviews, 40, (1), 79-93, (2011)
   

review - fluorescent nano-MIPs

Xiao DL et al., Fluorescent nanomaterials combined with molecular imprinting polymer: synthesis, analytical applications, and challenges.
Microchimica Acta, 187, (7), Article399-(2020)
   

Review - fluorescent receptors

Zhang YH et al., Molecular design and molecular recognition of fluorescent receptors.
Chinese Journal of Analysis Laboratory, 21, (5), 93-99, (2002)
   

Review - food analysis

Jandera P, Advances in the development of organic polymer monolithic columns and their applications in food analysis - A review.
Journal of Chromatography A, 1313, 37-53, (2013)
   

Review - fuel desulfurization technology

Al-Degs YS et al., Conventional and Upcoming Sulfur-Cleaning Technologies for Petroleum Fuel: A Review.
Energy Technology, 4, (6), 679-699, (2016)
   

Review - functional group positioning in catalyst design

Book chapter, Margelefsky ELet al., Heterogeneous Catalyst Design by Multiple Functional Group Positioning in Organic-Inorganic Materials: On the Route to Analogs of Multifunctional Enzymes, 
In: Model Systems in Catalysis, Rioux RM (Ed.) Springer: New York, 495-516, (2010)
   

Review - functional nanoparticles

de Dios AS et al., Multifunctional nanoparticles: Analytical prospects.
Analytica Chimica Acta, 666, (1-2), 1-22, (2010)
   

Review - functional nanospace in molecular recognition

Shiigi H, Application of a Functional Nanospace to Molecular Recognition.
Review of Polarography, 62, (1), 17-24, (2016)
   

Review - functional polymers in biosensors

Lee KM et al., Chemical Design of Functional Polymer Structures for Biosensors: From Nanoscale to Macroscale.
Polymers, 10, (5), ArticleNo551-(2018)
   

Review - gels and microgels in nanotechnology

Fernández-Barbero A et al., Gels and microgels for nanotechnological applications.
Advances in Colloid and Interface Science, 147-148, 88-108, (2009)
   

Review - genotoxic impurities in drug manufacturing

Szekely G et al., Genotoxic Impurities in Pharmaceutical Manufacturing: Sources, Regulations, and Mitigation.
Chemical Reviews, 115, (16), 8182-8229, (2015)
   

Review - glucose sensing

Hansen JS et al., Arylboronic acids: A diabetic eye on glucose sensing.
Sensors and Actuators B: Chemical, 161, (1), 45-79, (2012)
   

Review - glycan-based diagnostic devices

Wang SK et al., Glycan-based diagnostic devices: current progress, challenges and perspectives.
Chemical Communications, 51, (94), 16750-16762, (2015)
   

Review - graphene in chemiluminescence-based sensing

Chen H et al., Graphene materials-based chemiluminescence for sensing.
Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 27, 54-71, (2016)
   

Review - graphene in electrochemical sensing

Xu JH et al., Nanocomposites of graphene and graphene oxides: Synthesis, molecular functionalization and application in electrochemical sensors and biosensors. A review.
Microchimica Acta, 184, (1), 1-44, (2017)
   

Review - green chemistry

Brett CMA, Novel sensor devices and monitoring strategies for green and sustainable chemistry processes.
Pure And Applied Chemistry, 79, (11), 1969-1980, (2007)
   

Review - Green methods of pesticide analysis

Stocka J et al., Green Aspects of Techniques for the Determination of Currently Used Pesticides in Environmental Samples.
International Journal of Molecular Sciences, 12, (11), 7785-7805, (2011)
   

Review - green sample preparation methods

Book chapter, da Silva MRet al., New Materials for Green Sample Preparation, 
In: Green Extraction Techniques Principles, Advances and Applications, Ibáñez E, Cifuentes A (Eds.) Elsevier: 575-599, (2017)
   

Review - halloysite nanotubes in analysis and drug delivery

Fizir M et al., Halloysite nanotubes in analytical sciences and in drug delivery: A review.
Microchimica Acta, 185, (8), ArticleNo389-(2018)
   

Review - hierarchical imprinting

Book chapter, Kim Het al., Hierarchically Imprinted Adsorbents, 
In: Environmental Applications of Nanomaterials, Fryxell GE, Cao GZ (Eds.) Imperial College Press: 213-239, (2007)
   

Review - hierarchical imprinting

Book chapter, Kim Het al., Hierarchically Imprinted Adsorbents, 
In: Environmental Applications of Nanomaterials (2nd Edition), Fryxell GE, Cao GZ (Eds.) Imperial College Press: 261-285, (2012)
   

Review - history of MIPs

Book chapter, Mayes AG, A brief history of the "new era" of molecular imprinting, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 13-23, (2005)
   

Review - HPLC and CEC

Sano A et al., Recent advances in materials for separation.
Bunseki Kagaku, 56, (5), 279-297, (2007)
   

Review - hybrid nanostructures in biosensing

Zhang SD et al., Synthesis, Assembly, and Applications of Hybrid Nanostructures for Biosensing.
Chemical Reviews, 117, (20), 12942-13038, (2017)
   

Review - hydrogels in biomedicine

Kashyap N et al., Hydrogels for pharmaceutical and biomedical applications.
Critical Reviews in Therapeutic Drug Carrier Systems, 22, (2), 107-149, (2005)
   

Review - hydrogels in biomedicine

del Valle JL et al., Hydrogels for Biomedical Applications: Cellulose, Chitosan, and Protein/Peptide Derivatives.
Gels, 3, (3), ArticleNo27-(2017)
   

Review - hydrogels in biosensors

Mateescu A et al., Thin Hydrogel Films for Optical Biosensor Applications.
Membranes, 2, (1), 40-69, (2012)
   

Review - hydrogels in drug delivery

Kalshetti PP et al., Hydrogels as a drug delivery system and applications: A review.
International Journal of Pharmacy and Pharmaceutical Sciences, 4, (1), 1-7, (2012)
   

Review - hydrophilic materials in sample pretreatment

Tang F et al., Hydrophilic materials in sample pretreatment.
TrAC Trends in Analytical Chemistry, 86, 172-184, (2017)
   

Review - immobilized molecular catalysts

Book chapter, Anwander R, Immobilization of Molecular Catalysts, 
In: Handbook of Heterogeneous Catalysis, Ertl G, Knözinger H, Schüth F, Weitkamp J (Eds.) Wiley: 583-614, (2008)
   

Review - immunoassay and sensor technologies

Book chapter, Farré Met al., Immunochemical and Receptor Technologies: The Role of Immunoassay, Immunoaffinity Chromatography, Immunosensors and Molecularly Imprinted Polymeric Sensors, 
In: Food Contaminants and Residue Analysis, Picó Y (Ed.) Elsevier: Amsterdam, 91-130, (2008)
   

Review - Immunoassays in agriculture

Book chapter, Liu ZLet al., Future Perspectives and Challenges, 
In: Immunoassays in Agricultural Biotechnology, Shan GM (Ed.) John Wiley & Sons, Inc.: Hoboken, New Jersey, 325-339, (2011)
   

Review - immunochemical methods in medical analysis

Goryacheva IY, Contemporary trends in the development of immunochemical methods for medical analysis.
Journal of Analytical Chemistry, 70, (8), 903-914, (2015)
   

Review - immunodiagnostics

Shen M et al., Site-selective orientated immobilization of antibodies and conjugates for immunodiagnostics development.
Methods, 116, 95-111, (2017)
   

Review - impedometric biosensors

Prodromidis MI, Impedimetric immunosensors--A review.
Electrochimica Acta, 55, (14), 4227-4233, (2010)
   

Review - Imprinted monoliths

Book chapter, Sellergren B, Imprinted Monoliths, 
In: Monolithic Materials - Preparation, Properties and Applications, Svec F, Tennikova TB, Deyl Z (Eds.) Elsevier: 277-300, (2003)
   

Review - imprinted nanomaterials

He L et al., Current progress in research on the nanomaterials for biological macromolecules recognition.
Journal of Biomedical Engineering, 30, (2), 428-431, (2013)
   

Review - Indicator-displacement assays

Nguyen BT et al., Indicator-displacement assays.
Coordination Chemistry Reviews, 250, (23-24), 3118-3127, (2006)
   

Review - inorganic/polymer hybrid nanopartcles in sensing

Sierra-Martin B et al., Inorganic/polymer hybrid nanoparticles for sensing applications.
Advances in Colloid and Interface Science, 233, 25-37, (2016)
   

Review - intelligent biomaterials

Peppas NA, Intelligent biomaterials as pharmaceutical carriers in microfabricated and nanoscale devices.
MRS Bulletin, 31, (11), 888-893, (2006)
   

Review - intelligent drug delivery devices

Patil JS et al., Hydrogel System, a ’Smart’ and ’Intelligent’ Drug Delivery Device: A Systematic and Concise Review.
Indian Journal of Novel Drug delivery, 6, (2), 93-105, (2014)
   

Review - intellignt polymer gels

Nakano Y, Science and technology of polymer gels.
Journal of Chemical Engineering of Japan, 38, (8), 605-614, (2005)
   

Review - interfacial diazonium chemistry

Salmi Z et al., On the interfacial chemistry of aryl diazonium compounds in polymer science.
Chemical Papers, 66, (5), 369-391, (2012)
   

Review - interpenetrating polymer network hydrogels

Dragan ES, Design and applications of interpenetrating polymer network hydrogels. A review.
Chemical Engineering Journal, 243, 572-590, (2014)
   

Review - in-tube solid phase extraction

Moliner-Martinez Y et al., Recent advances of in-tube solid-phase microextraction.
TrAC Trends in Analytical Chemistry, 71, 205-213, (2015)
   

Review - ion-chelating resins

Matsunaga H, Recognition, separation and concentration of metal ions with chelating resins or chelating reagent impregnated resins (Review).
Bunseki Kagaku, 50, (2), 89-106, (2001)
   

Review - ionic liquids SPE

Fontanals N et al., Ionic liquids in solid-phase extraction.
TrAC Trends in Analytical Chemistry, 41, 15-26, (2012)
   

Review - ion-imprinting

Mafu LD et al., Ion-imprinted polymers for environmental monitoring of inorganic pollutants: synthesis, characterization, and applications.
Environmental Science and Pollution Research, 20, (2), 790-802, (2013)
   

Review - ion mobility spectroscopy

Borsdorf H et al., Recent Developments in Ion Mobility Spectrometry.
Applied Spectroscopy Reviews, 46, (6), 472-521, (2011)
   

Review - Isolation and identification of flavonoids

Book chapter, Feng WSet al., Isolation and Structure Identification of Flavonoids, 
In: Flavonoids - From Biosynthesis to Human Health, Justino GC (Ed.) InTech: Rijeka, 17-43, (2017)
   

Review - isolation of natural products

Bucar F et al., Natural product isolation - how to get from biological material to pure compounds.
Natural Product Reports, 30, (4), 525-545, (2013)
   

Review - label-free sensing in liquids

Book chapter, Jungmann Cet al., Biomimetic Recognition for Acoustic Sensing in Liquids, 
In: Label-Free Biosensing: Advanced Materials, Devices and Applications, Schöning MJ, Poghossian A (Eds.) Springer International Publishing: Cham, 323-344, (2018)
   

Review - lab-on-a-valve systems

Miró M et al., Analytical potential of mesofluidic lab-on-a-valve as a front end to column-separation systems.
TrAC Trends in Analytical Chemistry, 30, (1), 153-164, (2011)
   

Review - layer-by-layer assembly

Book chapter, Kunitake Tet al., Assembly of organic and inorganic molecular layers by adsorption from solution, 
In: Proceedings of the International Conference on Colloid and Surface Science - 25th Anniversary of the Division of Colloid and Surface Chemistry, The Chemical Society of Japan, Iwasawa Y, Oyama N, Kunieda H (Eds.) Elsevier: 15-24, (2001)
   

Review - layered metal nanoparticles in sensing

Tel-Vered R et al., Layered Metal Nanoparticle Structures on Electrodes for Sensing, Switchable Controlled Uptake/Release, and Photo-electrochemical Applications.
Small, 12, (1), 51-75, (2016)
   

Review - layered nanomaterial chemiluminescence systems

Zhong JP et al., Layered-nanomaterial-amplified chemiluminescence systems and their analytical applications.
Analytical and Bioanalytical Chemistry, 408, (30), 8731-8746, (2016)
   

Review - LC analysis of drugs

Mullett WM, Determination of drugs in biological fluids by direct injection of samples for liquid-chromatographic analysis.
Journal of Biochemical and Biophysical Methods, 70, (2), 263-273, (2007)
   

Review - LC-MS analysis of veterinary drug residues

Díaz-Cruz MS et al., Recent advances in LC-MS residue analysis of veterinary medicines in the terrestrial environment.
TrAC Trends in Analytical Chemistry, 26, (6), 637-646, (2007)
   

Review - LC-MS determination of warfare agents

Aleksenko SS, Liquid chromatography with mass-spectrometric detection for the determination of chemical warfare agents and their degradation products (Original Russian Text © S.S. Aleksenko, 2012, published in Zhurnal Analiticheskoi Khimii, 2012, Vol. 67, No. 2, pp. 116-132).
Journal of Analytical Chemistry, 67, (2), 82-97, (2012)
   

Review - LC-MS for bioanalysis

Núñez O et al., State-of-the-art in fast liquid chromatography-mass spectrometry for bio-analytical applications.
Journal of Chromatography B, 927, 3-21, (2013)
   

Review - LC stationary phases

Haginaka J, LC packing materials for pharmaceutical and biomedical analysis.
Chinese Journal of Chromatography, 20, (6), 508-518, (2002)
   

Review - LC stationary phases

Haginaka J, LC Packing Materials for Pharmaceutical and Biomedical Analysis.
Chromatography, 23, (1), 1-12, (2002)
   

Review - LC with porous polymers

Hosoya K, Simple LC using New Macroporous Polymers.
Chromatography, 34, (1), 1-22, (2013)
   

Review - light-activated membranes

Nicoletta FP et al., Light Responsive Polymer Membranes: A Review.
Membranes, 2, (1), 134-197, (2012)
   

Review - lipases in ester synthesis

Rajendran A et al., Lipase Catalyzed Ester Synthesis for Food Processing Industries.
Brazilian Archives of Biology and Technology, 52, (1), 207-219, (2009)
   

Review - luminescent polymer sensors

García JM et al., Fluorogenic and Chromogenic Polymer Chemosensors.
Polymer Reviews, 51, (4), 341-390, (2011)
   

Review - luminesence detection

Book chapter, Molina-Díaz Aet al., Luminescence Detection in Flow Analysis, 
In: Advances in Flow Analysis, Trojanowicz M (Ed.) Wiley-VCH: Weinheim, 343-393, (2008)
   

Review - macromolecular self-assembly

Zhao Y et al., Progressive Macromolecular Self-Assembly: From Biomimetic Chemistry to Bio-Inspired Materials.
Advanced Materials, 25, (37), 5215-5256, (2013)
   

Review - macroporous monolithc polymers

Arrua RD et al., Macroporous Monolithic Polymers: Preparation and Applications.
Materials, 2, 2429-2466, (2009)
   

Review - macroporous polymers

Hosoya K, Development of new macro-porous polymers contributing to assessment and improvement of environmental pollutions.
Kobunshi, 62, (8), 434-436, (2013)
   

review - magnetic core-shell MIPs for biomolecules

Dinc M et al., Recent advances on core-shell magnetic molecularly imprinted polymers for biomacromolecules.
TrAC Trends in Analytical Chemistry, 114, 202-217, (2019)
   

Review - magnetic materials in sample preparation

Li XS et al., Synthesis and applications of functionalized magnetic materials in sample preparation.
TrAC Trends in Analytical Chemistry, 45, 233-247, (2013)
   

Review - magnetic MIPs

Chen LG et al., Application of magnetic molecularly imprinted polymers in analytical chemistry.
Analytical Methods, 4, (9), 2613-2621, (2012)
   

review - magnetic MIPs in electrochemical sensing

Yang YK et al., Magnetic molecularly imprinted electrochemical sensors: A review.
Analytica Chimica Acta, 1106, 1-21, (2020)
   

review - magnetic MIPs in electrochemical sensors

Marfà J et al., Magnetic-molecularly imprinted polymers in electrochemical sensors and biosensors.
Analytical and Bioanalytical Chemistry, 413, (24), 6141-6157, (2021)
   

Review - magnetic MIPs in food analysis

Yuan LL et al., Application of magnetic molecularly imprinted polymers in the analysis of food safety.
Journal of Food Safety and Quality, 5, (11), 3582-3586, (2014)
   

review - magnetic MIPs in pesticide analysis

Farooq S et al., Application, advancement and green aspects of magnetic molecularly imprinted polymers in pesticide residue detection.
Science of The Total Environment, 804, Article150293-(2022)
   

Review - magnetic nanomaterials in separations

Ríos A et al., Magnetic (nano)materials as an useful tool for sample preparation in analytical methods. A review.
Analytical Methods, 5, (18), 4558-4573, (2013)
   

Review - magnetic nanomaterials in SPE

Huang DN et al., Functionalized magnetic nanomaterials as solid-phase extraction adsorbents for organic pollutants in environmental analysis.
Analytical Methods, 6, (18), 7130-7141, (2014)
   

Review - magnetic nanoparticles

Faraji M et al., Magnetic nanoparticles: Synthesis, stabilization, functionalization, characterization, and applications.
Journal of the Iranian Chemical Society, 7, (1), 1-37, (2010)
   

Review - magnetic nanoparticles in extraction

Tolmacheva VV et al., Magnetic adsorbents based on iron oxide nanoparticles for the extraction and preconcentration of organic compounds.
Journal of Analytical Chemistry, 71, (4), 321-338, (2016)
   

Review - magnetic nanoparticles in sample preparation

Xie LJ et al., Application of functionalized magnetic nanoparticles in sample preparation.
Analytical and Bioanalytical Chemistry, 406, (2), 377-399, (2014)
   

Review - magnetic sample preparation

He JC et al., Magnetic separation techniques in sample preparation for biological analysis: A review.
Journal of Pharmaceutical and Biomedical Analysis, 101, 84-101, (2014)
   

Review - magnetic solids in chemical analysis

Aguilar-Arteaga K et al., Magnetic solids in analytical chemistry: A review.
Analytica Chimica Acta, 674, (2), 157-165, (2010)
   

Review - magnetic solids in electrochemical analysis

Kudr J et al., Magnetic solids in electrochemical analysis.
TrAC Trends in Analytical Chemistry, 98, 104-113, (2018)
   

Review - materials for analytical chemistry

He L et al., Recent advances in analytical chemistry--A material approach.
Analytica Chimica Acta, 556, (1), 1-15, (2006)
   

Review - materials for enantioselective release

Yu HL et al., Materials Established for Enantioselective Release of Chiral Compounds.
Industrial & Engineering Chemistry Research, 55, (21), 6037-6048, (2016)
   

Review - materials for sample preparation

Fumes BH et al., Recent advances and future trends in new materials for sample preparation.
TrAC Trends in Analytical Chemistry, 71, 9-25, (2015)
   

Review - materials for the capture of cells and microorganisms

Bole AL et al., Advanced Materials for the Recognition and Capture of Whole Cells and Microorganisms.
Advanced Materials, 28, (27), 5349-5366, (2016)
   

Review - matrix solid-phase dispersion

Capriotti AL et al., Recent trends in matrix solid-phase dispersion.
TrAC Trends in Analytical Chemistry, 43, 53-66, (2013)
   

Review - matrix solid-phase dispersion

Capriotti AL et al., Recent advances and developments in matrix solid-phase dispersion.
TrAC Trends in Analytical Chemistry, 71, 186-193, (2015)
   

Review - matrix solid-phase dispersion extraction

Capriotti AL et al., Recent developments in matrix solid-phase dispersion extraction.
Journal of Chromatography A, 1217, (16), 2521-2532, (2010)
   

review - mechanism of MIP formation

Cowen T et al., Synthetic Mechanism of Molecular Imprinting at the Solid Phase.
Macromolecules, 53, (4), 1435-1442, (2020)
   

Review - medical biomaterials

Caldorera-Moore M et al., Micro- and nanotechnologies for intelligent and responsive biomaterial-based medical systems.
Advanced Drug Delivery Reviews, 61, (15), 1391-1401, (2009)
   

Review - melamine analysis

Sun FX et al., Analytical methods and recent developments in the detection of melamine.
TrAC Trends in Analytical Chemistry, 29, (11), 1239-1249, (2010)
   

Review - melamine detection

Liu Y et al., Recent developments in the detection of melamine.
Journal of Zhejiang University - Science B, 13, (7), 525-532, (2012)
   

Review - membrane-based microextraction

Chimuka L et al., Advances in sample preparation using membrane-based liquid-phase microextraction techniques.
TrAC Trends in Analytical Chemistry, 30, (11), 1781-1792, (2011)
   

Review - membrane chromatography

Book chapter, Avramescu Met al., Membrane Chromatography, 
In: Handbook of Membrane Separations, Pabby AK, Rizvi SSH, Sastre AM (Eds.) CRC Press: Boca Raton, FL, 25-63, (2008)
   

Review - membranes for chiral separations

Higuchi A et al., Polymeric Membranes for Chiral Separation of Pharmaceuticals and Chemicals.
Polymer Reviews, 50, (2), 113-143, (2010)
   

Review - membranes for enantiomeric separations

Fernandes C et al., Chiral Separation in Preparative Scale: A Brief Overview of Membranes as Tools for Enantiomeric Separation.
Symmetry, 9, (10), ArticleNo206-(2017)
   

Review - membranes in drug delivery

Book chapter, Grassi M, Membranes in Drug Delivery, 
In: Handbook of Membrane Separations, Pabby AK, Rizvi SSH, Sastre AM (Eds.) CRC Press: Boca Raton, FL, 427-471, (2008)
   

Review - membranes in sensing

Book chapter, Reddy SM, Membrane Technologies for Sensing and Biosensing, 
In: Materials for Chemical Sensing, Cesar Paixão TRL, Reddy SM (Eds.) Springer International Publishing: 75-103, (2017)
   

Review - mesoporous adsorbents

Wu ZJ et al., Adsorption mechanisms of mesoporous adsorbents in solutions.
Chemical Research in Chinese Universities, 20, (2), 185-187, (2004)
   

Review - mesoporous materials in electrochemical sensing

Walcarius A, Mesoporous Materials-Based Electrochemical Sensors.
Electroanalysis, 27, (6), 1303-1340, (2015)
   

Review - mesoporous materials in sample prep

Zhao L et al., Recent advances of mesoporous materials in sample preparation.
Journal of Chromatography A, 1228, (1), 193-204, (2012)
   

Review - mesoporous materials in sensing

Melde BJ et al., Mesoporous materials in sensing: morphology and functionality at the meso-interface.
Analytical and Bioanalytical Chemistry, 398, (4), 1565-1573, (2010)
   

Review - mesoporous organosilicas

Park SS et al., Periodic mesoporous organosilicas for advanced applications.
NPG Asia Materials, 6, e96-(2014)
   

Review - metal chelate monomers

Dzhardimalieva GI et al., Metal Chelate Monomers as Precursors of Polymeric Materials.
Journal of Inorganic and Organometallic Polymers and Materials, 26, (6), 1112-1173, (2016)
   

Review - metal ion binding polymers

Pustam AN et al., Engineering selectivity into polymer-supported reagents for transition metal ion complex formation.
Reactive and Functional Polymers, 70, (8), 545-554, (2010)
   

Review - metalloenzyme mimics

Zhao M et al., Insights into metalloenzyme microenvironments: biomimetic metal complexes with a functional second coordination sphere.
Chemical Society Reviews, 42, (21), 8360-8375, (2013)
   

Review - metals analysis with nano-materials

Wang LL et al., Application of nano-materials in the analysis of metal ions.
Metallurgical Analysis, 29, (2), 37-44, (2009)
   

Review - metals in porous hosts

Welbes LL et al., Confinement of metal complexes within porous hosts: development of functional materials for gas binding and catalysis.
Accounts of Chemical Research, 38, (10), 765-774, (2005)
   

Review - metal wire-supported SPE materials

Feng JJ et al., The development of solid-phase microextraction fibers with metal wires as supporting substrates.
TrAC Trends in Analytical Chemistry, 46, 44-58, (2013)
   

Review - methods for screening for bioactives in traditional chinese medicine

Yang XX et al., Screening for the bioactive constituents of traditional Chinese medicines-progress and challenges.
RSC Advances, 7, (6), 3089-3100, (2017)
   

Review - methods of extraction and analysis of chromium species

Trzonkowska L et al., Recent Advances in On-Line Methods Based on Extraction for Speciation Analysis of Chromium in Environmental Matrices.
Critical Reviews in Analytical Chemistry, 46, (4), 305-322, (2016)
   

Review - methods of separating compounds using polymers

Ingole PG et al., Methods for separation of organic and pharmaceutical compounds by different polymer materials.
Korean Journal of Chemical Engineering, 31, (12), 2109-2123, (2014)
   

Review - micro- and nano-particles in bioanalysis

Book chapter, Perez de Vargas-Sansalvador IMet al., Synthesis of Monodisperse Polymeric Nano- and Microparticles and Their Application in Bioanalysis, 
In: Advances in Chemical Bioanalysis, Matysik FM (Ed.) Springer: Berlin, Heidelberg, 1-24, (2013)
   

Review - microextraction and sample preparation

Szultka M et al., Microextraction sample preparation techniques in biomedical analysis.
Journal of Separation Science, 37, (21), 3094-3105, (2014)
   

Review - microextraction techniques

Farhadi K et al., Microextraction techniques in therapeutic drug monitoring.
Biomedical Chromatography, 26, (8), 972-989, (2012)
   

Review - microextraction techniques

More VN et al., Microextraction techniques in extraction of drugs.
International Journal of Research in Pharmacy and Chemistry, 3, (2), 330-344, (2013)
   

Review - microfluidics-chemiluminescence systems

Al Lawati HAJ, Flow-based analysis using microfluidics-chemiluminescence systems.
Luminescence, 28, (5), 618-627, (2013)
   

Review - microgel particles

Bonham JA et al., Non-aqueous microgel particles: synthesis, properties and applications.
Soft Matter, 10, (47), 9384-9398, (2014)
   

Review - micro-solid phase extraction

Boonjob W, An Overview about Recent Advances of Micro-Solid Phase Extraction in Flow Based Techniques.
Austin Journal of Analytical and Pharmaceutical Chemistry, 1, (2), Article No 6-(2014)
   

Review - mimetic enzymes in sensing

Yang B et al., Progress of Mimetic Enzymes and Their Applications in Chemical Sensors.
Critical Reviews in Analytical Chemistry, 46, (6), 469-481, (2016)
   

Review - miniaturised solid-phase extraction

Plotka-Wasylka J et al., Miniaturized solid-phase extraction techniques.
TrAC Trends in Analytical Chemistry, 73, 19-38, (2015)
   

Review - minimizing solvent use in sample preparation

Huang ZZ et al., Materials-based approaches to minimizing solvent usage in analytical sample preparation.
TrAC Trends in Analytical Chemistry, 39, 228-244, (2012)
   

Review - mini-solid-phase extraction

Book chapter, Plotka-Wasylka Jet al., Miniaturized Solid Phase Extraction, 
In: Green Extraction Techniques Principles, Advances and Applications, Ibáñez E, Cifuentes A (Eds.) Elsevier: 279-318, (2017)
   

Review - MIP and SERS in food

Feng SL et al., Molecularly imprinted polymers integrated with surface enhanced Raman spectroscopy: Innovative chemosensors in food science.
Lipid Technology, 27, (1), 14-17, (2015)
   

Review - MIP-Au nanoparticle composites in sensors

Ahmad R et al., Nanocomposites of Gold Nanoparticles@Molecularly Imprinted Polymers: Chemistry, Processing, and Applications in Sensors.
Chemistry of Materials, 27, (16), 5464-5478, (2015)
   

Review - MIP-based chiral sensors

Book chapter, Kaniewska Met al., Chiral Sensors Based on Molecularly Imprinted Polymers, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 175-194, (2012)
   

Review - MIP-based detection of antibiotics in milk

Mohsenzadeh MS et al., Simple and selective analysis of different antibiotics in milk using molecularly imprinted polymers: a review.
Food Additives & Contaminants: Part A, 35, (10), 1959-1974, (2018)
   

Review - MIP-based drug delivery

Zaidi SA, Latest trends in molecular imprinted polymer based drug delivery systems.
RSC Advances, 6, (91), 88807-88819, (2016)
   

Review - MIP-based electrochemical sensors

Book chapter, Antuña-Jiménez Det al., Molecularly Imprinted Electrochemical Sensors: Past, Present, and Future, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 1-34, (2012)
   

Review - MIP-based electrochemical sensors

Peng YY et al., Recent Innovations of Molecularly Imprinted Electrochemical Sensors Based on Electropolymerization Technique.
Current Analytical Chemistry, 11, (4), 307-317, (2015)
   

Review - MIP-based electrochemical sensors

Canfarotta F et al., Recent advances in electrochemical sensors based on chiral and nano-sized imprinted polymers.
Current Opinion in Electrochemistry, 7, 146-152, (2018)
   

Review - MIP-based electrochemical sensors

Gui RJ et al., Recent advances and future prospects in molecularly imprinted polymers-based electrochemical biosensors.
Biosensors and Bioelectronics, 100, 56-70, (2018)
   

Review - MIP-based electrochemical sensors from graphene or other nanomaterials

Zaidi SA et al., Molecularly Imprinted Polymer Electrochemical Sensors Based on Synergistic Effect of Composites Synthesized from Graphene and Other Nanosystems.
International Journal of Electrochemical Science, 9, (8), 4598-4616, (2014)
   

review - MIP-based electrochemical sensors in environmental analysis

Rebelo P et al., Molecularly imprinted polymer-based electrochemical sensors for environmental analysis.
Biosensors and Bioelectronics, 172, Article112719-(2021)
   

Review - MIP-based electroluminescence sensing

Zhang H et al., Recent Advances in Molecular Imprinting-Electrochemiluminescence Technology.
Journal of Instrumental Analysis, 35, (6), 769-776, (2016)
   

Review - MIP-based fluorescent sensor arrays

Book chapter, Tan Jet al., Discrimination of Analytes with Fluorescent Molecular Imprinting Sensor Arrays, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 161-173, (2012)
   

Review - MIP-based gas sensors

Zhang YM et al., Gas Sensors Based on Molecular Imprinting Technology.
Sensors, 17, (7), ArticleNo1567-(2017)
   

Review - MIP-based immunoassays

Baggiani C et al., MIP-based immunoassays: State of the Art, limitations and Perspectives.
Molecular Imprinting, 1, 41-54, (2013)
   

Review - MIP-based luminescent optical sensors

Book chapter, Zhao MPet al., Luminescent Optical Sensors Based on Nanoscale Molecularly Imprinted Polymers, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 237-246, (2012)
   

Review - MIP-based mass-sensitive sensors

Book chapter, Iqbal Net al., Artificial Receptors for Mass-Sensitive Sensors: Targeting Analytes from Surfaces, Nanoparticles, and Bioanalytes by Molecular Imprinting, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 195-235, (2012)
   

Review - MIP-based nano optical sensors

Book chapter, Wang SSet al., Optical Sensors Based on Molecularly Imprinted Nanomaterials, 
In: Smart Nanomaterials for Sensor Application, Li SJ, Ge Y, Li H (Eds.) (2012)
   

review - MIP-based optical sesnsing of pesticides

Fang L et al., Molecularly imprinted polymer-based optical sensors for pesticides in foods: Recent advances and future trends.
Trends In Food Science & Technology, 116, 387-404, (2021)
   

Review - MIP-based photonic crystal sensors

Chen W et al., Molecular imprinted photonic crystal for sensing of biomolecules.
Molecular Imprinting, 4, (1), 1-12, (2016)
   

Review - MIP-based potentiometric sensors

Book chapter, Javanbakht Met al., Molecularly Imprinted Polymer-Based Potentiometric Sensors for the Determination of Drugs in Pharmaceutical, Biological, and Environmental Samples, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 247-273, (2012)
   

Review - MIP-based sensors

Book chapter, Piletsky SAet al., MIP-based Sensors, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 339-354, (2012)
   

Review - MIP-based sensors

Yi N et al., Research Progress of Sensor Based Molecularly imprinted polymers.
Development and Application of Materials, (1), 117-124, (2013)
   

Review - MIP-based sensors

Yoshimi Y, Biomimetic sensors using of molecularly imprinted polymers.
IEEJ Transactions on Sensors and Micromachines, 135, (8), 305-310, (2015)
   

Review - MIP-based sensors

Uzun L et al., Molecularly-imprinted polymer sensors: realising their potential.
Biosensors and Bioelectronics, 76, 131-144, (2016)
   

review - MIP-based sensors

Kadhem AJ et al., Molecularly Imprinted Polymers (MIPs) in Sensors for Environmental and Biomedical Applications: A Review.
Molecules, 26, (20), ArticleNo6233-(2021)
   

Review - MIP-based sensors for bio-macromolecules

Ma XH et al., A Review on Bio-macromolecular Imprinted Sensors and Their Applications.
Chinese Journal of Analytical Chemistry, 44, (1), 152-159, (2016)
   

review - MIP-based sensors for COVID-19

Singhal A et al., High throughput molecularly imprinted polymers based electrochemical nanosensors for point-of-care diagnostics of COVID-19.
Materials Letters, 306, Article130898-(2022)
   

Review - MIP-based sensors for drugs and biomolecules

Yola ML et al., A Review: Molecularly Imprinted Electrochemical Sensors for Determination of Biomolecules/Drug.
Current Analytical Chemistry, 13, (1), 13-17, (2017)
   

Review - MIP-based sensors for environmental applications

Book chapter, Cao SSet al., The Fabrication and Development of Molecularly Imprinted Polymer-based Sensors for Environmental Application, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 57-72, (2012)
   

Review - MIP-based sensors for proteins

Book chapter, Jetzschmann KJet al., Label-Free MIP Sensors for Protein Biomarkers, 
In: Label-Free Biosensing: Advanced Materials, Devices and Applications, Schöning MJ, Poghossian A (Eds.) Springer International Publishing: Cham, 291-321, (2018)
   

review - MIP-based sensors incorporating carbon dots

Ansari S et al., Recent advances and future trends on molecularly imprinted polymer-based fluorescence sensors with luminescent carbon dots.
Talanta, 223, Article121411-(2021)
   

Review - MIP-based sensors in food analysis

Book chapter, Koirala Ket al., Food Biosensors Based on Molecularly Imprinted Polymers, 
In: Food Biosensors, Lim SA, Ahmed MU (Eds.) The Royal Society of Chemistry: 264-281, (2017)
   

Review - MIP-based sensors in food safety

Book chapter, Tang YWet al., Molecularly Imprinted Polymers-based Sensing in Food Safety and Quality Analysis, 
In: Sensing Techniques for Food Safety and Quality Control, Lu XN (Ed.) The Royal Society of Chemistry: 164-199, (2017)
   

review - MIP-based sensors in food safety

Cao YR et al., Recent advances of molecularly imprinted polymer-based sensors in the detection of food safety hazard factors.
Biosensors and Bioelectronics, 141, Article111447-(2019)
   

review - MIP-based sensors in medicine

Saylan Y et al., Molecularly Imprinted Polymer Based Sensors for Medical Applications.
Sensors, 19, (6), ArticleNo1279-(2019)
   

Review - MIP-based sol-gel sensors

Book chapter, Meng ZH, Molecularly Imprinted Sol-Gel Sensors, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 303-337, (2012)
   

Review - MIP-based SPR sensors

Book chapter, Cyago Aet al., Surface Plasmon Resonance Spectroscopy and Molecularly Imprinted Polymer (MIP) Sensors, 
In: Handbook of Spectroscopy, Gauglitz G, Advincula R (Eds.) Wiley-VCH Verlag GmbH & Co. KGaA: Weinheim, 1229-1258, (2014)
   

Review - MIP-based voltammetric sensors for pesticide residues

Kamel AH et al., Assessment of pesticides in environmental samples using voltammetric molecular imprinted based sensors: A review.
European Chemical Bulletin, 5, (2), 69-76, (2016)
   

Review - MIP beads

Book chapter, Ye Let al., Molecularly imprinted polymer beads, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 435-454, (2005)
   

Review - MIP binding properties

Book chapter, Ansell RJ, Characterization of the Binding Properties of Molecularly Imprinted Polymers, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 51-93, (2015)
   

Review - MIP catalyst design and synthesis

Book chapter, Mujahid Aet al., Molecularly Imprinted Polymers: Principle, Design, and Enzyme-Like Catalysis, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 79-101, (2016)
   

review - MIP catalysts

Li XT et al., Targeted degradation of refractory organic compounds in wastewaters based on molecular imprinting catalysts.
Water Research, 203, Article117541-(2021)
   

Review - MIP characterization

De Middeleer G et al., Characterization of MIP and MIP functionalized surfaces: Current state-of-the-art.
TrAC Trends in Analytical Chemistry, 76, 71-85, (2016)
   

Review - MIP composites

Zaidi SA, Molecular imprinting polymers and their composites: a promising material for diverse applications.
Biomaterials Science, 5, (3), 388-402, (2017)
   

Review - MIP core-shell nanoparticles

Niu MC et al., Core-shell nanoparticles coated with molecularly imprinted polymers: a review.
Microchimica Acta, 183, (10), 2677-2695, (2016)
   

Review - MIP core-shell particles

Wan LB et al., Core-shell molecularly imprinted particles.
TrAC Trends in Analytical Chemistry, 95, 110-121, (2017)
   

Review - MIP cryogels

Wang J et al., Research Progress of the Molecularly Imprinted Cryogel.
Chinese Journal of Analytical Chemistry, 43, (11), 1777-1784, (2015)
   

Review - MIP cryogels

Andaç M et al., Affinity based and molecularly imprinted cryogels: Applications in biomacromolecule purification.
Journal of Chromatography B, 1021, 69-80, (2016)
   

Review - MIP cryogels for protein purification

Book chapter, Andaç Met al., Molecularly Imprinted Cryogels for Protein Purification, 
In: Biomaterials from Nature for Advanced Devices and Therapies, Neves NM, Reis RG (Eds.) Wiley: 403-428, (2016)
   

Review - MIP design by computational and chemometric methods

Wu X et al., Chemometric and Computational Strategies for Rational Design of Molecularly Imprinted Polymer.
Current Organic Chemistry, 20, (4), 459-468, (2016)
   

Review - MIP electrochemical sensors

Malitesta C et al., MIP sensors - the electrochemical approach.
Analytical and Bioanalytical Chemistry, 402, (5), 1827-1846, (2012)
   

Review - MIP films and membranes

Book chapter, Ulbricht M, Molecularly imprinted polymer films and membranes, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 455-490, (2005)
   

Review - MIP formats

Book chapter, Pérez-Moral Net al., MIP formats for analytical applications, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 1-11, (2006)
   

Review - MIP grafted sensing layers

Bakas I et al., Molecularly imprinted polymeric sensings layers grafted from aryl diazonium-modified surfaces for electroanalytical applications. A mini review.
Surface And Interface Analysis, 46, (10-11), 1014-1020, (2014)
   

Review - MIP hydrogels

Byrne ME et al., Molecular imprinting within hydrogels.
Advanced Drug Delivery Reviews, 54, (1), 149-161, (2002)
   

Review - MIP hydrogels

Book chapter, Sobiech Met al., Imprinted Polymeric Gels for Pharmaceutical and Biomedical Purposes, 
In: Polymer Gels: Perspectives and Applications, Thakur VK, Thakur MK, Voicu SI (Eds.) Springer Singapore: Singapore, 153-183, (2018)
   

Review - MIP hydrogels in diagnostics

Book chapter, El-Sharif HFet al., Hydrogel-Based Molecularly Imprinted Polymers for Biological Detection, 
In: Advanced Synthetic Materials in Detection Science, Reddy SM (Ed.) The Royal Society of Chemistry: Cambridge, 75-115, (2014)
   

Review - MIP impedimetric sensors

Proceeding, Lagarde F, MIP-Based Impedimetric Sensors, 
In: Key Engineering Materials, Hristoforou E, Vlachos DS (Eds.), 499-502, (2013)
   

Review - MIP in mycotxin analysis

He QH et al., Application of Molecular Imprinting Technique in Determination of Mycotoxin.
Food Science, 30, (11), 273-275, (2009)
   

Review - MIP intelligent hydrogels

Sun J et al., Intelligent molecular imprinted hydrogel.
Chemical Sensors (China), 25, (3), 1-6, (2005)
   

Review - MIP magnetic microspheres

Wei SM et al., Application progress of magnetic molecularly imprinted polymer microspheres.
New Chemical Materials, 40, (6), 127-129, (2012)
   

Review - MIP membrane-based sensors

Algieri C et al., Bio-Mimetic Sensors Based on Molecularly Imprinted Membranes.
Sensors, 14, (8), 13863-13912, (2014)
   

Review - MIP membranes

Jiang ZY et al., Preparation and applications of molecularly imprinted polymer membranes.
Membrane Science and Technology, 26, (1), 78-84, (2006)
   

Review - MIP membranes

Xia SL et al., Review of Research on Molecular Recognition Polymeric Membranes.
Materials Review, 21, (4), 31-33, (2007)
   

Review - MIP membranes

Jiao CC et al., Preparation and Influence Factors of Composite Molecular Imprinted Membranes.
Chemical Industry and Engineering, 27, (4), 358-364, (2010)
   

Review - MIP membranes

Yoshikawa M et al., Molecularly imprinted nanofiber membranes.
Current Opinion in Chemical Engineering, 1, (1), 18-26, (2011)
   

Review - MIP membranes

Trotta F et al., Molecularly Imprinted Membranes.
Membranes, 2, (3), 440-447, (2012)
   

Review - MIP membranes

Yoshikawa M et al., Molecularly Imprinted Membranes: Past, Present, and Future.
Chemical Reviews, 116, (19), 11500-11528, (2016)
   

review - MIP membranes

Yang H et al., Synthesis, performance, and application of molecularly imprinted membranes: A review.
Journal of Environmental Chemical Engineering, 9, (6), Article106352-(2021)
   

Review - MIP membranes from biomolecule separation and sensing

Boysen RI et al., Molecularly imprinted polymer membranes and thin films for the separation and sensing of biomacromolecules.
Journal of Separation Science, 40, (1), 314-335, (2017)
   

Review - MIP membranes from cellulose acetate

Book chapter, Yoshikawa Met al., Application of Membranes from Cellulose Acetate Nanofibers, 
In: Handbook of Polymer Nanocomposites. Processing, Performance and Application, Pandey JK, Takagi H, Nakagaito AN, Kim HJ (Eds.) Springer: Berlin, Heidelberg, 369-394, (2015)
   

Review - MIP micromonoliths

Book chapter, Brazier JJet al., Micromonoliths and microfabricated molecularly imprinted polymers, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 491-516, (2005)
   

Review - MIP microspheres

Zhang LY et al., Progress in Preparation Processes of Molecularly Imprinted Polymeric Microspheres.
Materials Review, 15, (1), 60-61, (2001)
   

Review - MIP microspheres

Zhang LY et al., Preparation and Application of Molecularly Imprinted Polymers Microspheres.
Chinese High Technology Letters, 12, (7), 108-110+107, (2002)
   

Review - MIP microspheres

Jiang XH et al., Research Progress in Preparation of Molecularly Imprinted Polymer Microspheres.
Materials Review, 21, (12), 52-55, (2007)
   

Review - MIP microspheres

Lai JP et al., Progresses on Synthesis Methods of Molecularly Imprinted Microspheres and Their Applications in Solid phase Extraction.
Journal of Instrumental Analysis, 31, (9), 1161-1169, (2012)
   

Review - MIP microspheres synthesis

Book chapter, Lim KFet al., Advances and Challenges in the Design and Synthesis of Molecularly Imprinted Microspheres, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 55-77, (2016)
   

Review - MIP microsphere synthesis

Kang YF et al., Research progress in preparation of molecularly imprinted polymer microspheres.
New Chemical Materials, 40, (2), 38-40, (2012)
   

Review - MIP modelling approaches

Book chapter, Nicholls IAet al., Theoretical and Computational Strategies for the Study of the Molecular Imprinting Process and Polymer Performance, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 25-50, (2015)
   

Review - MIP-modified electrodes for sensing

Cervini P et al., Strategies for Preparation of Molecularly Imprinted Polymers Modified Electrodes and Their Application in Electroanalysis: A Review.
Analytical Letters, 45, (4), 297-313, (2012)
   

Review - MIP-modified TiO2 nanomaterials

Sun LN et al., Synthesis and Applications of Molecularly Imprinted Polymers Modified TiO2 Nanomaterials: A Review.
Polymers, 10, (11), ArticleNo1248-(2018)
   

Review - MIP monolithic columns

Liu HY et al., Monolithic molecularly imprinted columns for chromatographic separation.
Chromatographia, 61, (9-10), 429-432, (2005)
   

Review - MIP monolithic columns

Xue QH, Preparation and Application of Molecularly Imprinted Monolithic Column.
Journal of Qinghai Normal University (Natural Science Edition), (3), 57-60, (2009)
   

Review - MIP monolithic columns

Zheng C et al., Recent developments and applications of molecularly imprinted monolithic column for HPLC and CEC.
Journal of Separation Science, 34, (16-17), 1988-2002, (2011)
   

Review - MIP monoliths

Tan J et al., Molecularly-imprinted monoliths for sample treatment and separation.
TrAC Trends in Analytical Chemistry, 39, 207-217, (2012)
   

Review - MIP monoliths in analytical science

Wei ZH et al., Imprinted monoliths: Recent significant progress in analysis field.
TrAC Trends in Analytical Chemistry, 86, 84-92, (2017)
   

Review - MIP monoliths in HPLC

Zheng C et al., Synthesis and theoretical study of molecularly imprinted monoliths for HPLC.
Analytical and Bioanalytical Chemistry, 405, (7), 2147-2161, (2013)
   

Review - MIP nanofibres

Zaidi SA, Recent developments in molecularly imprinted polymer nanofibers and their applications.
Analytical Methods, 7, (18), 7406-7415, (2015)
   

Review - MIP nanomaterials

Book chapter, Takeuchi Tet al., Molecularly Imprinted Polymers, 
In: Encyclopedia of Polymeric Nanomaterials, Kobayashi S, Müllen K (Eds.) Springer: Berlin, Heidelberg, 1-5, (2014)
   

Review - MIP nanomaterials

Beyazit S et al., Molecularly imprinted polymer nanomaterials and nanocomposites by controlled/living radical polymerization.
Progress in Polymer Science, 62, 1-21, (2016)
   

Review - MIP nanomaterials in analytical chemistry

Keçili R et al., Recent Progress of Imprinted Nanomaterials in Analytical Chemistry.
International Journal of Analytical Chemistry, 2018, ArticleID8503853-(2018)
   

Review - MIP nanomaterials in protein recognition

Lv YQ et al., Molecular imprinting of proteins in polymers attached to the surface of nanomaterials for selective recognition of biomacromolecules.
Biotechnology Advances, 31, (8), 1172-1186, (2013)
   

Review - MIP nanomaterials in sensing

Zhong CJ et al., Current Progress of Nanomaterials in Molecularly Imprinted Electrochemical Sensing.
Critical Reviews in Analytical Chemistry, 48, (1), 15-32, (2018)
   

Review - MIP nanoparticles

Poma A et al., Advances in the manufacture of MIP nanoparticles.
Trends In Biotechnology, 28, (12), 629-637, (2010)
   

Review - MIP nanoparticles

Book chapter, Poma Aet al., Plastic Antibodies, 
In: Designing Receptors for the Next Generation of Biosensors, Piletsky SA, Whitcombe MJ (Eds.) Springer: Berlin, Heidelberg, 105-129, (2013)
   

Review - MIP nanoparticles

Wackerlig J et al., Applications of Molecularly Imprinted Polymer Nanoparticles and Their Advances toward Industrial Use: A Review.
Analytical Chemistry, 88, (1), 250-261, (2016)
   

Review - MIP nanoparticles

Book chapter, Sobiech Met al., Imprinted polymeric nanoparticles as nanodevices, biosensors and biolabels, 
In: Nanostructures for the Engineering of Cells, Tissues and Organs, Grumezescu AM (Ed.) William Andrew Publishing: 331-374, (2018)
   

Review - MIP nanoparticles in sensing

Wackerlig J et al., Molecularly imprinted polymer nanoparticles in chemical sensing - Synthesis, characterisation and application.
Sensors and Actuators B: Chemical, 207, (Part A), 144-157, (2015)
   

Review - MIP nanoparticles surface imprinted

Ding XC et al., Recent Developments in Molecularly Imprinted Nanoparticles by Surface Imprinting Techniques.
Macromolecular Materials And Engineering, 299, (3), 268-282, (2014)
   

Review - MIP nanosensors and medical devices

Book chapter, Prasad BBet al., Molecularly Imprinted Nanomaterial-based Highly Sensitive and Selective Medical Devices, 
In: Biomedical Materials and Diagnostic Devices, Tiwari A, Ramalingam M, Kobayashi H, Turner APF (Eds.) John Wiley & Sons, Inc.: 339-391, (2012)
   

Review - MIP optical fibre sensors

Gupta BD et al., Surface Plasmon Resonance-Based Fiber Optic Sensors Utilizing Molecular Imprinting.
Sensors, 16, (9), ArticleNo1381-(2016)
   

Review - MIP-QCM sensors for molecules and cells

Latif U et al., Biomimetic Receptors for Bioanalyte Detection by Quartz Crystal Microbalances - From Molecules to Cells.
Sensors, 14, (12), 23419-23438, (2014)
   

Review - MIP Ru-based catalysts

Muratsugu S et al., Molecularly Imprinted Ru Complex Catalysts Integrated on Oxide Surfaces.
Accounts of Chemical Research, 46, (2), 300-311, (2012)
   

Review - MIPs

Kunieda T, Selective memory of synthetic macromolecules for their origins.
Journal of Synthetic Organic Chemistry Japan, 40, (8), 686-693, (1982)
   

Review - MIPs

Mosbach K, Molecular imprinting.
Trends In Biochemical Sciences, 19, (1), 9-14, (1994)
   

Review - MIPs

Mosbach K et al., The emerging technique of molecular imprinting and its future impact on biotechnology.
Bio/Technology, 14, 163-170, (1996)
   

Review - MIPs

Takeuchi T et al., Molecular imprinting: An approach to ’’tailor-made’’ synthetic polymers with biomimetic functions.
Acta Polymerica, 47, (11-12), 471-480, (1996)
   

Review - MIPs

Wulff G, Molecular imprinting in crosslinked polymers - The role of the binding sites.
Molecular Crystals And Liquid Crystals Science And Technology Section A-Molecular Crystals And Liquid Crystals, 276, 1-6, (1996)
   

Review - MIPs

Liu JQ et al., Molecular Imprinting Polymer and its Application.
Journal of Functional Polymers, 11, (4), 561-565, (1998)
   

Review - MIPs

Book chapter, Mosbach Ket al., Molecular imprinting: Status artis et quo vadere?, 
In: Molecular and Ionic Recognition with Imprinted Polymers, Bartsch RA, Maeda M (Eds.) The American Chemical Society: Washington DC, 29-48, (1998)
   

Review - MIPs

Mosbach K et al., Some new developments and challenges in non-covalent molecular imprinting technology.
Journal of Molecular Recognition, 11, (1-6), 62-68, (1998)
   

Review - MIPs

Brüggemann O et al., New configurations and applications of molecularly imprinted polymers.
Journal of Chromatography A, 889, (1-2), 15-24, (2000)
   

Review - MIPs

Qu XJ et al., Progress in the preparation of molecular imprinted polymer.
Journal of Shandong Agricultural University (Natural Science), 31, (4), 457-462, (2000)
   

Review - MIPs

Book chapter, Spivak D, Molecular Imprinting, 
In: Kirk-Othmer Encyclopedia of Chemical Technology, John Wiley & Sons, Inc.: (2000)
   

Review - MIPs

Sui HY et al., Molecular Imprinting Technique - A New Affinity Separation Method.
Chemical Industry and Engineering Progress, 19, (5), 43-46, (2000)
   

Review - MIPs

Lai JP et al., A review on molecular imprinting technique.
Chinese Journal of Analytical Chemistry, 29, (7), 836-844, (2001)
   

Review - MIPs

Lei J et al., Molecular imprinting and its applications.
Modern Chemical Industry, 21, (4), 17-20, (2001)
   

Review - MIPs

Li HT et al., MOLECULAR IMPRINTED POLYMERS--Novel Polymer Adsorbents.
Chinese Journal of Reactive Polymers, 10, (1), 84-94, (2001)
   

Review - MIPs

Mosbach K, Toward the next generation of molecular imprinting with emphasis on the formation, by direct molding, of compounds with biological activity (biomimetics).
Analytica Chimica Acta, 435, (1), 3-8, (2001)
   

Review - MIPs

Wang YJ et al., Progres in the study of molecular imprinted polymers.
Ion Exchange and Adsorption, 17, (4), 360-368, (2001)
   

Review - MIPs

Book chapter, Yilmaz Eet al., The use of imprinted polymers as recognition elements in biosensors and binding assays, 
In: Novel Approaches In Biosensors And Rapid Diagnostic Assays, Liron Z, Bromberg A, Fisher M (Eds.) Kluwer Academic/Plenum Publishers: New York, 193-209, (2001)
   

Review - MIPs

Ying TL et al., Highly selective technique-molecular imprinting.
Chinese Journal of Analytical Chemistry, 29, (1), 99-102, (2001)
   

Review - MIPs

Yoshikawa M, Molecularly Imprinted Polymers.
Membrane, 26, (1), 39-45, (2001)
   

Review - MIPs

Jiang ZY et al., Molecular Imprinting Technology and Its Application.
Petrochemical Technology, 31, (8), 668-670, (2002)
   

Review - MIPs

Liu XL et al., The application and advancement of molecular imprinting technology.
Chinese Journal of Analytical Chemistry, 30, (10), 1260-1266, (2002)
   

Review - MIPs

Shi RX et al., Research on Selective Mechanism of Molecularly Imprinted polymer.
Chemical Sensors (China), 22, (3), 49-57, (2002)
   

Review - MIPs

Wan TX et al., Molecular Imprinting Technology and Its Applies.
Liaoning Chemical Industry, 31, (5), 214-217, (2002)
   

Review - MIPs

Wang QL et al., Techology and Application of Molecular Imprinting.
Food Science, 23, (9), 140-143, (2002)
   

Review - MIPs

Zhang XW et al., Molecular Imprinting Technique and Its Application.
Journal of Tianjin Agricultural College, 9, (3), 23-28, (2002)
   

Review - MIPs

Zhou XX et al., Progress of Molecule Imprinting Polymers.
Journal of Sichuan University of Science & Engineering (Natural Science Edition), 15, (3), 44-47, (2002)
   

Review - MIPs

Zhou XX et al., Progress of Molecule Imprinting Polymers.
Journal of Sichuan University of Science & Engineering (Natural Sicence Edition), 15, (3), 44-47, (2002)
   

Review MIPs

Bao GL et al., Progress of Molecular Imprinting Technique.
Chemical Sensors (China), 23, (1), 1-10, (2003)
   

Review - MIPs

Dong WG et al., Molecular Imprinting Technology and its Applications in Biochemical Engineering.
Chemical Industry and Engineering Progress, 22, (7), 683-688, (2003)
   

Review - MIPs

Haupt K, Imprinted polymers - Tailor-made mimics of antibodies and receptors.
Chemical Communications, (2), 171-178, (2003)
   

Review - MIPs

Hu XG et al., Progress in preparation technique of molecularly imprinted polymer.
Journal of South China Normal University (Natural Science Edition), (3), 150-157, (2003)
   

Review - MIPs

Jiang ZY, Preparation and Applications of Molecularly Imprinted Polymers.
Chemical World, 44, (2), 105-108, (2003)
   

Review - MIPs

Ren J et al., The Development of Research in Molecular Imprinting Technique.
Biotechnology Bulletin, (4), 19-21, (2003)
   

Review - MIPs

Xu WJ et al., Progress in Researches on Molecular Imprinting Polymers Based on Silica-gel Surface Modification.
Chinese Journal of Applied Chemistry, 20, (10), 919-923, (2003)
   

Review - MIPs

Zhang QZ et al., Molecular Imprinting Polymer.
Materials Review, 17, (z1), 194-196, (2003)
   

Review - MIPs

Jiang ZY, Design and preparation of molecularly imprinted polymers.
Polymer Materials Science and Engineering, 20, (3), 25-28, (2004)
   

Review - MIPs

Lan LX, Study of molecularly imprinting technology and its application.
Technological Development of Enterprise, 23, (11), 3-5, (2004)
   

Review - MIPs

Liu YQ et al., Principles of Molecular Imprinting and Synthesis of Its Polymers.
Journal of Weinan Teachers College, 19, (2), 30-32, (2004)
   

Review - MIPs

Tan SZ et al., Study and application of the molecular imprinting technique.
Applied Chemical Industry, 33, (4), 4-6,10, (2004)
   

Review - MIPs

Wu WX, Molecular Imprinting Technique and Its Applications.
Journal of Langfang Teachers College, 20, (4), 11-15,122, (2004)
   

Review - MIPs

Zhang LL et al., Application of molecular imprinting technique in medicine and chemical engineering.
Chemical Engineer, 20, (12), 48-50, (2004)
   

Review - MIPs

Book chapter, Hall AJet al., Imprinted polymers, 
In: Templates in Chemistry II, Schalley CA, Vögtle F, Dötz KH (Eds.) Springer Verlag: Berlin, 317-349, (2005)
   

Review - MIPs

Book chapter, Haupt K, Molecularly Imprinted Polymers: Artificial Receptors for Affinity Separations, 
In: Handbook of Affinity Chromatography, Second Edition, Hage DS (Ed.) CRC Press: 837-856, (2005)
   

Review - MIPs

Book chapter, Komiyama M, Molecular Imprinting, 
In: Supramolecular Polymers, Ciferri A (Ed.) CRC Press: Boca Raton, 711-724, (2005)
   

Review - MIPs

Kuzmic AE, The synthesis and application of molecularly imprinted polymers [Sinteza i primjena molekulski tiskanih polimera].
Polimeri (Zagreb), 25, (4), 122-131, (2005)
   

Review - MIPs

Liu WQ et al., Molecular Imprinting Technique (MIT).
Jiangxi Chemical Industry, (1), 30-31,22, (2005)
   

Review - MIPs

Liu YQ et al., Progress of the Applied Study on Molecular Imprinting Technique.
Journal of Weinan Teachers College, 20, (2), 43-45,51, (2005)
   

Review - MIPs

Book chapter, Marty JDet al., Molecular imprinting: State of the art and perspectives, 
In: Microlithography/Molecular Imprinting, Ito H, Marty JD (Eds.) Springer-Verlag GmbH: 1-35, (2005)
   

Review - MIPs

O’Mahony J et al., Molecularly imprinted polymers - potential and challenges in analytical chemistry.
Analytica Chimica Acta, 534, (1), 31-39, (2005)
   

Review - MIPs

Wang H et al., Preparation and Application of Molecularly Imprinted Polymers.
Chemical Industry and Engineering, 22, (5), 367-370, (2005)
   

Review - MIPs

Wang H et al., Advances in Molecularly Imprinted Polymers:From Small Molecules Towards Biological Macromolecules.
Chinese Polymer Bulletin, (1), 86-93, (2005)
   

Review - MIPs

Wu ZH, Application of molecular imprinting technique in pharmaceutical science.
Journal of China Pharmaceutical University, 36, (5), 477-480, (2005)
   

Review - MIPs

Zhou Q et al., Application of Molecular Imprinting Technique in the Environmental Field.
Bulletin of Science and Technology, 21, (1), 110-114, (2005)
   

Review - MIPs

Book chapter, Anon, Molecular Imprints, 
In: Encyclopedic Reference of Genomics and Proteomics in Molecular Medicine, Ganten D, Ruckpaul K (Eds.) Springer: Berlin, Heidelberg, 1160, (2006)
   

Review - MIPs

Alexander C et al., Molecular imprinting science and technology: a survey of the literature for the years up to and including 2003.
Journal of Molecular Recognition, 19, (2), 106-180, (2006)
   

Review - MIPs

Cao BQ et al., Synthetic Progress of Molecularly Imprinted Polymers.
Modern Scientific Instruments, (6), 29-33, (2006)
   

Review - MIPs

Chen CB et al., Progress in molecular imprinting technique.
Chemical Research and Application, 18, (8), 896-902, (2006)
   

Review - MIPs

Book chapter, Cormack PAG, Imprinted polymers, 
In: Encyclopedia of Supramolecular Chemistry, Atwood JL, Steed JW (Eds.) Taylor and Francis: (2006)
   

Review - MIPs

Liu ZH et al., Progress in the Application of MIPs.
Science and Technology Review, 24, (1), 51-54, (2006)
   

Review - MIPs

Ma SJ et al., New Progress in Molecular Imprinting Technique.
Journal of Shanxi Normal University (Natural Science Edition), 20, (2), 59-63, (2006)
   

Review - MIPs

Wang J et al., Advances of Application of Molecular Imprinting Technology.
Chemistry & Bioengineering, 23, (4), 4-6, (2006)
   

Review - MIPs

Wei ST et al., Capturing molecules with templated materials--Analysis and rational design of molecularly imprinted polymers.
Analytica Chimica Acta, 578, (1), 50-58, (2006)
   

Review - MIPs

Yan H et al., Characteristic and synthetic approach of molecularly imprinted polymer.
International Journal of Molecular Sciences, 7, (5-6), 155-178, (2006)
   

Review - MIPs

Jiang XM et al., Small organic molecular imprinted materials: their preparation and application.
Analytical and Bioanalytical Chemistry, 389, (2), 355-368, (2007)
   

Review - MIPs

Li R et al., Progress on the application of molecular imprinting polymers.
Acta Academiae Medicinae CPAPF, 16, (3), 325-327, (2007)
   

Review - MIPs

Book chapter, Li WKet al., Molecular Imprinting: A Versatile Tool for Separation, Sensors and Catalysis, 
In: Oligomers - Polymer Composites - Molecular Imprinting, Springer-Verlag: Berlin, 191-210, (2007)
   

Review - MIPs

Proceeding, Moreno-Bondi MC et al, Molecularly imprinted polymers as biomimetic receptors for fluorescence-based optical sensors, 
Cutolo A, Culshaw B, López-Higuera JM (Eds.), Art. No. 66190C, (2007)
   

Review - MIPs

Book chapter, Shimizu KDet al., Molecularly Imprinted Polymers, 
In: Encyclopedia of Chemical Processing, Lee SG (Ed.) Taylor & Francis: 1737-1746, (2007)
   

Review - MIPs

Wang XJ et al., Molecular recognition in aqueous media with molecular imprinting technique.
Progress In Chemistry, 19, (5), 805-812, (2007)
   

Review - MIPs

Book chapter, Wulff G, Templated Synthesis of Polymers - Molecularly Imprinted Materials for Recognition and Catalysis, 
In: Templated Organic Synthesis, Diederich F, Stang PJ (Eds.) Wiley-VCH: Weinheim, 39-73, (2007)
   

Review - MIPs

Xiao SJ et al., Application of molecularly imprinted polymers in separation fields.
New Chemical Materials, 35, (2), 4-5,8, (2007)
   

Review - MIPs

Book chapter, Dufaud Vet al., Molecular Imprinting, 
In: Nanomaterials and Nanochemistry, Bréchignac C, Houdy P, Lahmani M (Eds.) Springer: Berlin, 597-614, (2008)
   

Review - MIPs

Liu MM, The Molecular Design and Optimization of Molecular Imprinted Polymers.
Hebei Chemical Engineering and Industry, 31, (7), 20-22, (2008)
   

Review - MIPs

Ma YZ et al., Synthesis Progress in Molecular Imprinted Polymer.
Journal of Hebei Institute of Technology, 30, (4), 96-99, (2008)
   

Review - MIPs

Ooya T et al., Molecularly Imprinted Polymers: Covering from Molecular Level to Polymeric Material Level.
Kobunshi, 57, (11), 903-906, (2008)
   

Review - MIPs

Shelke CR et al., Synthesis and characterization of MIPs - a viable commercial venture.
Pharmaceutical Reviews, 6, (5), (2008)
   

Review - MIPs

Su J et al., Molecular imprinted polymer(MIP)and its application.
Journal of Shandong University of Technology (Natural Science Edition), 22, (6), 90-95, (2008)
   

Review - MIPs

Wang RY et al., New Progress and Application of Molecular Imprinting Technique.
Modern Scientific Instruments, (1), 11-16, (2008)
   

Review - MIPs

BelBruno JJ, Molecularly Imprinted Polymers: Artificial Receptors with Wide-Ranging Applications.
Micro and Nanosystems, 1, (3), 163-180, (2009)
   

Review - MIPs

Book chapter, Kempe Het al., Molecularly Imprinted Polymers, 
In: The Power of Functional Resins in Organic Synthesis, Tulla-Puche J, Albericio F (Eds.) Wiley-VCH: Weinheim, 15-44, (2009)
   

Review - MIPs

Liang JH et al., Progress and principle of molecular imprinting technique.
Journal of Chongqing University of Arts and Sciences, 28, (5), 38-43, (2009)
   

Review - MIPs

Ma TJ et al., Applications of Molecular Imprinting Technique in the Detection of Pesticides.
Academic Periodical of Farm Products Processing, (9), 29-32,35, (2009)
   

Review - MIPs

Qi XL et al., The synthetic methods and application of molecularly printed polymers.
Chemical Research and Application, 21, (4), 441-449, (2009)
   

Review - MIPs

Wang Y et al., Molecular imprinting technology and its application.
Chemical Industry and Engineering Progress, 29, (12), 2315-2323, (2010)
   

Review - MIPs

Xi S et al., Progress in Preparation of New Molecularly Imprinted Polymer Hybrid Membranes.
Development and Application of Materials, 25, (6), 67-72, (2010)
   

Review - MIPs

Book chapter, Atta NFet al., Molecular imprinting: State of the art and applications, 
In: Molecular Recognition: Biotechnology, Chemical Engineering and Materials Applications, McEvoy JA (Ed.) Nova Science Publishers, Inc.: New York, 151-174, (2011)
   

Review - MIPs

Chen LX et al., Recent advances in molecular imprinting technology: current status, challenges and highlighted applications.
Chemical Society Reviews, 40, (5), 2922-2942, (2011)
   

Review - MIPS

Feng XW et al., The Application of Molecular Imprinting Technologies on Active Ingredients Extraction and Purification from Natural Drug.
Guangdong Chemical Industry, 38, (2), 71-72, (2011)
   

Review - MIPs

Book chapter, Li SJet al., Molecular Imprinting: a Biomimetic Tool for Highly Selective Separation, Sensing and Catalysis, 
In: Smart Polymer Materials for Biomedical Applications, Li SJ, Tiwari A, Prabaharan M, Aryal S (Eds.) Nova Science Publishers Inc.: New York, 1-16, (2011)
   

Review - MIPs

Vasapollo G et al., Molecularly Imprinted Polymers: Present and Future Prospective.
International Journal of Molecular Sciences, 12, (9), 5908-5945, (2011)
   

Review - MIPs

Wang XH et al., Preparation and Application of Molecularly Imprinted Polymers.
Shanghai Plastics, (3), 1-4, (2011)
   

Review - MIPs

Bhole N et al., Molecular imprinting: A pharmaceutical Approach.
Journal of Chemical, Biological and Physical Sciences, 2, (1), 292-297, (2012)
   

Review - MIPs

Denderz N et al., Molecularly imprinted polymers.
Ceska a Slovenska Farmacie, 61, (3), 79-86, (2012)
   

Review - MIPs

Book chapter, Haupt Ket al., Molecularly Imprinted Polymers, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 1-28, (2012)
   

Review - MIPs

Book chapter, Martín-Esteban Aet al., 2.17 - Molecularly Imprinted Polymers, 
In: Comprehensive Sampling and Sample Preparation, Pawliszyn J (Ed.) Academic Press: Oxford, 331-344, (2012)
   

Review - MIPs

Philip JYN et al., Molecularly imprinted polymer technology: a powerful, generic, facile and cost effective alternative for enantio-recognition and separation: a glance at advances and applications.
Tanzania Journal of Science, 38, (3), 72-83, (2012)
   

Review - MIPs

Book chapter, Piletsky SAet al., Molecularly Imprinted Polymers, 
In: Encyclopedia of Biophysics, Roberts GCK (Ed.) Springer: 1596-1599, (2012)
   

Review - MIPs

Book chapter, Sellergren Bet al., Molecularly Imprinted Polymers, 
In: Supramolecular Chemistry, Gale P, Steed J (Eds.) John Wiley & Sons, Ltd: 3255-3282, (2012)
   

Review - MIPs

Shah N et al., A Brief Overview of Molecularly Imprinted Polymers: From Basics to Applications.
Journal of Pharmacy Research, 5, (6), 3309-3317, (2012)
   

Review - MIPs

Zhang XX et al., Synthesis and Application of Molecularly Imprinted Polymer.
Guangzhou Chemical Industry, 40, (9), 6-10, (2012)
   

Review - MIPs

Cheong WJ et al., Molecular imprinted polymers for separation science: A review of reviews.
Journal of Separation Science, 36, (3), 609-628, (2013)
   

Review - MIPs

Shang HZ et al., Recent research development of molecular imprinting polymer.
Modern Chemical Industry, 33, (12), 28-30,32, (2013)
   

Review - MIPs

Szatkowska P et al., Molecularly Imprinted Polymers’ Applications: A Short Review.
Mini-Reviews in Organic Chemistry, 10, (4), 400-408, (2013)
   

Review - MIPs

Proceeding, Xiao SJ et al, Research Progress of Molecular Imprinting Technology, 
In: Advanced Materials Research, Bu JL, Kim YH (Eds.), 1678-1681, (2013)
   

Review - MIPs

Zhang TT et al., Research on Progress of Molecular Imprinting Technology.
Chemical Intermediate, (11), 15-18, (2013)
   

Review - MIPs

Chen XJ et al., The application of molecular imprinting technique in analysis and test.
Journal of Food Safety and Quality, 5, (5), 1459-1467, (2014)
   

Review - MIPs

Book chapter, Deng QLet al., Molecularly imprinted polymers (MIPs) - an emerging technique for chemical hazard determination, 
In: Food Chemical Hazard Detection: Development and Application of New Technologies, Wang S (Ed.) Wiley-Blackwell: Chichester, 137-172, (2014)
   

Review - MIPs

Whitcombe MJ et al., Molecular imprinting science and technology: a survey of the literature for the years 2004-2011.
Journal of Molecular Recognition, 27, (6), 297-401, (2014)
   

Review - MIPs

Hussain M, ’Molecular Imprinting’ as Multidisciplinary Material Science: Today and Tomorrow.
International Journal of Advanced Materials Research, 1, (5), 347-351, (2015)
   

Review - MIPs

Book chapter, Takeuchi Tet al., Molecularly Imprinted Polymers, 
In: Encyclopedia of Polymeric Nanomaterials, Kobayashi S, Müllen K (Eds.) Springer: Berlin, Heidelberg, 1291-1295, (2015)
   

Review - MIPs

Zhao M et al., The Application of Molecularly Imprinted Polymers.
Journal of Materials Science and Chemical Engineering, 3, 87-89, (2015)
   

Review - MIPs

Chen LX et al., Molecular imprinting: perspectives and applications.
Chemical Society Reviews, 45, (8), 2137-2211, (2016)
   

Review - MIPs

Machynakova A et al., The Possibilities of Preparation of Molecularly Imprinted Polymers.
Chemicke Listy, 110, (9), 609-615, (2016)
   

Review - MIPs

Takeuchi T et al., Molecularly Imprinted Tailor-Made Functional Polymer Receptors for Highly Sensitive and Selective Separation and Detection of Target Molecules.
Chromatography, 37, (2), 43-64, (2016)
   

Review - MIPs

Kubo T, Molecularly Imprinted Materials in Analytical Chemistry.
Analytical Sciences, 33, (12), 1321-1322, (2017)
   

Review - MIPs

Huang Y et al., Review on Fundamentals, Preparations and Applications of Imprinted Polymers.
Current Organic Chemistry, 22, (16), 1600-1618, (2018)
   

review - MIPs

BelBruno JJ, Molecularly Imprinted Polymers.
Chemical Reviews, 119, (1), 94-119, (2019)
   

review - MIPs

Book chapter, Kubo Tet al., Molecularly Imprinted Materials, 
In: Handbook of Smart Materials in Analytical Chemistry, de la Guardia M, Esteve-Turrillas FA (Eds.) Wiley: 159-178, (2019)
   

review - MIPs

Merdas SM, Molecular Imprinting: Fundamentals and Applications.
University of Thi-Qar Journal, 16, (2), 19-51, (2021)
   

review - MIPs

Sajini T et al., A brief overview of molecularly imprinted polymers: Highlighting computational design, nano and photo-responsive imprinting.
Talanta Open, 4, Article100072-(2021)
   

review - MIPs

Zhang GY et al., Mesoporous molecularly imprinted materials: From preparation to biorecognition and analysis.
TrAC Trends in Analytical Chemistry, 144, Article116426-(2021)
   

Review - MIPs - a history

Book chapter, Alvarez-Lorenzo Cet al., Molecular Imprinting: A Historical Perspective, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 1-22, (2013)
   

review - MIPs and aptamers

Naseri M et al., The Use of Aptamers and Molecularly Imprinted Polymers in Biosensors for Environmental Monitoring: A Tale of Two Receptors.
Chemosensors, 8, (2), ArticleNo32-(2020)
   

Review - MIPs and aptamers in capillary electrophoresis and electrochromatography

Giovannoli C et al., Aptamers and molecularly imprinted polymers as artificial biomimetic receptors in affinity capillary electrophoresis and electrochromatography.
Electrophoresis, 29, (16), 3349-3365, (2008)
   

Review - MIPs and aptamers in sensing

Menger M et al., MIPs and Aptamers for Recognition of Proteins in Biomimetic Sensing.
Biosensors, 6, (3), ArticleNo35-(2016)
   

review - MIPs and carbon nanomaterials in analysis

Pandey H et al., Carbon nanomaterials integrated molecularly imprinted polymers for biological sample analysis: A critical review.
Materials Chemistry and Physics, 239, Article121966-(2020)
   

Review - MIPs and carbon nanomaterials in sensing

Ansari S, Combination of molecularly imprinted polymers and carbon nanomaterials as a versatile biosensing tool in sample analysis: Recent applications and challenges.
TrAC Trends in Analytical Chemistry, 93, 134-151, (2017)
   

Review - MIPs and carbon nanotubes

Book chapter, Cirillo Get al., Carbon Nanotubes – Imprinted Polymers: Hybrid Materials for Analytical Applications, 
In: Materials Science and Technology, Hutagalung SD (Ed.) InTech: 181-218, (2012)
   

Review - MIPs and chemical sensors

Book chapter, Pietrzyk-Le Aet al., Supramolecular Self-Assembly Governed Molecularly Imprinted Polymers for Selective Chemical Sensing, 
In: Applications of Supramolecular Chemistry, Schneider HJ (Ed.) CRC Press: (2012)
   

Review - MIPs and controlled polymerisation

Bompart M et al., Molecularly Imprinted Polymers and Controlled/Living Radical Polymerization.
Australian Journal of Chemistry, 62, (8), 751-761, (2009)
   

review - MIPs and crosslinking density

Mueller A, A Note about Crosslinking Density in Imprinting Polymerization.
Molecules, 26, (17), ArticleNo5139-(2021)
   

Review - MIPs and cross-reactivity

Book chapter, Yilmaz Eet al., Utilizing the Cross-Reactivity of MIPs, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 167-182, (2015)
   

review - MIPs and DNA

Zhang ZJ et al., Molecular Imprinting with Functional DNA.
Small, 15, (26), Article1805246-(2019)
   

Review - MIPs and drugs

Lulinski P, Molecularly Imprinted Polymers in Pharmaceutical Sciences. Part I. the Principles of Molecular Imprinting. Applications in Drug Synthesis and Drug Delivery Systems.
Polimery, 55, (11-12), 799-805, (2010)
   

review - MIPs and dummy MIPs

Chen RN et al., Comparison and recent progress of molecular imprinting technology and dummy template molecular imprinting technology.
Analytical Methods, 13, (39), 4538-4556, (2021)
   

Review - MIPs and electrochemiluminesence in analysis

Yang YK et al., Electrochemiluminescence Analysis Based on Molecular Imprinting Technique.
Progress In Chemistry, 28, (9), 1351-1362, (2016)
   

Review - MIPs and entioseparation of drugs

Chen XX et al., Molecular imprinting technique and its application in separation of chiral pharmaceutical drugs.
Modern Chemical Industry, (z1), 245-247, (2003)
   

Review - MIPs and fluorescense detection of explosives

Liu Y et al., Application of Molecular Imprinting and Fluorescence Analysis Techniques in Explosive Detection.
Progress In Chemistry, 21, (12), 2712-2717, (2009)
   

Review - MIPs and LbL films

Xu HP et al., Unconventional Layer-by-Layer Assembly: Surface Molecular Imprinting and Its Applications.
Small, 8, (4), 517-523, (2012)
   

Review - MIPs and living radicla polymerization

Salian VD et al., Living Radical Polymerization and Molecular Imprinting: Improving Polymer Morphology in Imprinted Polymers.
Macromolecular Materials And Engineering, 298, (4), 379-390, (2013)
   

Review - MIPs and mass sensitive sensors

Book chapter, Dickert Fet al., Molecularly imprinted polymers for mass sensitive sensors - from cells to viruses and enzymes, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 50-63, (2006)
   

Review - MIPs and mass-sensitive sensors

Book chapter, Dickert FLet al., Imprinted Polymers in Chemical Recognition for Mass-Sensitive Devices, 
In: Piezoelectric Sensors, Steinem C, Janshoff A (Eds.) Springer: Berlin, 173-210, (2007)
   

Review - MIPs and modelling

Jiang XH et al., Progress in thermodynamics, physical characterization and modeling of molecular imprinting polymers.
Polymer Materials Science and Engineering, 25, (3), 170-174, (2009)
   

Review - MIPs and modelling

Nicholls IA et al., Rational design of biomimetic molecularly imprinted materials: theoretical and computational strategies for guiding nanoscale structured polymer development.
Analytical and Bioanalytical Chemistry, 400, (6), 1771-1786, (2011)
   

review - MIPs and molecular modelling

Nicholls IA et al., The Use of Computational Methods for the Development of Molecularly Imprinted Polymers.
Polymers, 13, (17), ArticleNo2841-(2021)
   

Review - MIPs and molecular simulation

Liu Y et al., Applications of molecular simulation in molecular imprinting technology.
Journal of Chemical Industry and Engineering (China), 57, (10), 2257-2262, (2006)
   

Review - MIPs and molecular simulation

Xiong HG et al., Applications of Molecular Simulation in Molecular Imprinting Technology.
Meat Research, (11), 52-54, (2009)
   

review - MIPs and nanocarbon in sensors

Beluomini MA et al., Electrochemical sensors based on molecularly imprinted polymer on nanostructured carbon materials: A review.
Journal of Electroanalytical Chemistry, 840, 343-366, (2019)
   

Review - MIPs and nanomaterials

Book chapter, Bossi AMet al., Application of Nanomaterials to Molecularly Imprinted Polymers, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 124-144, (2018)
   

Review - MIPs and nanotechnology

Book chapter, Madhuri Ret al., Combination of Molecular Imprinting and Nanotechnology: Beginning of a New Horizon, 
In: Biosensors Nanotechnology, Tiwari A, Turner APF (Eds.) Wiley: Hoboken, 375-432, (2014)
   

Review - MIPs and nanotechnology

Book chapter, Madhuri Ret al., Combination of Molecular Imprinting and Nanotechnology: Beginning of a New Horizon, 
In: Advanced Biomaterials and Biodevices, Tiwari A, Nordin AN (Eds.) Wiley: Hoboken, 367-422, (2014)
   

review - MIPs and NIPs

Ndunda EN, Molecularly imprinted polymers - A closer look at the control polymer used in determining the imprinting effect: A mini review.
Journal of Molecular Recognition, 33, (11), Article_e2855-(2020)
   

Review - MIPs and particles

Lv R et al., Research Developments of Molecular Imprinting and Monodisperse Polymer Particles.
Chinese Journal of Colloid and Polymer, 20, (4), 32-35, (2002)
   

Review - MIPs and personal care products removal and analysis

Figueiredo L et al., Applications of molecularly imprinted polymers to the analysis and removal of personal care products: A review.
Talanta, 146, 754-765, (2016)
   

Review - MIPs and piezoelectric sensors

Uludag Y et al., Piezoelectric sensors based on molecular imprinted polymers for detection of low molecular mass analytes.
FEBS Journal, 274, (21), 5471-5480, (2007)
   

Review - MIPs and post-imprinting modification

Takeuchi T et al., Beyond natural antibodies - a new generation of synthetic antibodies created by post-imprinting modification of molecularly imprinted polymers.
Chemical Communications, 54, (49), 6243-6251, (2018)
   

Review - MIPs and proteins

Guo TY et al., Progress in the Study on Proteins Imprinted Technique.
Chemical Industry and Engineering Progress, 22, (7), 713-716, (2003)
   

Review - MIPS and QCMs

Mujahid A et al., Label-Free Bioanalyte Detection from Nanometer to Micrometer Dimensions-Molecular Imprinting and QCMs.
Biosensors, 8, (2), ArticleNo52-(2018)
   

Review - MIPs and quantum dots

Li Y, Study and development of the surface molecular imprinting on the Quantum Dots.
Laboratory Science, (2), 64-66, (2009)
   

review - MIPs and quantum dots

Sobiech M et al., Semiconductor nanocrystal-polymer hybrid nanomaterials and their application in molecular imprinting.
Nanoscale, 11, (25), 12030-12074, (2019)
   

review - MIPs and quantum dots in optical sensing

Kazemifard N et al., A review of the incorporation of QDs and imprinting technology in optical sensors - imprinting methods and sensing responses.
New Journal of Chemistry, 45, (23), 10170-10198, (2021)
   

Review - MIPs and rapid screening

Zhu XF et al., Rapid Screening for Non-convalented Molecular Imprinted Systems.
Yunnan Chemical Technology, 32, (1), 35-38, (2005)
   

Review - MIPs and recognition

Zheng XM et al., Influential Factors of Capabilities of Combination and Recognition in Molecularly Imprinted Polymers.
Materials Review, 18, (10), 57-59, (2004)
   

Review - MIPs and selectivity

Book chapter, Spivak DA, Selectivity in molecularly imprinted matrices, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 395-417, (2005)
   

Review - MIPs and sensors

Cao BQ et al., Progress of the Applied Study on Imprinting Sensors and Preparation of Molecularly Imprinted Polymers.
Chinese Polymer Bulletin, (8), 34-42, (2007)
   

Review - MIPs and SPME

Wang L et al., Application of molecular imprinting technique to solid-phase microextraction.
Metallurgical Analysis, 33, (11), 33-39, (2013)
   

Review - MIPs and template removal

Lorenzo RA et al., To Remove or Not to Remove? The Challenge of Extracting the Template to Make the Cavities Available in Molecularly Imprinted Polymers (MIPs).
International Journal of Molecular Sciences, 12, (7), 4327-4347, (2011)
   

Review - MIPs and their applications in tea

Yang XL et al., Molecular Imprinting Technique and Its Application in Separating and Assaying Functional Components in Tea.
Journal of Tea, 34, (1), 15-18,55, (2008)
   

Review - MIPs and their physical forms

Book chapter, Biffis Aet al., Physical Forms of MIPs, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 29-82, (2012)
   

Review - MIPs and their synthesis

Yemis F et al., Molecularly imprinted polymers and their synthesis by different methods.
Polymers & Polymer Composites, 21, (3), 145-150, (2013)
   

Review - MIPs and Traditional Chinese Medicine

Book chapter, Liu QSet al., The application of MITs on active ingredients extraction and separation from TCM, 
In: Advances in Energy Equipment Science and Engineering, Zhou SQ, Patty A, Chen SM (Eds.) CRC Press: London, 241-244, (2015)
   

Review - MIPs and water quality detection

Zhang P et al., Application of molecular imprinting technique in the sensor field of water quality detection.
Transducer and Microsystem Technologies, 25, (6), 9-12, (2006)
   

review - MIPs anf the gate-effect

Sharma PS et al., ’Gate effect’ in molecularly imprinted polymers: the current state of understanding.
Current Opinion in Electrochemistry, 16, 50-56, (2019)
   

Review - MIPs applied to traditional chinese medicine

Guo LF et al., Research and application of molecular imprinting technique in separating functional factors of traditional Chinese medicines.
Chinese Journal of Pharmaceutical Analysis, 29, (6), 1055-1058, (2009)
   

Review - MIPs as antibody mimics

Book chapter, Schirhagl R, Transferring the Selectivity of a Natural Antibody into a Molecularly Imprinted Polymer, 
In: Synthetic Antibodies: Methods and Protocols, Tiller T (Ed.) Springer: New York, NY, 325-340, (2017)
   

Review - MIPs as antibody replacements in assays

Lv CH et al., Molecularly Imprinted Polymers as Antibody Alternatives in Sorbent Immunoassays.
Progress In Chemistry, 24, (5), 844-851, (2012)
   

Review - MIPs as antibody substitutes in immunoassays

Chen CC et al., Molecularly Imprinted Polymer as an Antibody Substitution in Pseudo-immunoassays for Chemical Contaminants in Food and Environmental Samples.
Journal of Agricultural and Food Chemistry, 66, (11), 2561-2571, (2018)
   

Review - MIPs as artificial antibodies

Book chapter, Canfarotta Fet al., Nano-sized Molecularly Imprinted Polymers as Artificial Antibodies, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 1-27, (2018)
   

Review - MIPs as biomimetic catalysts

Book chapter, Chen ZYet al., Molecularly Imprinted Polymers for Biomimetic Catalysts, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 229-239, (2016)
   

Review - MIPs as biomimetic catalysts

Book chapter, Say Ret al., Biomimetic Imprinted Polymers: Theory, Design Methods, and Catalytic Applications, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 103-120, (2016)
   

Review - MIPs as biomimetic catalysts in sensors

Book chapter, Yoshimi Y, Molecularly Imprinted Polymers Applicable for Biomimetic Catalysts in Sensors, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 241-252, (2016)
   

review - MIPs as biomimetics

Bereli N et al., Molecular Imprinting Technology for Biomimetic Assemblies.
Hacettepe Journal of Biology and Chemistry, 48, (5), 575-601, (2020)
   

Review - MIPs as catalysts

Wulff G et al., Design of Biomimetic Catalysts by Molecular Imprinting in Synthetic Polymers: The Role of Transition State Stabilization.
Accounts of Chemical Research, 45, (2), 239-247, (2011)
   

Review - MIPs as catalysts

Book chapter, Resmini Met al., Microgels and Nanogels with Catalytic Activity, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 307-342, (2012)
   

Review - MIPs as catalysts

Resmini M, Molecularly imprinted polymers as biomimetic catalysts.
Analytical and Bioanalytical Chemistry, 402, (10), 3021-3026, (2012)
   

review - MIPs as catalysts

Mathew D et al., Design, synthesis and characterization of enzyme-analogue-built polymer catalysts as artificial hydrolases.
Artificial Cells, Nanomedicine, and Biotechnology, 47, (1), 1149-1172, (2019)
   

Review - MIPs as catalysts and molecular reaction vessels

Lou ZL et al., Application of Molecular Imprinting Technology to Enzyme Mimics and Molecular Reaction Vessels.
Chinese Journal of Organic Chemistry, 29, (11), 1744-1749, (2009)
   

Review - MIPs as catalysts by design

Book chapter, Dong ZYet al., Designing of Biomimetic Molecularly Imprinted Catalysts, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 359-378, (2018)
   

Review - MIPs as core-shell particles

Ming WN et al., Preparation and Applications of Core-Shell Molecularly Imprinted Polymers.
Progress In Chemistry, 28, (4), 552-563, (2016)
   

Review - MIPs as enzyme mimics

Book chapter, Severin K, Applications of molecularly imprinted materials as enzyme mimics, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 619-640, (2005)
   

Review - MIPs as metal-containing catalysts

Book chapter, Tada Met al., Molecular-Imprinted Metal Complexes for the Design of Catalytic Structures, 
In: Model Systems in Catalysis: Single Crystal to Supported Enzyme Mimics, Rioux RM (Ed.) Springer: New York, 475-493, (2010)
   

Review - MIPs as metalloenzyme mimetics

Book chapter, Li JPet al., The Recognizing Mechanism and Selectivity of the Molecularly Imprinting Membrane, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 159-182, (2016)
   

Review - MIPs as metalloenzyme mimetics

Book chapter, Szekely Get al., Biomimics of Metalloenzymes via Imprinting, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 121-158, (2016)
   

Review - MIPs as metallonzyme mimics

Czulak J et al., Molecularly imprinted polymers as biomimetics of metalloenzymes [Polimery z odciskiem molekularnym jako biomimetyki metaloenzymów].
Wiadomosci Chemiczne, 68, (9-10), 783-809, (2014)
   

Review - MIPs as monolithic adsorbents

Vlakh EG et al., Molecular imprinting: a tool of modern chemistry for the preparation of highly selective monolithic sorbents.
Russian Chemical Reviews, 84, (9), 952-980, (2015)
   

Review - MIPs as nanomaterials

Flavin K et al., Imprinted nanomaterials: a new class of synthetic receptors.
Analytical and Bioanalytical Chemistry, 393, (2), 437-444, (2009)
   

Review - MIPs as nanomaterials

Komiyama M et al., Molecular Imprinting: Materials Nanoarchitectonics with Molecular Information.
Bulletin of the Chemical Society of Japan, 91, (7), 1075-1111, (2018)
   

Review - MIPs as nucleants in crystallisation

Saridakis E et al., Imprinted polymers assisting protein crystallization.
Trends In Biotechnology, 31, (9), 515-520, (2013)
   

Review - MIPs as nucleotide receptors

Longo L et al., Molecularly imprinted polymers as nucleotide receptors.
Mini-Reviews in Organic Chemistry, 5, (3), 163-170, (2008)
   

Review - MIPs as photocatalysts

Book chapter, Shen XT, Molecularly Imprinted Photocatalysts, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 211-228, (2016)
   

review - MIPs as photocatalysts

Book chapter, de Escobar CCet al., Nanostructured Imprinted Supported Photocatalysts: Organic and Inorganic Matrixes, 
In: Nanophotocatalysis and Environmental Applications : Materials and Technology, Inamuddin, Sharma G, Kumar A, Lichtfouse E, Asiri AM (Eds.) Springer International Publishing: Cham, 1-48, (2019)
   

review - MIPs as photoluminescent materials

Gui RJ et al., Recent advances in synthetic methods and applications of photo-luminescent molecularly imprinted polymers.
Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 41, Article100315-(2019)
   

Review - MIPs as plastic antibodies

Hoshino Y et al., The evolution of plastic antibodies.
Journal of Materials Chemistry, 21, (11), 3517-3521, (2011)
   

Review - MIPs as plastic antibodies

Bowen JL et al., Twenty years since ’antibody mimics’ by molecular imprinting were first proposed: A critical perspective.
Molecular Imprinting, 1, (1), 35-40, (2013)
   

Review - MIPs as recognition elements in sensors

Book chapter, Li JPet al., Molecularly Imprinted Polymers as Recognition Elements in Sensors, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 35-55, (2012)
   

Review - MIPs as resposive hydrogels

Li ZB et al., Development of Molecularly Imprinted Intelligent Hydrogels.
Chinese Polymer Bulletin, (12), 24-28, (2007)
   

Review - MIPs as selective SPE materials

Chapuis F et al., Molecularly imprinted polymers: Developments and applications of new selective solid-phase extraction materials.
Lc Gc Europe, 17, (7), 408-417, (2004)
   

Review - MIPs as sorbents

Book chapter, Koesdjojo MTet al., Molecularly imprinted polymers as sorbents for separations and extractions, 
In: Separation Science and Technology: HPLC Method Development for Pharmaceuticals, Ahuja S, Rasmussen H (Eds.) Academic Press: 479-503, (2007)
   

Review - MIPs as SPE matrices in flow analysis

Dias ACB et al., Molecularly imprinted polymer as a solid phase extractor in flow analysis.
Talanta, 76, (5), 988-996, (2008)
   

Review - MIPs as stimuli-responsive materials

Book chapter, Parisi OIet al., Stimuli-responsive Molecularly Imprinted Polymers, 
In: Chemoresponsive Materials: Stimulation by Chemical and Biological Signals, Schneider HJ (Ed.) The Royal Society of Chemistry: 364-383, (2015)
   

Review - MIPs as synthetic catalysts

Book chapter, Sharma PSet al., Molecularly Imprinted Polymers as Synthetic Catalysts, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 183-210, (2016)
   

Review - MIPs based on chitosan

Wang LL et al., Advances in the Adsorptive Power of Chitosan Imprinting Molecule.
Chemical World, 51, (8), 501-504, (2010)
   

Review - MIPs based on chitosan

Xu L et al., Preparation and application of molecularly imprinted polymers based on chitosan.
Chemical Industry and Engineering Progress, 35, (3), 847-855, (2016)
   

Review - MIPs based on β-cyclodextrin

Lu K et al., The recognition mechanism and evaluation method of molecular imprinting technique based on β-cyclodextrins.
Journal of Functional Materials, 43, (SUPPL. 1), 10-15,21, (2012)
   

Review - MIPs based on β-cyclodextrin

Proceeding, Feng F et al, Novel β-Cyclodextrin Functional Monomers and its Application for Molecularly Imprinted Polymers, 
In: Advanced Materials Research, Adiguzel O (Ed.), 256-260, (2015)
   

Review - MIPs based on cyclodextrins

Lay S et al., State-of-the-art applications of cyclodextrins as functional monomers in molecular imprinting techniques: a review.
Journal of Separation Science, 39, (12), 2321-2331, (2016)
   

review - MIPs based on dopamine for biomacromolecules

Li MY et al., Dopamine-based molecularly imprinted polymers for the recognition of biomacromolecules.
Chinese Science Bulletin, 64, (13), 1321-1329, (2019)
   

Review - MIPs based on graphene

Roy E et al., Introduction of selectivity and specificity to graphene using an inimitable combination of molecular imprinting and nanotechnology.
Biosensors and Bioelectronics, 89, (Part 1), 234-248, (2017)
   

review - MIPs based on MOFs

Book chapter, Das TRet al., Metal-Organic Framework-Based Artificial Antibodies for Sensing Applications, 
In: Metal-Organic Frameworks for Environmental Sensing, Kumar SS, Ghosh P, Singh L (Eds.) American Chemical Society: Washington DC, 155-175, (2021)
   

Review - MIPs based on nanomaterials

Yan MM et al., Advance of molecularly imprinted technology based on nanomaterials.
Chinese Journal of Analysis Laboratory, 37, (5), 607-613, (2018)
   

Review - MIPs based on polysaccharides

Wang HF et al., Molecularly Imprinted Functional Materials Based on Polysaccharides.
Progress In Chemistry, 22, (11), 2165-2172, (2010)
   

Review - MIPs beads with surface imprints

Tan CJ et al., Molecularly imprinted beads by surface imprinting.
Analytical and Bioanalytical Chemistry, 389, (2), 369-376, (2007)
   

Review - MIPs binding site characterization

García-Calzón JA et al., Characterization of binding sites in molecularly imprinted polymers.
Sensors and Actuators B: Chemical, 123, (2), 1180-1194, (2007)
   

Review - MIPs by combinatorial methods

Rokushika H, Combinatorial molecular imprint method.
Bunseki, (2), 107-108, (2000)
   

Review - MIPs by computational design

Nicholls IA et al., Computational Strategies for the Design and Study of Molecularly Imprinted Materials.
Industrial & Engineering Chemistry Research, 52, (39), 13900-13909, (2013)
   

Review - MIPs by computational design

Cowen T et al., Computational approaches in the design of synthetic receptors - A review.
Analytica Chimica Acta, 936, 62-74, (2016)
   

Review - MIPs by computational modelling

Marc M et al., Computational modeling of molecularly imprinted polymers as a green approach to the development of novel analytical sorbents.
TrAC Trends in Analytical Chemistry, 98, 64-78, (2018)
   

Review - MIPs by controlled radical polymerisation

Zhang HQ, Recent Advances in Macromolecularly Imprinted Polymers by Controlled Radical Polymerization Techniques.
Molecular Imprinting, 3, (1), 63-74, (2015)
   

Review - MIPs by controlled radical polymerization

Zhang Y et al., Recent advances in the preparation of molecularly imprinted polymers via controlled radical polymerization techniques.
Chinese Journal of Reactive Polymers, 17, (2), 1-11, (2008)
   

Review - MIPs by covalent and stoichiometric imprinting

Book chapter, Wulff G, The covalent and other stoichiometric approaches, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 59-92, (2005)
   

Review - MIPs by electropolymerization

Book chapter, Whitcombe MJet al., Imprinted Polymers, 
In: Electropolymerisation, Cosnier S, Karyakin A (Eds.) Wiley-VCH: Weinheim, 133-151, (2010)
   

Review - MIPs by electrosynthesis in sensing

Book chapter, Mazzotta Eet al., Electrosynthesized Molecularly Imprinted Polymers for Chemosensing: Fundamentals and Applications, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 412-446, (2018)
   

Review - MIPs by epitope imprinting in disease monitoring

Singh M et al., Epitope Imprinting Approach to Monitor Diseases.
Journal of Molecular and Genetic Medicine, (2017)
   

Review - MIPs by fragment impriting

Kubo T, Development and Applications of Fragment Imprinting Technique.
Chromatography, 29, (1), 9-17, (2008)
   

Review - MIPs by ’’living’’ radical polymerisation

Zhang HQ, Controlled/’’living’’ radical precipitation polymerization: A versatile polymerization technique for advanced functional polymers.
European Polymer Journal, 49, (3), 579-600, (2013)
   

Review - MIPs by microcontact imprinting

Ertürk G et al., From imprinting to microcontact imprinting-A new tool to increase selectivity in analytical devices.
Journal of Chromatography B, 1021, 30-44, (2016)
   

Review - MIPs by nanofabrication

Book chapter, Prabhu Pet al., Recent progress on nanofabrication of molecularly imprinted polymers, 
In: Emerging Applications of Nanoparticles and Architecture Nanostructures, Barhoum A, Makhlouf ASH (Eds.) Elsevier: 385-409, (2018)
   

Review - MIPs by non-covalent imprinting

Book chapter, Yilmaz Eet al., The noncovalent approach, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 25-57, (2005)
   

review - MIPs by oriented templating

Kitayama Y et al., Oriented Immobilization-based Molecular Imprinting for Constructing Nanocavities Capable of Precise Molecular Recognition.
Bunseki Kagaku, 68, (2), 89-101, (2019)
   

Review - MIPs by peptide epitope imprinting

Pasquardini L et al., Molecularly imprinted polymers by epitope imprinting: a journey from molecular interactions to the available bioinformatics resources to scout for epitope templates.
Analytical and Bioanalytical Chemistry, 413, (24), 6101-6115, (2021)
   

Review - MIPs by photopolymerization

Fuchs Y et al., Photopolymerization and photostructuring of molecularly imprinted polymers for sensor applications - A review.
Analytica Chimica Acta, 717, (1), 7-20, (2012)
   

Review - MIPs by precipitation polymerisation

Pardeshi S et al., Precipitation polymerization: a versatile tool for preparing molecularly imprinted polymer beads for chromatography applications.
RSC Advances, 6, (28), 23525-23536, (2016)
   

Review - MIPs by rational design

Nicholls IA et al., Theoretical and computational strategies for rational molecularly imprinted polymer design.
Biosensors and Bioelectronics, 25, (3), 543-552, (2009)
   

Review - MIPs by rational design

Jalink T et al., Towards EMIC rational design: setting the molecular simulation toolbox for enantiopure molecularly imprinted catalysts.
Chemistry Central Journal, 10, (1), ArticleNo66-(2016)
   

Review - MIPs by semi-covalent imprinting

Book chapter, Kirsch Net al., The semi-covalent approach, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 93-122, (2005)
   

Review - MIPs by surface imprinting

Zhang WY et al., Advances in preparation of surface molecularly imprinted materials.
Modern Chemical Industry, 25, (12), 20-23, (2005)
   

Review - MIPs by surface imprinting

Yang YF et al., Advances in surface molecular imprinting.
Chemistry Bulletin, 70, (5), 324-330, (2007)
   

Review - MIPs catalysts

Wang JG et al., Progress in Study on Molecular Imprinting Polymers as Enzyme-mimic Catalyst.
Chemical Research and Application, 16, (4), 449-452, (2004)
   

Review - MIPs catalysts

Book chapter, Whitcombe M, MIP catalysts - from theory to practice, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 122-139, (2006)
   

Review - MIPs catalyst synthesis

Book chapter, Dramou Pet al., Molecularly Imprinted Catalysts: Synthesis and Applications, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 35-53, (2016)
   

Review - MIPs characterisation

Kumar R et al., Analytical strategies for characterization of molecular imprinted polymers: A current Review.
International Journal of ChemTech Research, 6, (2), 1162-1167, (2014)
   

Review - MIPs combinatorial approach

Book chapter, Lanza Fet al., Combinatorial approaches to molecular imprinting, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 225-248, (2005)
   

Review - MIPs comparison of performance

Toth B et al., Which molecularly imprinted polymer is better?
Analytica Chimica Acta, 591, (1), 17-21, (2007)
   

review - MIPs composition

Pratama KF et al., Effect of the Molecularly Imprinted Polymer Component Ratio on Analytical Performance.
Chemical and Pharmaceutical Bulletin, 68, (11), 1013-1024, (2020)
   

Review - MIPs design by computer modelling

Karim K et al., How to find effective functional monomers for effective molecularly imprinted polymers?
Advanced Drug Delivery Reviews, 57, (12), 1795-1808, (2005)
   

Review - MIPs design through combinatorial methods

Book chapter, Sellergren Bet al., Experimental Combinatorial Methods in Molecular Imprinting, 
In: Combinatorial Methods for Chemical and Biological Sensors, Potyrailo RA, Mirsky VM (Eds.) Springer: New York, 173-198, (2009)
   

Review - Mips design through molecular modelling

Book chapter, Subrahmanyam Set al., Computational Design of Molecularly Imprinted Polymers, 
In: Combinatorial Methods for Chemical and Biological Sensors, Potyrailo RA, Mirsky VM (Eds.) Springer: New York, 135-172, (2009)
   

Review - MIPs efficiency

Wang XJ et al., Concept of Imprinting Efficiency and Recent Progress of Molecular Imprinting.
Chemical World, 48, (4), 243-247, (2007)
   

Review - MIPs electrochemically prepared for biosensors

Book chapter, Yarman Aet al., Electropolymers for (nano-)imprinted biomimetic biosensors, 
In: Nanosensors for Chemical and Biological Applications: Sensing with Nanotubes, Nanowires and Nanoparticles, Honeychurch KC (Ed.) Woodhead Publishing: Amsterdam, 125-149, (2014)
   

Review - MIP sensor arrays

Book chapter, Li Pet al., Molecularly Imprinted Polymer Sensor Arrays, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 447-474, (2018)
   

Review - MIP sensors

Ding P et al., Research and Application Progress of Molecular Imprinting Technology in Sensors.
Chemical World, 52, (3), 178-183,189,168, (2011)
   

Review - MIP sensors

Schirhagl R et al., Immunosensing with artificial antibodies in organic solvents or complex matrices.
Sensors and Actuators B: Chemical, 173, 585-590, (2012)
   

Review - MIP sensors

Book chapter, Mustafa Get al., MIP Sensors on the Way to Real-World Applications, 
In: Designing Receptors for the Next Generation of Biosensors, Piletsky SA, Whitcombe MJ (Eds.) Springer: Berlin, Heidelberg, 167-187, (2013)
   

Review - MIP sensors

Book chapter, Uygun ZOet al., Molecularly Imprinted Sensors - New Sensing Technologies, 
In: Biosensors - Micro and Nanoscale Applications, Rinken T (Ed.) InTech: 85-108, (2015)
   

Review - MIP sensors based on overoxidized polypyrrole

Book chapter, Tokonami Set al., Molecularly Imprinted Overoxidized Polypyrrole Films for Sensor Applications from Enantiorecognition to Trace Analysis, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 73-89, (2012)
   

review - MIP sensors for cancer biomarkers

Bhakta S et al., Molecularly imprinted polymer-based sensors for cancer biomarker detection.
Sensors and Actuators Reports, 3, Article100061-(2021)
   

review - MIP sensors for environmental pollutants

Mostafiz B et al., Molecularly imprinted polymer-carbon paste electrode (MIP-CPE)-based sensors for the sensitive detection of organic and inorganic environmental pollutants: A review.
Trends in Environmental Analytical Chemistry, 32, Article_e00144-(2021)
   

Review - MIP sensors for urinary biomarkers

Agrofoglio LA et al., Detection of urinary modified nucleosides by a bulk acoustic wave MIP sensor - Results and future work.
IRBM, 35, (2), 66-71, (2014)
   

Review - MIP sensors for viruses and proteins

Proceeding, Dickert FL et al, Sensors for Healthcare Monitoring - Proteins, Viruses and Blood-Group-Typing, 
Dössel O, Schlegel WC (Eds.), 325-328, (2009)
   

Review - MIP sensors with nano- and micro-molar sensitivity

Book chapter, Horemans Fet al., MIP-based Sensor Platforms for Detection of Analytes in Nano- and Micromolar Range, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 91-124, (2012)
   

Review - MIP sensors with optical and mass-sensitive detection

Book chapter, Mujahid Aet al., Molecularly Imprinted Polymers for Sensors: Comparison of Optical and Mass-Sensitive Detection, 
In: Molecularly Imprinted Sensors, Li SJ, Ge Y, Piletsky SA, Lunec J (Eds.) Elsevier: Amsterdam, 125-159, (2012)
   

Review - MIPs fluorescent sensors

Wang HY et al., Progress in fluorescent molecular imprinting polymer sensors.
Chemistry Bulletin, 73, (5), 396-403, (2010)
   

Review - MIPs for anion recognition

Book chapter, Ewen SLet al., Molecularly Imprinted Polymers Using Anions as Templates, 
In: Recognition of Anions, Vilar R (Ed.) Springer: Berlin / Heidelberg, 207-248, (2008)
   

Review - MIPs for anion recognition

Wu XY, Molecular imprinting for anion recognition in aqueous media.
Microchimica Acta, 176, (1), 23-47, (2012)
   

Review - MIPs for antibiotic recognition

Fernández-González A et al., Mimicking molecular receptors for antibiotics - analytical implications.
TrAC Trends in Analytical Chemistry, 25, (10), 949-957, (2006)
   

Review - MIPs for antibiotics

Yakhkind MI et al., Molecular imprinted polymers for macrolides, aminoglycosides and some other biosynthetic antibiotics.
Antibiotiki i Khimioterapiya, 59, (7-8), 37-40, (2014)
   

Review - MIPs for antibiotics

Yakhkind MI et al., Molecularly imprinted polymers: possible use for isolation of biosynthetic antibiotics.
Russian Chemical Bulletin, 63, (5), 1049-1056, (2014)
   

Review - MIPs for antioxidants

Proceeding, Pardeshi S et al, Molecular Imprinting: Mimicking Molecular Receptors for Antioxidants, 
In: Materials Science Forum, 515-520, (2011)
   

Review - MIPs for aqueous separations

Zhang H et al., Water-Compatible Molecular Imprinting Separation Technique and Its Application in Analytical Chemistry.
Progress In Chemistry, 23, (10), 2140-2150, (2011)
   

review - MIPs for arsenic and mercury

Jinadasa KK et al., New adsorbents based on imprinted polymers and composite nanomaterials for arsenic and mercury screening/speciation: A review.
Microchemical Journal, 156, Article104886-(2020)
   

review - MIPs for bacteria

Zhang JB et al., Molecular imprinting technology for sensing foodborne pathogenic bacteria.
Analytical and Bioanalytical Chemistry, 413, (18), 4581-4598, (2021)
   

Review - MIPs for binding peptides in water

Sumaoka J et al., Molecularly Imprinted Polymers for the Recognition of Biomolecules in Water.
Kobunshi Ronbunshu, 66, (6), 191-201, (2009)
   

Review - MIPs for biomacromolecules

Luo H et al., Recognition of Biomacromolecule by Molecular Imprinting Technique.
China Biotechnology, 21, (5), 63-67, (2001)
   

Review - MIPs for biomacromolecules

Zheng C et al., Separation and Recognition of Biomacromolecule by Molecular Imprinting Technique.
Chinese Journal of Chromatography, 24, (3), 309-314, (2006)
   

Review - MIPs for biomacromolecules

Zahedi P et al., Biomacromolecule template-based molecularly imprinted polymers with an emphasis on their synthesis strategies: a review.
Polymers for Advanced Technologies, 27, (9), 1124-1142, (2016)
   

review - MIPs for biomacromolecules

Teixeira SPB et al., Epitope-imprinted polymers: Design principles of synthetic binding partners for natural biomacromolecules.
Science Advances, 7, (44), Article_eabi9884-(2021)
   

Review - MIPs for biomedicine and biotechnology

Dmitrienko EV et al., Molecularly imprinted polymers for biomedical and biotechnological applications.
Russian Chemical Reviews, 85, (5), 513-536, (2016)
   

Review - MIPs for biomolecules

Kotrotsiou O et al., Molecularly imprinted polymers for selective recognition of biomolecules.
Journal of Nanostructured Polymers and Nanocomposites, 3, (2), 35-45, (2007)
   

review - MIPs for biomolecules

Zhang N et al., Molecularly Imprinted Materials for Selective Biological Recognition.
Macromolecular Rapid Communications, 40, (17), Article1900096-(2019)
   

Review - MIPs for biomolecules using metal ion coordination

Tamahkar E et al., Metal Ion Coordination Interactions for Biomolecule Recognition: a Review.
Hittite Journal of Science and Engineering, 1, (1), 21-26, (2014)
   

Review - MIPs for bioparticle detection

Eersels K et al., A Review on Synthetic Receptors for Bioparticle Detection Created by Surface-Imprinting Techniques - From Principles to Applications.
ACS Sensors, 1, (10), 1171-1187, (2016)
   

Review - MIPs for bio-templates

Mujahid A et al., Bioimprinting strategies: From soft lithography to biomimetic sensors and beyond.
Biotechnology Advances, 31, (8), 1435-1447, (2013)
   

review - MIPs for bisphenols

Kubiak A et al., Application of Molecularly Imprinted Polymers for Bisphenols Extraction from Food Samples - A Review.
Critical Reviews in Analytical Chemistry, 50, (4), 311-321, (2020)
   

review - MIPS for bovine serum albumin

Jahanban-Esfahlan A et al., Latest developments in the detection and separation of bovine serum albumin using molecularly imprinted polymers.
Talanta, 207, Article120317-(2020)
   

Review - MIPs for cholesterol

Zhang SZ et al., Preparation methods and selective adsorption capabilities of cholesterol molecularly imprinted polymers.
Chemistry Bulletin, 74, (2), 137-143, (2011)
   

Review - MIPs for crystal growth

Whitcombe MJ, Molecularly imprinted polymers: Smart hydrogel crystal gardens.
Nature Chemistry, 3, (9), 657-658, (2011)
   

Review - MIPs for desulfurization of fuels

Yang YZ et al., Recent advances in molecular imprinting technology for the deep desulfurization of fuel oils.
New Carbon Materials, 29, (1), 1-14, (2014)
   

Review - MIPs for detecting antibiotics in milk

Bitas D et al., Molecularly Imprinted Polymers as Extracting Media for the Chromatographic Determination of Antibiotics in Milk.
Molecules, 23, (2), ArticleNo316-(2018)
   

Review - MIPs for detection of food analysis

Garcia R et al., "On-off" switchable tool for food sample preparation: merging molecularly imprinting technology with stimuli-responsive blocks. Current status, challenges and highlighted applications.
Talanta, 176, 479-484, (2018)
   

Review - MIPs for determination of organophosphorus pesticides

Boulanouar S et al., Molecularly imprinted polymers for the determination of organophosphorus pesticides in complex samples.
Talanta, 176, 465-478, (2018)
   

Review - MIPs for disease markers

Wang Y et al., Applications of Disease Markers Molecularly Imprinting Technology in Separation and Sensing.
Chinese Journal of Analytical Chemistry, 41, (5), 787-794, (2013)
   

Review - MIPs for dopamine

Zaidi SA, Development of molecular imprinted polymers based strategies for the determination of Dopamine.
Sensors and Actuators B: Chemical, 265, 488-497, (2018)
   

Review - MIPs for drug analysis

Ansari S et al., Recent configurations and progressive uses of magnetic molecularly imprinted polymers for drug analysis.
Talanta, 167, 470-485, (2017)
   

Review - MIPs for drug delivery

Book chapter, Alvarez-Lorenzo Cet al., Molecularly imprinted hydrogels for affinity-controlled and stimuli-responsive drug delivery, 
In: Smart Materials for Drug Delivery, Volume 1, Alvarez-Lorenzo C, Concheiro A, Schneider HJ, Shahinpoor M (Eds.) RSC: Cambridge, 228-260, (2013)
   

Review - MIPs for electrochemical sensing

Merkoçi A et al., New materials for electrochemical sensing - IV. Molecular imprinted polymers.
TrAC Trends in Analytical Chemistry, 21, (11), 717-725, (2002)
   

Review - MIPs for enantiomer recognition

Book chapter, Sellergren B, Recognition of enantiomers using molecularly imprinted polymers, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 95-121, (2006)
   

Review - MIPs for endocrine disrupters

Book chapter, Le Noir Net al., Removal of Endocrine Disrupting Contaminants from Water Using Macroporous Molecularly Imprinted Selective Media, 
In: New Membranes and Advanced Materials for Wastewater Treatment, Mueller A, Guieysse B, Sarkar A (Eds.) American Chemical Society: Washington DC, 25-51, (2009)
   

Review - MIPs for environmental pollutants

Kubo T et al., Molecularly Imprinted Adsorbents for Selective Separation and/or Concentration of Environmental Pollutants.
Analytical Sciences, 30, (1), 97-104, (2014)
   

Review - MIPs for explosive and chemical warfare agent detection

Lu W et al., Molecularly Imprinted Polymers for the Sensing of Explosives and Chemical Warfare Agents.
Current Organic Chemistry, 19, (1), 62-71, (2015)
   

review - MIPs for explosives

Zarejousheghani M et al., Molecularly Imprinted Polymer Materials as Selective Recognition Sorbents for Explosives: A Review.
Polymers, 11, (5), ArticleNo888-(2019)
   

Review - MIPs for explosives sensing

Book chapter, Sharma PSet al., Molecular Imprinting for Selective Sensing of Explosives, Warfare Agents, and Toxins, 
In: Portable Chemical Sensors, Nikolelis D (Ed.) Springer Netherlands: 63-94, (2012)
   

Review - MIPs for exraction of estrogens from environmental waters

Gadzala-Kopciuch R et al., Applications of Molecularly Imprinted Polymers for Isolation of Estrogens from Environmental Water Samples.
Current Analytical Chemistry, 12, (4), 315-323, (2016)
   

Review - MIPs for extraction from traditional medicines

Zhu QH et al., Application of molecular imprinting polymer in study on Chinese materia medica.
Chinese Traditional and Herbal Drugs, 39, (2), 294-297, (2008)
   

Review - MIPs for extraction of active compounds from natural products

Pardo A et al., Targeted extraction of active compounds from natural products by molecularly imprinted polymers.
Central European Journal of Chemistry, 10, (3), 751-765, (2012)
   

Review - MIPs for extraction of contaminants

Speltini A et al., Newest applications of molecularly imprinted polymers for extraction of contaminants from environmental and food matrices: A review.
Analytica Chimica Acta, 974, 1-26, (2017)
   

Review - MIPs for extraction of toxic compounds

Widstrand C et al., Efficient extraction of toxic compounds from complex matrices using molecularly imprinted polymers.
American Laboratory, 39, (17), 23-24, (2007)
   

Review - MIPs for fluorescent or phosphorescent detection

Xu JG et al., Molecular Imprinting-Based Biomimetic Molecular Recognition with Fluorescence or Phosphorescence Detection.
Journal of Fuzhou University (Natural Science Edition), 27, (S1), 6-8, (1999)
   

Review - MIPs for fluoroquinolines

Fei JZ et al., Progress of molecular imprinted polymer of fluoroquinolones and its application on the food determination.
Chemical Industry and Engineering Progress, 29, (S2), 205-209, (2010)
   

review - MIPS for fluoroquinolines

Madikizela LM et al., Synthesis of molecularly imprinted polymers for extraction of fluoroquinolones in environmental, food and biological samples.
Journal of Pharmaceutical and Biomedical Analysis, 208, Article114447-(2022)
   

Review - MIPs for food toxin analysis

Saini SS et al., Molecularly Imprinted Polymers for the Detection of Food Toxins: A Minireview.
Advances in Nanoparticles, 2, (1), 60-65, (2013)
   

review - MIPs for gaseous pollutants

Huang Y et al., Removal of Typical Industrial Gaseous Pollutants: From Carbon, Zeolite, and Metal-organic Frameworks to Molecularly Imprinted Adsorbents.
Aerosol and Air Quality Research, 19, (9), 2130-2150, (2019)
   

Review - MIPs for heavy metal ions

Shang HZ et al., Latest research development of ion imprinted polymer.
Modern Chemical Industry, 36, (9), 32-35, (2016)
   

review - MIPs for heavy metals

El Ouardi Y et al., Benefit of ion imprinting technique in solid-phase extraction of heavy metals, special focus on the last decade.
Journal of Environmental Chemical Engineering, 9, (6), Article106548-(2021)
   

review - MIPs for heavy metals and dyes

Sharma G et al., Molecularly Imprinted Polymers for Selective Recognition and Extraction of Heavy Metal Ions and Toxic Dyes.
Journal of Chemical & Engineering Data, 65, (2), 396-418, (2020)
   

Review - MIPs for herbicides

Liu MJ et al., Preparation of molecular imprinted polymer used in herbicides residue analysis.
Chemical Industry Times, 23, (7), 57-60, (2009)
   

review - MIPs for hormone analysis and SPE

Mpupa A et al., Recent Advances in Solid-Phase Extraction (SPE) Based on Molecularly Imprinted Polymers (MIPs) for Analysis of Hormones.
Chemosensors, 9, (7), ArticleNo151-(2021)
   

Review - MIPs for HPLC

Zuo GQ, Preparation and Application of Molecularly Imprinting Technique of Monolithic Liquid Chromatography Column.
Journal of Henan Institute of Science and Technology, 35, (1), 37-41, (2007)
   

Review - MIPs for ionic species

Fu JQ et al., Current status and challenges of ion imprinting.
Journal of Materials Chemistry A, 3, (26), 13598-13627, (2015)
   

Review - MIPs for ionic templates

Cejner M et al.,  Ion-imprinted polymers: synthesis, characterization and applications.
Ann. Univ. Mariae Curie-Sklodowska, Lublin-Polonia: Sect. AA, 70, (2), 67-85, (2015)
   

Review - MIPs for ions

Rao TP et al., Metal ion-imprinted polymers--Novel materials for selective recognition of inorganics.
Analytica Chimica Acta, 578, (2), 105-116, (2006)
   

Review - MIPs for ions

Fan HT et al., Ion imprinted polymer and its application in the analytical chemistry.
Chemistry Bulletin, 72, (1), 10-14, (2009)
   

Review - MIPs for ions

Mu HY et al., Progress in template-ion imprinted polymer.
Chemical Industry and Engineering Progress, 30, (11), 2467-2480, (2011)
   

Review - MIPs for ions

Mafu LD et al., Ion-imprinted polymers for environmental monitoring of inorganic pollutants: synthesis, characterization, and applications.
Environmental Science and Pollution Research, 20, (2), 790-802, (2013)
   

Review - MIPs for ions

Shang HZ et al., Research progress of ion imprinted polymer.
Modern Chemical Industry, 33, (2), 20-23,25, (2013)
   

Review - MIPs for isolation of actives from natural products

Yang X et al., Application of molecular imprinting technology in separation and purification of active ingredients from natural products.
Journal of Northeast Agricultural University, 42, (8), 146-153, (2011)
   

Review - MIPs for isolation of biological materials

Kwasniewska K et al., Magnetic molecular imprinted polymers as a tool for isolation and purification of biological samples.
Open Chemistry, 13, (1), 1228-1235, (2015)
   

Review - MIPs for lipoic acid

Zhu QJ et al., Research progress in anti-oxidative and thermo-sensitive lipoic acid molecularly imprinted polymers.
Journal of Food Safety and Quality, 4, (6), 1785-1789, (2013)
   

Review - MIPs for macromolecular templates

Kryscio DR et al., Critical review and perspective of macromolecularly imprinted polymers.
Acta Biomaterialia, 8, (2), 461-473, (2012)
   

Review - MIPs for macromolecules

Ge Y et al., Too large to fit? Recent developments in macromolecular imprinting.
Trends In Biotechnology, 26, (4), 218-224, (2008)
   

Review - MIPs for macromolecules

Li SJ et al., Size matters: Challenges in imprinting macromolecules.
Progress in Polymer Science, 39, (1), 145-163, (2014)
   

Review - MIPs for macromolecules

Iskierko Z et al., Molecularly imprinted polymers for separating and sensing of macromolecular compounds and microorganisms.
Biotechnology Advances, 34, (1), 30-46, (2016)
   

Review - MIPs for macromolecules

Stevenson D et al., Selective extraction of proteins and other macromolecules from biological samples using molecular imprinted polymers.
Bioanalysis, 8, (21), 2255-2263, (2016)
   

Review - MIPs for medical devices

Ciardelli G et al., The relevance of the transfer of molecular information between natural and synthetic materials in the realisation of biomedical devices with enhanced properties.
Journal of Biomaterials Science-Polymer Edition, 16, (2), 219-236, (2005)
   

Review - MIPs for metal ions

Book chapter, Murray GMet al., Metal ion selective molecularly imprinted polymers, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 579-602, (2005)
   

Review - MIPs for metal ions

Wang JS et al., Application of ion imprinting technology in heavy metal waste treating and recycling.
Journal of Safety and Environment, (4), 59-62, (2009)
   

Review - MIPs for metal ions

Zhu LY et al., Progress of metal-ion imprinting technology.
Chemistry Bulletin, 73, (4), 326-331, (2010)
   

Review - MIPs for metal ions

Marestoni LD et al., Ion imprinted polymers: fundamentals, preparation strategies and applications in analytical chemistry.
Quimica Nova, 36, (8), 1194-1207, (2013)
   

Review - MIPs for metal ions

Hande PE et al., Highly selective monitoring of metals by using ion-imprinted polymers.
Environmental Science and Pollution Research, 22, (10), 7375-7404, (2015)
   

Review - MIPs for metal ions

Fu JQ et al., Ion Imprinting Technology for Heavy Metal Ions.
Progress In Chemistry, 28, (1), 83-90, (2016)
   

Review - MIPs for metal ions

Gos P et al., Metal ion imprinted and moleculary imprinted polymers used in chemical analysis and examination of the environmental pollution / Polimery z odwzorowanymi jonami metali oraz sladem molekularnym i ich wykorzystanie w analityce chemicznej oraz w badaniach zanieczyszczenia srodowiska.
Przemysl Chemiczny, 95, (11), 2330-2333, (2016)
   

Review - MIPs for metal ions

Shakerian F et al., Advanced polymeric materials: Synthesis and analytical application of ion imprinted polymers as selective sorbents for solid phase extraction of metal ions.
TrAC Trends in Analytical Chemistry, 83, (Part B), 55-69, (2016)
   

Review - MIPs for metal ions

Erdem O et al., Molecularly Imprinted Polymers for Removal of Metal Ions: An Alternative Treatment Method.
Biomimetics, 3, (4), Article38-(2018)
   

Review - MIPs for microextraction

Zhang KG et al., Development of molecularly imprinted microextraction techniques.
Chinese Journal of Chromatography, 30, (12), 1220-1228, (2012)
   

Review - MIPs for microorganism biosensors

Idil N et al., Imprinting of Microorganisms for Biosensor Applications.
Sensors, 17, (4), ArticleNo708-(2017)
   

Review - MIPs for mycotoxins analysis

Appell M et al., Mycotoxin Analysis Using Imprinted Materials Technology: Recent Developments.
Journal of AOAC International, 99, (4), 861-864, (2016)
   

Review - MIPs for natural products

Hong YX et al., Molecular Imprinting Technologies for Natural Product Research Active Ingredients Progress.
Journal of Anhui Agricultural Sciences, 36, (21), 8960-8962, (2008)
   

Review - MIPs for nucleotides, nucleosides etc.

Book chapter, Favetta Pet al., Molecularly Imprinted Polymers-based Separation and Sensing of Nucleobases, Nucleosides, Nucleotides and Oligonucleotides, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 65-123, (2018)
   

Review - MIPs for Ochratoxin

Yu JCC et al., Molecularly Imprinted Polymers for Ochratoxin A Extraction and Analysis.
Toxins, 2, (6), 1536-1553, (2010)
   

Review - MIPs for online extraction

Moein MM et al., Molecularly imprinted polymers for on-line extraction techniques.
Bioanalysis, 7, (17), 2145-2153, (2015)
   

Review - MIPs for optical sensing

Henry OYF et al., Optical interrogation of molecularly imprinted polymers and development of MIP sensors: a review.
Analytical and Bioanalytical Chemistry, 382, (4), 947-956, (2005)
   

review - MIPs for organic pollutants in environmental waters

Azizi A et al., A critical review of molecularly imprinted polymers for the analysis of organic pollutants in environmental water samples.
Journal of Chromatography A, 1614, Article460603-(2020)
   

Review MIPs for organophosphates

Verma A et al., A Path to Soluble Molecularly Imprinted Polymers.
Journal of Functional Biomaterials, 3, (1), 1-22, (2012)
   

Review - MIPs for organophosphorus pesticide detection

Hou CJ et al., Application of molecular imprinting technique in field of organophosphorus pesticide detection.
Transducer and Microsystem Technologies, 28, (4), 5-9,14, (2009)
   

Review - MIPs for organotin detection

Zhu SS et al., Organotin Compounds Chromatographic Detection Methods Based on Molecular Imprinting Technique.
Journal of Ningbo University (Natural Science and Engineering Edition), 25, (3), 97-100, (2012)
   

Review - MIPs for peptides and proteins

Dai Y, Research Advance of Molecular Imprinting Technique in the Peptides and Proteins.
Journal of Yancheng Institute of Technology (Natural Science Edition), 16, (4), 46-49, (2003)
   

Review - MIPs for peptides and proteins

Janiak DS et al., Molecular imprinting of peptides and proteins in aqueous media.
Analytical and Bioanalytical Chemistry, 389, (2), 399-404, (2007)
   

Review - MIPs for peptides and proteins

Hu J et al., Recognition of proteins and peptides: Rational development of molecular imprinting technology.
Polymer Science Series A, 52, (3), 328-339, (2010)
   

Review - MIPs for peptides and proteins

Proceeding, Sharma A et al, Molecular imprinted nanoPolymer nanomaterials: Application in biomolecule recognition, 
270-273, (2010)
   

Review - MIPs for peptides and proteins

Ghorbani-Bidkorbeh F, Molecular Imprinting of Peptides and Proteins.
Trends in Peptide and Protein Sciences, 1, (3), 99-108, (2017)
   

Review - MIPs for perfluorinated compounds

Karoyo AH et al., Nano-Sized Cyclodextrin-Based Molecularly Imprinted Polymer Adsorbents for Perfluorinated Compounds—A Mini-Review.
Nanomaterials, 5, (2), 981-1003, (2015)
   

Review - MIPs for pesticide detection

Zhang HT et al., The Application of Molecularly Imprinted Polymer Sensor in Pesticide Detection.
Chinese Journal of Pesticide Science, 8, (1), 8-13, (2006)
   

Review - MIPs for pesticide detection

Liu Y et al., Application of molecularly imprinted polymer in pesticide detection.
Modern Instruments, 16, (4), 12-14,17, (2010)
   

Review - MIPs for pesticide food analysis

Garcia R et al., Application of Molecularly Imprinted Polymers for the Analysis of Pesticide Residues in Food—A Highly Selective and Innovative Approach.
American Journal of Analytical Chemistry, 2, (8A), 16-25, (2011)
   

Review - MIPs for pesticide residue analysis

Yan SL et al., Progress of molecular imprinting technique on the determination of pesticides residues.
Journal of Hygiene Research, 34, (2), 227-230, (2005)
   

Review - MIPs for pesticide residue determination

Zuo HG et al., Progresss of molecular imprinting technique on the determination of pesticides residues.
Journal of Nanjing Agricultural University, 35, (5), 175-182, (2012)
   

review - MIPs for pesticides

Wang SL et al., Molecular imprinting technology and its application for the detection of pesticide residue.
Journal of Food Safety and Quality, 10, (7), 1955-1960, (2019)
   

review - MIPs for pesticides

Book chapter, Yilmaz Fet al., Molecularly Imprinted Sensors for Detecting Controlled Release of Pesticides, 
In: Controlled Release of Pesticides for Sustainable Agriculture, Rakhimol KR, Thomas S, Volova T, Jayachandran K (Eds.) Springer International Publishing: Cham, 207-235, (2020)
   

Review - MIPs for pharmaceuticals

Book chapter, Madikizela Let al., Molecularly Imprinted Polymers for Pharmaceutical Compounds: Synthetic Procedures and Analytical Applications, 
In: Recent Research in Polymerization, Cancaya N (Ed.) InTechOpen: 47-67, (2018)
   

review - MIPs for polar pesticides

Li T et al., Advances in application of molecularly imprinted polymers to the detection of polar pesticide residues.
Chinese Journal of Chromatography, 39, (9), 930-940, (2021)
   

review - MIPs for pollutants

Bagheri AR et al., Molecularly imprinted polymers-based adsorption and photocatalytic approaches for mitigation of environmentally-hazardous pollutants - A review.
Journal of Environmental Chemical Engineering, 9, (1), Article104879-(2021)
   

review - MIPs for pollutants

Parlapiano M et al., Selective removal of contaminants of emerging concern (CECs) from urban water cycle via Molecularly Imprinted Polymers (MIPs): Potential of upscaling and enabling reclaimed water reuse.
Journal of Environmental Chemical Engineering, 9, (1), Article105051-(2021)
   

Review - MIPs for polychlorinated aromatics

Ndunda EN et al., Molecularly imprinted polymers for the analysis and removal of polychlorinated aromatic compounds in the environment: a review.
Analyst, 141, (11), 3141-3156, (2016)
   

Review - MIPs for precious metals

Kyzas GZ et al., Molecular Imprinting for High-Added Value Metals: An Overview of Recent Environmental Applications.
Advances in Materials Science and Engineering, 2014, Article ID 932637-(2014)
   

Review - MIPs for protein

Wang P et al., Advance in the Molecular Imprinting Based Protein Recognition.
Chemistry & Bioengineering, 25, (9), 1-4, (2008)
   

Review - MIPs for protein

Book chapter, Mingotaud AFet al., Next generation molecular imprinted polymers: Examples of liquid crystalline materials and hydrogels for protein recognition, 
In: Molecular Recognition: Biotechnology, Chemical Engineering and Materials Applications, McEvoy JA (Ed.) Nova Science Publishers, Inc.: New York, 45-77, (2011)
   

Review - MIPS for protein

Raim V et al., Comparison of descriptors for predicting selectivity of protein-imprinted polymers.
Journal of Molecular Recognition, 29, (8), 391-400, (2016)
   

Review - MIPs for protein

Culver HR et al., Protein-Imprinted Polymers: The Shape of Things to Come?
Chemistry of Materials, 29, (14), 5753-5761, (2017)
   

Review - MIPs for protein detection

Whitcombe MJ et al., The rational development of molecularly imprinted polymer-based sensors for protein detection.
Chemical Society Reviews, 40, (3), 1547-1571, (2011)
   

review - MIPs for protein epitopes

Wang XD et al., Advances in epitope molecularly imprinted polymers for protein detection: a review.
Analytical Methods, 13, (14), 1660-1671, (2021)
   

Review - MIPs for protein recognition

Song XJ et al., Proteins molecular imprinted technique.
Chemistry Bulletin, 68, (7), 504-509, (2005)
   

Review - MIPs for protein recognition

Bossi A et al., Molecularly imprinted polymers for the recognition of proteins: The state of the art.
Biosensors and Bioelectronics, 22, (6), 1131-1137, (2007)
   

Review - MIPs for protein recognition

Hansen DE, Recent developments in the molecular imprinting of proteins.
Biomaterials, 28, (29), 4178-4191, (2007)
   

Review - MIPs for protein recognition

Zhou X et al., Recent Advances in the Study of Protein Imprinting.
Separation & Purification Reviews, 36, (4), 257-283, (2007)
   

Review - MIPs for protein recognition

Bergmann NM et al., Molecularly imprinted polymers with specific recognition for macromolecules and proteins.
Progress in Polymer Science, 33, (3), 271-288, (2008)
   

Review - MIPs for protein recognition

Gao N, Development of molecular imprinting for protein recognition.
Chemical Research and Application, 24, (3), 337-343, (2012)
   

Review - MIPs for protein recognition

Kamon Y et al., Antibody-like Synthetic Molecular Recognition Thin Layers Fabricated by Molecular Imprinting Based on Specific Protein-ligand Interactions.
Membrane, 42, (3), 97-103, (2017)
   

Review - MIPs for proteins

Lu SL et al., Preparation methods of nanocavity biomaterials with recognition specificity via template imprinting of proteins.
Acta Academiae Medicinae Sinicae, 25, (5), 640-644, (2003)
   

Review - MIPs for proteins

Turner NW et al., From 3D to 2D: A Review of the Molecular Imprinting of Proteins.
Biotechnology Progress, 22, (6), 1474-1489, (2006)
   

Review - MIPs for proteins

Qin H et al., Progress of Proteins Imprinted Technique and Prospect of Its Application.
Food Science, 28, (8), 577-580, (2007)
   

Review - MIPs for proteins

Gao T et al., Progress of Protein Molecular imprinting in Carrier Materials Form.
Chinese Polymer Bulletin, (4), 36-43, (2010)
   

Review - MIPs for proteins

Li YT et al., The Characteristics and Elution Approaches of Protein Bulk Imprinting.
Journal of Analytical Science, 27, (6), 785-790, (2011)
   

Review - MIPs for proteins

Sun YJ et al., Recent advances and perspective in the study of the molecular imprinting of proteins.
Acta Pharmaceutica Sinica, 46, (2), 132-137, (2011)
   

Review - MIPs for proteins

Verheyen E et al., Challenges for the effective molecular imprinting of proteins.
Biomaterials, 32, (11), 3008-3020, (2011)
   

Review - MIPs for proteins

Yang KG et al., Protein-imprinted materials: rational design, application and challenges.
Analytical and Bioanalytical Chemistry, 403, (8), 2173-2183, (2012)
   

Review - MIPs for proteins

Wu ZH et al., Recent advances and perspective in the study of the nano-reinforcing materials for molecular imprinting of proteins.
Acta Pharmaceutica Sinica, 50, (1), 15-20, (2015)
   

review - MIPs for proteins

Ansari S et al., Molecularly imprinted polymers for capturing and sensing proteins: Current progress and future implications.
TrAC Trends in Analytical Chemistry, 114, 29-47, (2019)
   

Review - MIPs for protein sensing

Dabrowski M et al., Nanostructured molecularly imprinted polymers for protein chemosensing.
Biosensors and Bioelectronics, 102, 17-26, (2018)
   

Review - MIPs for radioactive ions

Liang HL et al., Application of Ion-Imprinting Technology in the Field of Radiochemistry.
Journal of Nuclear and Radiochemistry, 38, (3), 129-144, (2016)
   

Review - MIPs for removal of dyes from polluted sites

Algieri C et al., Emerging Tools for Recognition and/or Removal of Dyes from Polluted Sites: Molecularly Imprinted Membranes.
Journal of Membrane and Separation Technology, 3, (4), 243-266, (2014)
   

Review - MIPs for sensing

Sharma PS et al., Molecular imprinting for selective chemical sensing of hazardous compounds and drugs of abuse.
TrAC Trends in Analytical Chemistry, 34, (1), 59-77, (2012)
   

Review - MIPs for sensing cancer biomarkers

Selvolini G et al., MIP-Based Sensors: Promising New Tools for Cancer Biomarker Determination.
Sensors, 17, (4), ArticleNo718-(2017)
   

Review - MIPs for sensing cancer cells

Hasanzadeh M et al., Cytosensing of cancer cells using antibody-based molecular imprinting: A short-review.
TrAC Trends in Analytical Chemistry, 99, 129-134, (2018)
   

Review - MIPs for separating active from chinese traditional medicine

Chi D et al., Application of Molecular Imprinting Membrane to Separating Active Components in Chinese Materia Medica.
Guangming Journal of Chinese Medicine, 24, (3), 571-573, (2009)
   

Review - MIPs for separation and anlysis

Hou HQ et al., Recent applications of surface molecularly imprinting materials and techniques for separation and analysis.
Chinese Journal of Chromatography, 34, (12), 1206-1214, (2016)
   

Review - MIPs for separation of active components from traditional medicines

Yi LN et al., Application of molecularly imprinting technology in efficient separation of active components from Traditional Chinese herb.
Journal of International Pharmaceutical Research, 39, (4), 307-310, (2012)
   

Review - MIPs for separation of drugs

Yang S et al., Molecularly Imprinted Polymers for the Identification and Separation of Chiral Drugs and Biomolecules.
Polymers, 8, (6), ArticleNo216-(2016)
   

Review - MIPs for separations

Kubo T et al., Recent progress in molecularly imprinted media by new preparation concepts and methodological approaches for selective separation of targeting compounds.
TrAC Trends in Analytical Chemistry, 81, 102-109, (2016)
   

Review - MIPs for solid phase extraction

Meng ZH et al., Application of Molecularly Imprinted Solid Phase Extraction in the Assay of Environmental Samples.
Chinese Journal of Chromatography, 24, (6), 551-554, (2006)
   

Review - MIPs for SPE

Book chapter, Andersson LI, Solid-phase extraction on molecularly imprinted polymers - requirements, achievements and future work, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 140-148, (2006)
   

Review - MIPs for SPE

BelHadj-Kaabi F et al., Different approaches to synthesizing moleculariy imprinted polymers for solid-phase extraction.
Lc Gc Europe, 20, (7), 406-413, (2007)
   

Review - MIPs for SPE

Hugon-Chapuis F et al., Molecularly imprinted polymers for selective extraction of analytes from biological samples (Polymères à empreintes moléculaires pour l’extraction sélective de composés de milieux biologiques).
Annales de Toxicologie Analytique, 19, (3), 239-251, (2007)
   

Review - MIPs for SPE

Kaabi FB et al., Different approaches to synthesizing molecularly imprinted polymers for solid-phase extraction.
Lc Gc North America, 25, (8), 732-739, (2007)
   

Review - MIPs for SPE

Kaabi FB et al., Different approaches to synthesizing molecularly imprinted polymers for solid-phase extraction.
Lc Gc Europe, 21, (7), 406-+, (2007)
   

Review - MIPs for SPE

Proceeding, Pei HY et al, The Application of Molecularly Imprinted Polymers to Solid-Phase Extraction, 
In: Advanced Materials Research, Kida K (Ed.), 238-286, (2014)
   

Review - MIPs for SPE of drugs

Madikizela LM et al., Applications of molecularly imprinted polymers for solid-phase extraction of non-steroidal anti-inflammatory drugs and analgesics from environmental waters and biological samples.
Journal of Pharmaceutical and Biomedical Analysis, 147, 624-633, (2018)
   

Review - MIPs for steroid recognition

Zhang J et al., The application of molecular imprinting technique in steroid recognition and analysis.
Chemical Reagents, 27, (6), 331-335,351, (2005)
   

Review - MIPs for sulfonylurea herbicides

Guo L et al., Study on Molecular Imprinting Detection Technique of Sulfonylurea Herbicides.
Food Research and Development, 33, (5), 216-219, (2012)
   

Review - MIPs for terpenoids

Liang YL et al., Molecular imprinting technology and its application in terpenoids.
China Journal of Chinese Materia Medica, 43, (2), 267-273, (2018)
   

Review - MIPs for toxic pollutants

Shen XT et al., Molecular imprinting for removing highly toxic organic pollutants.
Chemical Communications, 48, (6), 788-798, (2012)
   

Review - MIPs for trace metal recovery

Deng B, The application of molecular imprinting techniques in selective separation and preconcentration of trace metals.
Chinese Journal of Inorganic Analytical Chemistry, 1, (1), 1-6, (2011)
   

review - MIPs for tumor cells

Fu XP et al., Selective recognition of tumor cells by molecularly imprinted polymers.
Journal of Separation Science, 44, (12), 2483-2495, (2021)
   

Review - MIPs for viral pathogen detection

Malik AA et al., Molecularly imprinted polymer for human viral pathogen detection.
Materials Science and Engineering: C, 77, 1341-1348, (2017)
   

review - MIPs for virus detection

Jamalipour Soufi G et al., Molecularly imprinted polymers for the detection of viruses: challenges and opportunities.
Analyst, 146, (10), 3087-3100, (2021)
   

Review - MIPs for virus recognition

Book chapter, Iqbal Net al., Molecularly Imprinted Polymers (MIPs): Virus Sensing Applications, 
In: Encyclopedia of Biomedical Polymers and Polymeric Biomaterials, Taylor & Francis: 4856-4866, (2015)
   

review - MIPs for virus recognition

Gast M et al., Advances in imprinting strategies for selective virus recognition a review.
TrAC Trends in Analytical Chemistry, 114, 218-232, (2019)
   

Review - MIPs for water

Proceeding, Halvorson B et al, Transitioning molecular imprinted polymers and SERS to the water industry: Practical significance and progress, 
108-111, (2010)
   

Review - MIPs for water analysis and purification

Shen XT et al., Molecularly Imprinted Polymers for Clean Water: Analysis and Purification.
Industrial & Engineering Chemistry Research, 52, (39), 13890-13899, (2013)
   

Review - MIPs for water quality estimation

Zhang P et al., Application of molecularly imprinted polymers in water quality detection.
Water & Wastewater Engineering, 32, (3), 102-107, (2006)
   

review - MIPs for water soluble vitamins

Suwanwong Y et al., Molecularly imprinted polymers for the extraction and determination of water-soluble vitamins: A review from 2001 to 2020.
European Polymer Journal, 161, Article110835-(2021)
   

Review - MIPs for xenoestrogens

Narula P et al., Recent Progress, Challenges and Prospects in Monitoring Plastic-Derived Xenoestrogens Using Molecularly Imprinted Sorbents.
Chromatographia, 77, (3-4), 207-221, (2014)
   

Review - MIPs from chitosan

Xu L et al., Chitosan in Molecularly-Imprinted Polymers: Current and Future Prospects.
International Journal of Molecular Sciences, 16, 18328-18347, (2015)
   

Review - MIPs from conjugated polymers

Öpik A et al., Molecularly imprinted polymers: a new approach to the preparation of functional materials.
Proceedings of the Estonian Academy of Sciences, 58, (1), 3-11, (2009)
   

Review - MIPs from cyclodextrin and catalysis

Karakhanov EA et al., Molecular imprinting technique for the design of cyclodextrin based materials and their application in catalysis.
Current Organic Chemistry, 14, (13), 1284-1295, (2010)
   

Review - MIPs from cyclodextrins

Sun T et al., Molecular Imprinting Technology Based on Cyclodextrins.
Progress In Chemistry, 22, (5), 888-897, (2010)
   

Review - MIPs from electrosynthesis for protein recognition

Erdõssy J et al., Electrosynthesized molecularly imprinted polymers for protein recognition.
TrAC Trends in Analytical Chemistry, 79, 179-190, (2016)
   

Review - MIPs from green approaches

Viveiros R et al., Green Strategies for Molecularly Imprinted Polymer Development.
Polymers, 10, (3), ArticleNo306-(2018)
   

Review - MIPs from micro and nano inorganic materials

Bulatova EV et al., Use of Micro- and Nanodimensional Inorganic Materials in Surface Molecular Imprinting.
Journal of Analytical Chemistry, 73, (8), 750-764, (2018)
   

Review - MIPs from oxides chemical sesors

Afzal A et al., Imprinted Oxide and MIP/Oxide Hybrid Nanomaterials for Chemical Sensors.
Nanomaterials, 8, (4), ArticleNo257-(2018)
   

Review - MIPs from particle-stabilised emulsions

Ye L et al., Molecular imprinting in particle-stabilized emulsions: enlarging template size from small molecules to proteins and cells.
Molecular Imprinting, 3, (1), 8-16, (2016)
   

review - MIPs from polydopamine

Zaidi SA, An Account on the Versatility of Dopamine as a Functional Monomer in Molecular Imprinting.
ChemistrySelect, 4, (17), 5081-5090, (2019)
   

Review - MIPs from poly(HEMA)

Oral E et al., Hydrophilic molecularly imprinted poly(hydroxyethyl-methacrylate) polymers.
Journal of Biomedical Materials Research Part A, 78A, (1), 205-210, (2006)
   

Review - MIPs from polypyrrole

Deore B et al., Enantioselective Uptake of Amino Acids with Molecularly Imprinted Overoxidized Polypyrrole.
Review of Polarography, 47, (2), 76-86, (2001)
   

Review - MIPs from RAFT polymerization

Abdollahi E et al., Molecular Recognition Ability of Molecularly Imprinted Polymer Nano- and Micro-Particles by Reversible Addition-Fragmentation Chain Transfer Polymerization.
Polymer Reviews, 56, (4), 557-583, (2016)
   

Review - MIPs from TiO2

Lai C et al., A review of titanium dioxide and its highlighted application in molecular imprinting technology in environment.
Journal of the Taiwan Institute of Chemical Engineers, 91, 517-531, (2018)
   

Review - MIPs functional monomer selection

Chi DM et al., Development in the Research of the Selection Methods of Functional Monomer in Molecular Imprinting.
Chemical Industry Times, 23, (12), 55-57, (2009)
   

Review - MIPs grafted to carbon nanotubes

Dai H et al., Synthesis and analytical applications of molecularly imprinted polymers on the surface of carbon nanotubes: a review.
Microchimica Acta, 182, (5-6), 893-908, (2015)
   

Review - MIPs green aspects

Madikizela LM et al., Green aspects in molecular imprinting technology: From design to environmental applications.
Trends in Environmental Analytical Chemistry, 17, 14-22, (2018)
   

Review - MIPs hybrid materials

Book chapter, Dai S, Molecular imprinting using hybrid materials as host matrices, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 347-361, (2005)
   

Review - MIPs hydrogels

Byrne ME et al., Molecular imprinting within hydrogels II: Progress and analysis of the field.
International Journal of Pharmaceutics, 364, (2), 188-212, (2008)
   

Review - MIPs imprinted with dummy templates

Xu ZG et al., Development of dummy template molecularly imprinted techniques in sample pretreatment.
Progress In Chemistry, 24, (8), 1592-1598, (2012)
   

review - MIPs imprinted with epitopes

Yang KG et al., Recent advances and application of epitope imprinted materials.
Chinese Science Bulletin, 64, (13), 1368-1379, (2019)
   

review - MIPs imprinted with epitopes

Yang KG et al., Epitope Imprinting Technology: Progress, Applications, and Perspectives toward Artificial Antibodies.
Advanced Materials, 31, (50), Article1902048-(2019)
   

review - MIPs imprinted with epitopes for biomolecule recognition

Dietl S et al., Epitope-imprinted polymers for biomacromolecules: Recent strategies, future challenges and selected applications.
TrAC Trends in Analytical Chemistry, 143, Article116414-(2021)
   

review - MIPs imprinted with peptide epitopes

Khumsap T et al., Epitope-imprinted polymers: applications in protein recognition and separation.
RSC Advances, 11, (19), 11403-11414, (2021)
   

Review - MIPs in affinity separation

Wei ST et al., Recent advances on noncovalent molecular imprints for affinity separations.
Journal of Separation Science, 30, (11), 1794-1805, (2007)
   

Review - MIPs in analysis

Takeuchi T, Analytical applications of molecularly imprinted polymers.
Chromatography, 20, (4), 316-317, (1999)
   

Review - MIPs in analysis

Sadecka J et al., Molecularly imprinted polymers in analytical chemistry.
Chemicke Listy, 99, (4), 222-230, (2005)
   

Review - MIPs in analysis

Lachová M et al., Applications of molecularly imprinted polymers in analytical and pharmaceutical chemistry.
Ceska a Slovenska Farmacie, 56, (4), 159-164, (2007)
   

Review - MIPs in analysis of food contaminants

Zhang XY et al., Solid phase extraction of food contaminants using molecular imprinted polymers.
Science and Technology of Food Industry, 30, (1), 341-344, (2009)
   

review - MIPs in analysis of residues in meat

Banan K et al., MIP-based extraction techniques for the determination of antibiotic residues in edible meat samples: Design, performance & recent developments.
Trends In Food Science & Technology, 119, 164-178, (2022)
   

Review - MIPs in analysis of veterinary drug residues in food

Qiu SC et al., Application of molecular imprinting technique in residue analysis of veterinary drugs in food.
Journal of Food Safety and Quality, 6, (6), 2248-2255, (2015)
   

Review - MIPs in analytical chemistry

Haupt K, Molecularly imprinted polymers in analytical chemistry.
Analyst, 126, (6), 747-756, (2001)
   

Review - MIPs in analytical chemistry

Kandimalla VB et al., Molecular imprinting: a dynamic technique for diverse applications in analytical chemistry.
Analytical and Bioanalytical Chemistry, 380, (4), 587-605, (2004)
   

Review - MIPs in analytical chemistry

Tóth B et al., Molecularly imprinted polymers: optimization of their preparation by combinatorial methods and applications in non-linear chromatography and binding assays. Molekuláris lenyomatú polimerek: kombinatorikus elõállítás, nemlineáris kromatográfi a és pszeudo-immunanalitika.
Magyar Kémiai Folyóirat, 111, (3), 110-113, (2005)
   

Review - MIPs in analytical chemistry

Li CX et al., Application and progress of molecularly imprinted technique in analytical chemistry.
Metallurgical Analysis, 28, (12), 41-50, (2008)
   

Review - MIPs in analytical chemistry

Wei X et al., Research progress of surface molecular imprinting technique in analytical chemistry.
Ion Exchange and Adsorption, 29, (2), 183-192, (2013)
   

review - MIPs in analytical chemistry

Malik MI et al., Recent Applications of Molecularly Imprinted Polymers in Analytical Chemistry.
Separation & Purification Reviews, 48, (3), 179-219, (2019)
   

review - MIPs in anti-doping

Hand RA et al., Application of molecularly imprinted polymers in the anti-doping field: sample purification and compound analysis.
Analyst, 145, (14), 4716-4736, (2020)
   

Review - MIPs in aqueous environments

Book chapter, Wan YCet al., MIPs in Aqueous Environments, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 131-166, (2015)
   

Review - MIPs in aqueous systems

Zhang HQ, Water-compatible molecularly imprinted polymers: Promising synthetic substitutes for biological receptors.
Polymer, 55, (3), 699-714, (2014)
   

Review - MIPs in assays

Piletsky SA et al., Substitution of antibodies and receptors with molecularly imprinted polymers in enzyme-linked and fluorescent assays.
Biosensors and Bioelectronics, 16, (9-12), 701-707, (2001)
   

Review - MIPs in assays

Xu ZX et al., Advances in molecularly imprinted sorbent immunoassay and its application.
Modern Chemical Industry, 28, (4), 32-35, (2008)
   

Review - MIPs in assays and microchips

Book chapter, Moreno-Bondi MCet al., Immuno-Like Assays and Biomimetic Microchips, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 111-164, (2012)
   

Review - MIPs in binding and catalysis

Shea KJ, Molecular imprinting of synthetic network polymers: The de novo synthesis of macromolecular binding and catalytic sites.
Trends in Polymer Science, 2, (5), 166-173, (1994)
   

Review - MIPs in bioagent detection

Book chapter, Warriner Ket al., Molecular Imprinted Polymers for Biorecognition of Bioagents, 
In: Principles of Bacterial Detection: Biosensors, Recognition Receptors and Microsystems, Zourob M, Elwary S, Turner A (Eds.) Springer: New York, 785-814, (2008)
   

Review - MIPs in bioanalysis

Tse Sum Bui B et al., Molecularly imprinted polymers: synthetic receptors in bioanalysis.
Analytical and Bioanalytical Chemistry, 398, (6), 2481-2492, (2010)
   

review - MIPs in bioanalysis

Li RF et al., Advances in Molecularly Imprinting Technology for Bioanalytical Applications.
Sensors, 19, (1), ArticleNo177-(2019)
   

Review - MIPs in bioassays and biotransformations

Book chapter, Liu YBet al., Molecularly Imprinted Polymers as Tools for Bioassays and Biotransformation, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 207-226, (2015)
   

Review - MIPs in biochemical engineering

Xu ZX et al., Research advances in molecular imprinting technique and its application in biochemical engineering.
Modern Chemical Industry, 27, (SUPPL. 1), 137-141, (2007)
   

Review - MIPs in biological and environmental analysis

Ansari S et al., Novel developments and trends of analytical methods for drug analysis in biological and environmental samples by molecularly imprinted polymers.
TrAC Trends in Analytical Chemistry, 89, 146-162, (2017)
   

Review - MIPs in biological applications

Schirhagl R, Bioapplications for Molecularly Imprinted Polymers.
Analytical Chemistry, 86, (1), 250-261, (2014)
   

Review - MIPs in biomedical applications

Book chapter, Puoci Fet al., Molecularly Imprinted Polymers (MIPs) in Biomedical Applications, 
In: Biopolymers, Elnashar M (Ed.) InTech: 547-574, (2010)
   

Review - MIPs in biomedical applications

Book chapter, Mujahid Aet al., Molecular Imprinted Polymers for Biomedical Applications, 
In: Supramolecular Systems in Biomedical Fields, Schneider HJ (Ed.) Royal Society of Chemistry: Cambridge, UK, 419-450, (2013)
   

review - MIPs in biomedicine

Choi JR et al., Progress in Molecularly Imprinted Polymers for Biomedical Applications.
Combinatorial Chemistry & High Throughput Screening, 22, (2), 78-88, (2019)
   

Review - MIPs in biomimetic assays

Díaz-Díaz G et al., New materials for analytical biomimetic assays based on affinity and catalytic receptors prepared by molecular imprinting.
TrAC Trends in Analytical Chemistry, 33, (1), 68-80, (2012)
   

review - MIPs in biomimetic binding assays

Becskereki G et al., The Selectivity of Immunoassays and of Biomimetic Binding Assays with Imprinted Polymers.
International Journal of Molecular Sciences, 22, (19), ArticleNo10552-(2021)
   

Review - MIPs in biomimetic immunoassays

Xu ZX et al., The Biomimetic Immunoassay Based on Molecularly Imprinted Polymer: A Comprehensive Review of Recent Progress and Future Prospects.
Journal of Food Science, 76, (2), R69-R75, (2011)
   

Review - MIPs in biomimetic sensor arrays

Cuypers W et al., Combining Two Selection Principles: Sensor Arrays Based on Both Biomimetic Recognition and Chemometrics.
Frontiers in Chemistry, 6, ArticleNo268-(2018)
   

Review - MIPs in biosensors

Book chapter, Gajovic-Eichelmann Net al., Molecular Imprinting Technique for Biosensing and Diagnostics, 
In: Applications of Nanomaterials in Sensors and Diagnostics, Tuantranont A (Ed.) Springer: Berlin Heidelberg, 143-170, (2013)
   

Review - MIPs in biosensors

Cieplak M et al., Artificial Biosensors: How Can Molecular Imprinting Mimic Biorecognition?
Trends In Biotechnology, 34, (11), 922-941, (2016)
   

Review - MIPs in biosensors

Ertürk G et al., Molecular Imprinting Techniques Used for the Preparation of Biosensors.
Sensors, 17, (2), ArticleNo288-(2017)
   

Review - MIPs in biotechnology

Book chapter, Spivak DA, MIPs in biotechnology, perspective and reality, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 182-190, (2006)
   

Review - MIPs in business

Book chapter, Leverkus P, Business models for the commercialisation of MIPs, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 191-198, (2006)
   

review - MIPS in cancer treatment

Zaidi SA, Molecular Imprinting Prevents Environmental Contamination and Body Toxicity from Anticancer Drugs: An Update.
Critical Reviews in Analytical Chemistry, 49, (4), 324-335, (2019)
   

Review - MIPs in capacitive biosensors

Ertürk G et al., Capacitive Biosensors and Molecularly Imprinted Electrodes.
Sensors, 17, (2), ArticleNo390-(2017)
   

Review - MIPs in capillary electrochromatography

Shibukawa A, Separation of optical isomers by capillary electrochromatography using the molecular imprint method.
Bunseki, (2), 131-(1998)
   

Review - MIPs in capillary electrochromatography

Turiel E et al., Molecular imprinting technology in capillary electrochromatography.
Journal of Separation Science, 28, (8), 719-728, (2005)
   

Review - MIPs in capillary electrochromatography

Liu ZS et al., Molecularly imprinted polymers as a tool for separation in CEC.
Electrophoresis, 28, (1-2), 127-136, (2007)
   

Review - MIPs in capillary electrochromatography

Huang YP et al., Recent developments of molecularly imprinted polymer in CEC.
Electrophoresis, 30, (1), 155-162, (2009)
   

Review - MIPs in capillary electrochromatography

Iacob BC et al., Recent advances in capillary electrochromatography using molecularly imprinted polymers.
Electrophoresis, 35, (19), 2722-2732, (2014)
   

Review - MIPs in capillary electrochromatography (CEC)

Mu LN et al., Current trends in the development of molecularly imprinted polymers in CEC.
Electrophoresis, 36, (5), 764-772, (2015)
   

Review - MIPs in capillary electrophoresis

Book chapter, Brüggemann O, Capillary electrophoresis, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 553-578, (2005)
   

Review - MIPs in catalysis

Huo PW et al., Molecular imprinting technology and its application in field of catalysis.
Chemical Reagents, 30, (6), 421-425,448, (2008)
   

Review - MIPs in catalysis

Book chapter, Muratsugu Set al., Molecularly Imprinted Polymers as Catalysts toward Artificial Enzymes, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 259-308, (2013)
   

Review - MIPs in catalysis

Book chapter, Dechtrirat Det al., Catalytically Active MIP Architectures, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 19-34, (2016)
   

Review - MIPs in CE

Liu X et al., Monolithic Column and Coating Capillary Based on Molecularly Imprinted Polymers for Separation of Organic Compounds in Capillary Electrochromatography.
Current Organic Chemistry, 17, (15), 1659-1665, (2013)
   

Review - MIPs in CE and CEC

Book chapter, Bossi Aet al., Imprinted polymers in capillary electrophoresis and capillary electrochromatography, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 149-163, (2006)
   

Review - MIPs in CEC

Li HX et al., Highly selective separations by capillary electrochromatography with molecular imprint-based stationary phases.
Chemical Research and Application, 14, (5), 525-530, (2002)
   

Review - MIPs in CEC

Huang YP et al., Molecularly Imprinted Polymers for the Separation of Organic Compounds in Capillary Electrochromatography.
Current Organic Chemistry, 15, (11), 1863-1870, (2011)
   

Review - MIPs in CEC

Yue CY et al., Application of molecularly imprinted polymers particles in capillary electrochromatography.
Chinese Journal of Chromatography, 31, (1), 10-14, (2013)
   

Review - MIPs in charal separation and analysis

Rutkowska M et al., Application of molecularly imprinted polymers in analytical chiral separations and analysis.
TrAC Trends in Analytical Chemistry, 102, 91-102, (2018)
   

Review - MIPs in chemiluminescence analysis

Hu YF et al., Application of molecular imprinted techniques in chemiluminescence analysis.
Journal of Instrumental Analysis, 28, (8), 989-994, (2009)
   

Review - MIPs in Chinese herbal medicine

Li JY et al., Combinational Technology of Separation, Selection and Identification on Active Composition of Chinese Traditional Herb and Molecular Imprinting Technology.
Lishizhen Medicine and Materia Medica Research, 19, (12), 2901-2904, (2008)
   

Review - MIPs in chiral chromatography

Zhu L et al., The progress on mechanism of molecular imprinted chiral recognition and applied in chromatography.
China Adhesives, 16, (10), 50-54, (2007)
   

Review - MIPs in chiral recognition

Maier NM et al., Chiral recognition applications of molecularly imprinted polymers: a critical review.
Analytical and Bioanalytical Chemistry, 389, (2), 377-397, (2007)
   

Review - MIPs in chiral separation

Meng ZH et al., Application of molecular imprinting in chiral separation.
Chinese Journal of Analytical Chemistry, 25, (3), 349-354, (1997)
   

Review - MIPs in chiral separation

Book chapter, Sellergren B, Separation of Enantiomers Using Molecularly Imprinted Polymers, 
In: Chiral Separation Techniques, Subramanian G (Ed.) WILEY-VCH Verlag GmbH & Co.: Weinheim, 399-431, (2007)
   

Review - MIPs in chiral separations

Kempe M et al., Molecular imprinting used for chiral separations.
Journal of Chromatography A, 694, (1), 3-13, (1995)
   

review - MIPs in chiral separations and sensing

Moein MM, Advancements of chiral molecularly imprinted polymers in separation and sensor fields: A review of the last decade.
Talanta, 224, Article121794-(2021)
   

Review - MIPs in Chromatography

Xu ZG, Molecular imprinting Technique and Its Application in Chromatography Separation.
Journal of Qiongzhou University, 13, (2), 15-17, (2006)
   

Review - MIPs in chromatography

Book chapter, Tóth Bet al., Chromatography, Solid-Phase Extraction, and Capillary Electrochromatography with MIPs, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 267-306, (2012)
   

Review - MIPs in chromatography

Book chapter, Renkecz Tet al., Molecularly Imprinted Polymers for Chromatography and Related Techniques, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 141-196, (2013)
   

Review - MIPs in chromatography and SPE

Pichon V et al., Affinity separations on molecularly imprinted polymers with special emphasis on solid-phase extraction.
Journal of Liquid Chromatography & Related Technologies, 29, (7-8), 989-1023, (2006)
   

Review - MIPs in clinical diagnostics

Piletsky SA et al., Molecularly imprinted polymers in clinical diagnostics - Future potential and existing problems.
Medical Engineering & Physics, 28, (10), 971-977, (2006)
   

Review - MIPs in commercial sensors

Hayden O, One Binder to Bind Them All.
Sensors, 16, (10), ArticleNo1665-(2016)
   

Review - MIPs in contact lenses

Alvarez-Lorenzo C et al., Ocular drug delivery from molecularly-imprinted contact lenses.
Journal of Drug Delivery Science and Technology, 20, (4), 237-248, (2010)
   

Review - MIPs in contact lenses

White CJ et al., Molecularly imprinted therapeutic contact lenses.
Expert Opinion on Drug Delivery, 7, (6), 765-780, (2010)
   

Review - MIPs in contact lenses for occular drug delivery

Tashakori-Sabzevar F et al., Development of ocular drug delivery systems using molecularly imprinted soft contact lenses.
Drug Development and Industrial Pharmacy, 41, (5), 703-713, (2015)
   

review - MIPs in coronavirus detectionand treatment

Nahhas AF et al., The promising use of nano-molecular imprinted templates for improved SARS-CoV-2 detection, drug delivery and research.
Journal of Nanobiotechnology, 19, (1), Article305-(2021)
   

review - MIPs incorporating aptamers

Ali GK et al., Molecular imprinted polymer combined with aptamer (MIP-aptamer) as a hybrid dual recognition element for bio(chemical) sensing applications. Review.
Talanta, 236, Article122878-(2022)
   

Review - MIPs in dermal drug delivery

Suedee R, The Use of Molecularly Imprinted Polymers for Dermal Drug Delivery.
Pharmaceutica Analytica Acta, 4, (8), Art No. 264-(2013)
   

Review - MIPs in desulfurization of fuels

Book chapter, Ogunlaja ASet al., Molecularly Imprinted Polymer Nanofibers for Adsorptive Desulfurization, 
In: Applying Nanotechnology to the Desulfurization Process in Petroleum Engineering, Saleh TA (Ed.) IGI Global: Hershey, PA, 281-336, (2016)
   

Review - MIPs in determination of food contaminents

Zhou ZZ et al., Research Progress of Molecular Imprinting Technique in the Determination of Food Contaminants.
Journal of Anhui Agricultural Sciences, (7), 3967-3969, 3972, (2012)
   

Review - MIPs in diagnostic assays

Bedwell TS et al., Analytical applications of MIPs in diagnostic assays: future perspectives.
Analytical and Bioanalytical Chemistry, 408, (7), 1735-1751, (2016)
   

Review - MIPs in diagnostic sensors

Book chapter, Altintas Z, Molecular imprinting technology in advanced biosensors for diagnostics, 
In: Advances in Biosensors Research, Everett TG (Ed.) Nova Science Publishers Inc.: New York, 1-29, (2015)
   

review - MIPs in DNA biosensors

Nawaz N et al., Molecularly imprinted polymers-based DNA biosensors.
Analytical Biochemistry, 630, Article114328-(2021)
   

Review - MIPs in drug analysis

Pu JZ et al., The application of molecular imprinting polymer in pharmaceutical analysis.
West China Journal of Pharmaceutical Sciences, 18, (2), 122-124, (2003)
   

Review - MIPs in drug analysis

Guo H et al., Molecularly Imprinted Technique and Application in Drug Analysis.
Journal of Liaoning Police Academy, (3), 54-(2009)
   

Review - MIPs in drug analysis

Zhang CB et al., Application of Molecular Imprinting Technology in the Detection of Drug Residues.
Food Science, 35, (9), 323-328, (2014)
   

Review - MIPs in drug delivery

Alvarez-Lorenzo C et al., Molecularly imprinted polymers for drug delivery.
Journal of Chromatography B-Analytical Technologies in the Biomedical and Life Sciences, 804, (1), 231-245, (2004)
   

Review - MIPs in drug delivery

Cunliffe D et al., Molecularly imprinted drug delivery systems.
Advanced Drug Delivery Reviews, 57, (12), 1836-1853, (2005)
   

Review - MIPs in drug delivery

Sellergren B et al., Molecularly imprinted polymers: A bridge to advanced drug delivery.
Advanced Drug Delivery Reviews, 57, (12), 1733-1741, (2005)
   

Review - MIPs in drug delivery

Zhang Y et al., Advances in Drug Delivery System Based on Molecularly Imprinted Polymers.
Chinese Pharmaceutical Journal, 41, (21), 1605-1608, (2006)
   

Review - MIPs in drug delivery

Figueiredo EC et al., Molecular imprinting: A promising strategy in matrices elaboration for drug delivery systems.
Brazilian Journal of Pharmaceutical Sciences, 44, (3), 361-375, (2008)
   

Review - MIPs in drug delivery

Puoci F et al., Molecularly imprinted polymers in drug delivery: state of art and future perspectives.
Expert Opinion on Drug Delivery, 8, (10), 1379-1393, (2011)
   

Review - MIPs in drug delivery

Book chapter, da Silva MSet al., High Affinity Polymers by Molecular Imprinting for Drug Delivery, 
In: Polymerization, Gomes ADS (Ed.) InTech: 145-162, (2012)
   

Review - MIPs in drug delivery

Book chapter, Alvarez-Lorenzo Cet al., Molecularly Imprinted Polymers as Components of Drug Delivery Systems, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 309-349, (2013)
   

Review - MIPs in drug delivery

Lulinski P, Molecularly imprinted polymers as the future drug delivery devices.
Acta Poloniae Pharmaceutica - Drug Research, 70, (4), 601-609, (2013)
   

Review - MIPs in drug delivery

Suedee R, Novel Strategic Innovations for Designing Drug Delivery System Using Molecularly Imprinted Micro/Nanobeads.
International Journal of Pharmaceutical Sciences Review and Research, 20, (2), 235-268, (2013)
   

Review - MIPs in drug delivery

Gagliardi M et al., Molecularly imprinted polymeric micro- and nano-particles for the targeted delivery of active molecules.
Future Medicinal Chemistry, 7, (2), 123-138, (2015)
   

Review - MIPs in drug delivery

Dhanashree S et al., Molecularly Imprinted Polymers: Novel Discovery for Drug Delivery.
Current Drug Delivery, 13, (5), 632-645, (2016)
   

Review - MIPs in drug delivery

Zaidi SA, Molecular imprinted polymers as drug delivery vehicles.
Drug Delivery, 23, (7), 2262-2271, (2016)
   

Review - MIPs in drug delivery

Lulinski P, Molecularly imprinted polymers based drug delivery devices: a way to application in modern pharmacotherapy. A review.
Materials Science and Engineering: C, 76, 1344-1353, (2017)
   

Review - MIPs in drug delivery

Tuwahatu CA et al., The molecularly imprinted polymer essentials: curation of anticancer, ophthalmic, and projected gene therapy drug delivery systems.
Journal of Controlled Release, 287, 24-34, (2018)
   

review - MIPs in drug delivery

He SN et al., Advances of molecularly imprinted polymers (MIP) and the application in drug delivery.
European Polymer Journal, 143, Article110179-(2021)
   

review - MIPs in drug delivery

Liu R et al., Advances in Molecularly Imprinted Polymers as Drug Delivery Systems.
Molecules, 26, (12), ArticleNo3589-(2021)
   

Review - MIPs in drug discovery

Rathbone DL, Molecularly imprinted polymers in the drug discovery process.
Advanced Drug Delivery Reviews, 57, (12), 1854-1874, (2005)
   

Review - MIPs in drug residue SPE of animal-based foods

Yan HY et al., Application of molecularly imprinted solid-phase extraction on drug residues in animal source foods.
Chinese Journal of Chromatography, 29, (7), 572-579, (2011)
   

Review - MIPs in drug screening

Book chapter, Allender C, Molecularly imprinted polymers in drug screening, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 164-181, (2006)
   

Review - MIPs in drug separation

Liu ZS et al., Application of molecular imprinted monolith in drug separation.
Chinese Journal of Pharmaceutical Analysis, 26, (11), 1684-1688, (2006)
   

Review - MIPs in electroanalysis of proteins

Shumyantseva VV et al., Molecularly imprinted polymers in electro analysis of proteins.
Biomeditsinskaya Khimiya, 61, (3), 325-331, (2015)
   

Review - MIPs in electroanalysis of proteins

Shumyantseva VV et al., Molecularly imprinted polymers (MIP) in electroanalysis of proteins.
Biochemistry (Moscow) Supplement Series B: Biomedical Chemistry, 10, (2), 145-151, (2016)
   

review - MIPs in electrochemical and optical sensing

Ahmad OS et al., Molecularly Imprinted Polymers in Electrochemical and Optical Sensors.
Trends In Biotechnology, 37, (3), 294-309, (2019)
   

Review - MIPS in electrochemical detection of drugs

Adumitrachioaie A et al., Electrochemical Methods Based on Molecularly Imprinted Polymers for Drug Detection. A Review.
International Journal of Electrochemical Science, 13, 2556-2576, (2018)
   

Review - MIPs in electrochemical protein detection

Liu YL et al., The fabrication of molecularly imprinted electochemical sensor and its application in protein detection.
Chemical Industry and Engineering Progress, 36, (7), 2533-2539, (2017)
   

Review - MIPs in electrochemical sensing

Liu ZH et al., Progress of electrochemical sensor based on molecular imprinting.
Chemical Sensors (China), 25, (4), 1-8, (2005)
   

Review - MIPs in electrochemical sensing

Sharma PS et al., Electrochemically synthesized polymers in molecular imprinting for chemical sensing.
Analytical and Bioanalytical Chemistry, 402, (10), 3177-3204, (2012)
   

Review - MIPs in electrochemical sensing

Frasco MF et al., Imprinting Technology in Electrochemical Biomimetic Sensors.
Sensors, 17, (3), ArticleNo523-(2017)
   

review - MIPs in electrochemical sensing

Scheller FW et al., Molecularly imprinted polymer-based electrochemical sensors for biopolymers.
Current Opinion in Electrochemistry, 14, 53-59, (2019)
   

Review - MIPs in electrochemical sensing of pesticides

Liu XY, The Progress of the Study on Molecularly Imprinted Electrochemical Sensor for Pesticides Determining.
Journal of Simao Teachers College, (6), 14-16, (2008)
   

Review - MIPs in electrochemical sensors

Blanco-López MC et al., Electrochemical sensors based on molecularly imprinted polymers.
TrAC Trends in Analytical Chemistry, 23, (1), 36-48, (2004)
   

Review - MIPs in electrochemical sensors

Ma JJ et al., Progress in the Study on Electrochemical Sensor with Molecularly Imprinted Polymers as Sensitive Material.
Electronic Components & Materials, 23, (10), 48-51, (2004)
   

Review - MIPs in electrochemical sensors

Li CY et al., Progress of Electrochemical Sensors Based on Molecularly Imprinted Polymers.
Journal of Analytical Science, 22, (5), 605-610, (2006)
   

Review - MIPs in electrochemical sensors

Xiong L, Recent progress of electrochemical sensor based on molecularly imprinted polymers.
Meteorological, Hydrological and Marine Instruments, 26, (4), 172-175,178, (2009)
   

Review - MIPs in electrochemical sensors

Chen ZQ et al., Progress on construction and research of sensing films of molecularly imprinted electrochemical sensors.
Journal of Instrumental Analysis, 29, (1), 97-104, (2010)
   

Review - MIPs in electrochemical sensors

Book chapter, Fuchiwaki Yet al., Electrochemical Sensor Based on Biomimetic Recognition Utilizing Molecularly Imprinted Polymer Receptor, 
In: Biomimetics Learning from Nature, Mukherjee A (Ed.) InTech: 385-398, (2010)
   

Review - MIPs in electrochemical sensors

Suryanarayanan V et al., Molecularly Imprinted Electrochemical Sensors.
Electroanalysis, 22, (16), 1795-1811, (2010)
   

Review - MIPs in electrochemical sensors

Luan CL et al., Progress of molecularly imprinted electrochemical sensor.
Chemical Industry and Engineering Progress, 30, (2), 353-358,370, (2011)
   

Review - MIPs in electrochemical sensors

Yáñez-Sedeño P et al., Electrochemical sensors based on magnetic molecularly imprinted polymers: A review.
Analytica Chimica Acta, 960, 1-17, (2017)
   

Review - MIPs in electrochemical sensors

Yang B et al., Frontiers in highly sensitive molecularly imprinted electrochemical sensors: Challenges and strategies.
TrAC Trends in Analytical Chemistry, 105, 53-7, (2018)
   

review - MIPs in electrochemical sensors

Lahcen AA et al., Recent Advances in Electrochemical Sensors Based on Molecularly Imprinted Polymers and Nanomaterials.
Electroanalysis, 31, (2), 188-201, (2019)
   

review - MIPs in electrochemical sensors

Radi AE et al., Electrochemical Sensors Based on Molecularly Imprinted Polymers for Pharmaceuticals Analysis.
Current Analytical Chemistry 15 219-239 (2019)
   

review - MIPs in electrochemical sensors

Herrera-Chacón A et al., Molecularly imprinted polymers - towards electrochemical sensors and electronic tongues.
Analytical and Bioanalytical Chemistry, 413, (24), 6117-6140, (2021)
   

review - MIPs in electrochemical sensors

Hasseb AA et al., Application of molecularly imprinted polymers for electrochemical detection of some important biomedical markers and pathogens.
Current Opinion in Electrochemistry, 31, Article100848-(2022)
   

Review - MIPs in electrochemiluminescence analysis

Li SP et al., Progress in Molecular Imprinting Electrochemiluminescence Analysis.
Chinese Journal of Analytical Chemistry, 43, (2), 294-299, (2015)
   

review - MIPs in electronic tongues

Book chapter, Herrera-Chacon Aet al., Voltammetric electronic tongues using sensors based on molecularly imprinted polymers, 
In: Electronic Tongues, IOP Publishing: 5_1-5_19, (2021)
   

Review - MIPs in electropolymerized chemical sensors

Shang ZY et al., Advance Research of Molecular Imprinted Chemical Sensors Based on Electropolymerization.
Journal of Instrumental Analysis, 32, (11), 1401-1408, (2013)
   

Review - MIPs in electrospun nanofibre membranes

Ghorani B et al., Approaches for the assembly of molecularly imprinted electrospun nanofibre membranes and consequent use in selected target recognition.
Food Research International, 78, 448-464, (2015)
   

Review - MIPs in enantioselective sensors

Tiwari MP et al., Molecularly imprinted polymer based enantioselective sensing devices: A review.
Analytica Chimica Acta, 853, 1-18, (2015)
   

Review - MIPs in enantioseparation of drugs

Ansell RJ, Molecularly imprinted polymers for the enantioseparation of chiral drugs.
Advanced Drug Delivery Reviews, 57, (12), 1809-1835, (2005)
   

Review - MIPs in enatioselective sensing

Book chapter, Tiwari MPet al., Moleculalry Imprinted Polymer as Advanced Material for Development of Enantioselective Sensing Devices, 
In: Advanced Sensor and Detection Materials, Tiwari A, Demir MM (Eds.) John Wiley & Sons Inc.: Hoboken, 87-109, (2014)
   

Review - MIPs in environmental analysis

Martín-Esteban A, Recent molecularly imprinted polymer-based sample preparation techniques in environmental analysis.
Trends in Environmental Analytical Chemistry, 9, 8-14, (2016)
   

Review - MIPs in environmental analysis

Soledad-Rodríguez B, Technological Innovations in the Industry. A Proposal for the Analysis of Environmental Contaminants with Molecular Imprint Polymers (Innovaciones Tecnológicas En La Industria. Una Propuesta Para El Análisis De Contaminantes Ambientales Con Polímeros De Impronta Molecular).
Revista Techné, 21, (2), 19-51, (2018)
   

review - MIPs in environmental analysis

Soledad-Rodríguez BE, Analysis of environmental contaminants with molecularly imprinted polymers [ANÁLISIS DE CONTAMINANTES AMBIENTALES CON POLÍMEROS DE IMPRONTA MOLECULAR].
Revista Internacional de Contaminación Ambiental, 36, (1), 197-207, (2020)
   

review - MIPs in environmental analysis

Hua YB et al., Recent progress on hollow porous molecular imprinted polymers as sorbents of environmental samples.
Microchemical Journal, 171, Article106848-(2021)
   

Review - MIPs in environmental applications

Xiao HH et al., Progress of the application of molecular imprinting technique in environmental field.
Chemistry Bulletin, 72, (8), 701-706, (2009)
   

Review - MIPs in environmental biotechnology

Book chapter, Mattiasson B, MIPs as Tools in Environmental Biotechnology, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 183-205, (2015)
   

Review - MIPs in environmental monitoring

Liu XH et al., Research and development of molecular imprinting technique in the environmental monitoring field.
Energy Environmental Protection, 19, (1), 1-4, (2005)
   

Review - MIPs in environmental science

Jin HH et al., Application of Molecular Imprinting Technique in Environmental Science.
Environmental Protection of Chemical Industry, 26, (4), 295-298, (2006)
   

Review - MIPs in environmental science

Book chapter, Bach Met al., Molecularly Imprinted Polymers as Traps for Environmental and Bioremediation Applications, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 229-258, (2013)
   

Review - MIPs in environmental science

Proceeding, Fu WD, Relevant Discussion about the Application of Molecular Imprinting Technology in Environmental Science, 
Yao M, Liang H (Eds.), 13-17, (2015)
   

Review - MIPs in environmental science

Book chapter, Keçili Ret al., Tailor-Made Molecular Traps for the Treatment of Environmental Samples, 
In: Handbook of Environmental Materials Management, Hussain CM (Ed.) Springer International Publishing: Cham, 1-22, (2018)
   

Review - MIPs in environmental Science

Xiao G et al., Advances in molecularly imprinted supramolecular technology for monitoring and controlling trace environmental pollutants.
Scientia Sinica Chimica, 48, (3), 266-276, (2018)
   

Review - MIPs in enzyme-like catalysis

Book chapter, Li SJet al., Molecularly Imprinted Polymers for Enzyme-like Catalysis: Principle, Design, and Applications, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 1-17, (2016)
   

Review - MIPs in e-tongue senor arrays

Huynh TP et al., Molecularly imprinted polymers as recognition materials for electronic tongues.
Biosensors and Bioelectronics, 74, 856-864, (2015)
   

Review - MIPs in extraction and separation

Tarley CRT et al., Biomimetic polymers in analytical chemistry. Part 1: Preparation and applications of MIP (molecularly imprinted polymers) in extraction and separation techniques.
Quimica Nova, 28, (6), 1076-1086, (2005)
   

Review - MIPs influence of monomers

Guc M et al., The Molecularly Imprinted Polymers. Influence of Monomers on The Properties of Polymers - A Review.
World Journal of Research and Review, 5, (6), 36-47, (2017)
   

Review - MIPs in fluorescence sensing

Yang Q et al., Strategies of molecular imprinting-based fluorescence sensors for chemical and biological analysis.
Biosensors and Bioelectronics, 112, 54-71, (2018)
   

review - MIPs in fluorescense sensing

Liu GY et al., Recent Advances and Perspectives of Molecularly Imprinted Polymer-Based Fluorescent Sensors in Food and Environment Analysis.
Nanomaterials, 9, (7), ArticleNo1030-(2019)
   

Review - MIPs in fluorescent sensing

Sunayama H et al., Molecularly imprinted materials: Applications to fluorescent sensing systems.
Kobunshi, 61, (6), 406-409, (2012)
   

Review - MIPs in food analysis

Ramström O et al., Food analyses using molecularly imprinted polymers.
Journal of Agricultural and Food Chemistry, 49, (5), 2105-2114, (2001)
   

Review - MIPs in food analysis

Tang KJ et al., Applications of Molecular Imprinting Technology in Trace Analysis of Food.
Journal of Food Science and Biotechnology, 26, (6), 105-109, (2007)
   

Review - MIPs in food analysis

Lok CM et al., Application of molecularly imprinted polymers in food sample analysis - A perspective.
International Food Research Journal, 16, (2), 127-140, (2009)
   

Review - MIPs in food analysis

Regal P et al., Application of molecularly imprinted polymers in food analysis: clean-up and chromatographic improvements.
Central European Journal of Chemistry, 10, (3), 766-784, (2012)
   

Review - MIPs in food analysis

Song XL et al., Recent advances in molecularly imprinted polymers in food analysis.
Journal of Applied Polymer Science, 131, (16), Article40766-(2014)
   

Review - MIPs in food analysis

Ashley J et al., Molecularly imprinted polymers for sample preparation and biosensing in food analysis: Progress and perspectives.
Biosensors and Bioelectronics, 91, 606-615, (2017)
   

Review - MIPs in food quality and safety

Tang SF, Research progress on application of molecular imprinting technique in detection of quality and safety of aquatic products.
Journal of Food Safety and Quality, 8, (4), 1220-1226, (2017)
   

Review - MIPs in food safety

Liu HF et al., Application of molecular imprinting technique in food safety detection.
Food Science and Technology, (7), 1-4, (2007)
   

Review - MIPs in food safety

Ji DS et al., Application of Molecular Imprinting Technique in Animal Derived Food Detection.
Meat Research, (3), 66-68,43, (2008)
   

Review - MIPs in food safety

Xu XY et al., Application of molecular imprinting technique in the detection of food safety.
Guangdong Agricultural Sciences, (11), 108-(2008)
   

Review - MIPs in food safety

An FK et al., Application of molecular imprinting technology in food safety detection and analysis.
Food Research and Development, 30, (3), 154-157, (2009)
   

Review - MIPs in food safety

Gao YF et al., Research Progress of Molecular Imprinting Technique in Food Safety Detection.
Biological Disaster Science, 36, (1), 100-104, (2013)
   

Review - MIPs in food safety

Suo A et al., New methods for preparation of molecularly imprinted polymers and their application in food safety.
Journal of Food Safety and Quality, 5, (11), 3587-3591, (2014)
   

Review - MIPs in food safety

Wang PL et al., Advancements of molecularly imprinted polymers in the food safety field.
Analyst, 141, (12), 3540-3553, (2016)
   

review - MIPs in food safety

Huang C et al., Recent application of molecular imprinting technique in food safety.
Journal of Chromatography A, 1657, Article462579-(2021)
   

Review - MIPs in forensic analysis

McCluskey A et al., Molecularly imprinted polymers (MIPs): sensing, an explosive new opportunity?
Organic & Biomolecular Chemistry, 5, (20), 3233-3244, (2007)
   

Review - MIPs in forensic science

Chang J et al., The development of molecularly imprinted technology research in forensic science toxicology.
Chinese Journal of Forensic Medicine, 25, (6), 411-413, (2010)
   

Review - MIPs in forensic science

Yilmaz E et al., Molecular Imprinting Applications in Forensic Science.
Sensors, 17, (4), ArticleNo691-(2017)
   

review - MIPs in forensic science

Ferreira JB et al., Molecularly imprinted polymers as a selective sorbent for forensic applications in biological samples - a review.
Analytical and Bioanalytical Chemistry, 413, (24), 6013-6036, (2021)
   

review - MIPs in green chemistry

Arabi M et al., Molecular Imprinting: Green Perspectives and Strategies.
Advanced Materials, 33, (30), Article2100543-(2021)
   

Review - MIPs in health care

Book chapter, Ganjali MRet al., Biomimetic Molecularly Imprinted Polymers as Smart Materials and Future Perspective in Health Care, 
In: Advanced Healthcare Materials, Tiwari A (Ed.) Wiley: Hoboken, 465-492, (2014)
   

Review - MIPs in health security

Book chapter, Sharma PSet al., Macromolecular Imprinting for Improved Health Security, 
In: Biosensors for Security and Bioterrorism Applications, Nikolelis PD, Nikoleli GP (Eds.) Springer International Publishing: Cham, 141-160, (2016)
   

Review - MIPs in HPLC

Huai QY et al., Molecular Imprinted Polymers as Chromatographic Stationary Phases for Molecular Recognition.
Journal of Instrumental Analysis, 20, (6), 84-89, (2001)
   

Review - MIPs in HPLC

Liu YQ et al., Investigation and progress of chromatography column packed with molecularly imprinted polymer.
Chemical Research and Application, 19, (4), 351-357, (2007)
   

Review - MIPs in HPLC

Book chapter, Spivak DA, Enantioseparations by high-performance liquid chromatography using molecularly imprinted polymers, 
In: Chiral Separations, Methods and Protocols, Scriba GKE (Ed.) Humana Press: 209-220, (2013)
   

Review - MIPs in illegal drugs detection

Xiao DL et al., Molecularly imprinted polymers for the detection of illegal drugs and additives: a review.
Microchimica Acta, ArticleNo185, (4), 247-(2018)
   

Review - MIPs in immunoassays

Book chapter, Ansell RJ, Application of MIPs as antibody mimics in immunoassays, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 641-683, (2005)
   

Review - MIPs in immunoassays

Ge Y et al., Molecularly Imprinted Sorbent Assays: Recent Developments and Applications.
Chemistry - A European Journal, 15, (33), 8100-8107, (2009)
   

Review - MIPs in in vivo sensing

Book chapter, Ge Yet al., Molecularly Imprinted Polymers: Promising Advanced Materials for In Vivo Sensing, 
In: Microelectrode Biosensors, Marinesco S, Dale N (Eds.) Humana Press: 369-384, (2013)
   

Review - MIPs in isolation of active constituents of chinese traditional medicine

Lin Z et al., Application of molecular imprinting technique to separating and purifying active components in Chinese materia medica.
Chinese Traditional and Herbal Drugs, 38, (3), 457-460, (2007)
   

Review - MIPs in isolation of active constituents of natural products

Zhou YY et al., Application of molecular imprinting technology in the separation and purification of active ingredients from natural products.
Chinese Journal of Chromatography, 27, (3), 359-363, (2009)
   

Review - MIPs in (mass and electrochemical) sensors

Book chapter, Haupt K, Molecularly imprinted polymers as recognition elements in sensors: mass and electrochemical sensors, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 685-700, (2005)
   

Review - MIPs in medical devices

Book chapter, Peeters Met al., Molecularly Imprinted Polymers: Synthetic Receptors for Diagnostic Medical Devices, 
In: Molecularly Imprinted Catalysts: Principles, Syntheses and Applications, Li SJ, Cao SS, Piletsky SA, Turner APF (Eds.) Elsevier: Amsterdam, 253-271, (2016)
   

Review - MIPs in medical diagnostics

Lulinski P et al., Investigations of molecularly imprinted polymers for medical diagnostics and clinical analysis.
Polimery w Medycynie, 41, (1), 3-15, (2011)
   

Review - MIPs in medicine

Schillemans JP et al., Molecularly imprinted polymer particles: synthetic receptors for future medicine.
Nanomedicine, 1, (4), 437-447, (2006)
   

review - MIPs in metabolomics

Ozcelikay G et al., Sensor-based MIP technologies for targeted metabolomics analysis.
TrAC Trends in Analytical Chemistry, 146, Article116487-(2022)
   

Review - MIPs in metal organic frameworks for sensing

Guo ZZ et al., Molecularly Imprinted Polymer/Metal Organic Framework Based Chemical Sensors.
Coatings, 6, (4), ArticleNo42-(2016)
   

Review - MIPs in microanalysis

Zhang LF, Study on Molecular Imprinted Technique and Its Application in Microanalysis.
Journal of Hebei North University (Natural Science Edition), 21, (3), 13-17, (2005)
   

Review - MIPs in microanalysis

Zhang LF, Molecular Imprinting Technique and Its Application to Micro Analysis.
Journal of Qujing Normal University, 24, (3), 14-18, (2005)
   

Review - MIPs in micro- and nano-fabrication

Book chapter, Bompart Met al., Micro and Nanofabrication of Molecularly Imprinted Polymers, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 83-110, (2012)
   

Review - MIPs in micro-extraction

Li G et al., Recent Applications of Molecularly Imprinted Polymers (MIPs) on Micro-extraction Techniques.
Separation & Purification Reviews, 47, (1), 1-18, (2018)
   

Review - MIPs in microorganism analysis

Jia MF et al., Molecular imprinting technology for microorganism analysis.
TrAC Trends in Analytical Chemistry, 106, 190-201, (2018)
   

Review - MIPs in micro-solid phase extraction

Moreda-Pineiro A et al., MIPs as a Versatile Tool for Micro-Solid-Phase Extraction and Probe Sensing.
Current Chemical Biology, 12, (2), 114-134, (2018)
   

review - MIPs in microSPE

Turiel E et al., Molecularly imprinted polymers-based microextraction techniques.
TrAC Trends in Analytical Chemistry, 118, 574-586, (2019)
   

review - MIPs in microSPE

Santos H et al., Molecularly imprinted polymers for miniaturized sample preparation techniques: strategies for chromatographic and mass spectrometry methods.
Analytical Methods, 12, (7), 894-911, (2020)
   

review - MIPS in miniaturized extraction devices

Bouvarel T et al., Molecularly imprinted polymers in miniaturized extraction and separation devices.
Journal of Separation Science, 44, (8), 1727-1751, (2021)
   

Review - MIPs in modern biotechnology

Sergeyeva TA, Molecularly-imprinted polymers as synythetic mimics of bioreceptors. 2. Applications in modern biotechnology.
Biopolymers and Cell, 25, (6), 431-444, (2009)
   

review - MIPs in nanomedicine

Garnier M et al., Hybrid Molecularly Imprinted Polymers: The Future of Nanomedicine?
Nanomaterials, 11, (11), ArticleNo3091-(2021)
   

Review - MIPs in nanosensr applications

Irshad M et al., Molecularly Imprinted Nanomaterials for Sensor Applications.
Nanomaterials, 3, (4), 615-637, (2013)
   

Review - MIPs in online SPE

Proceeding, Sun Q et al, The Recent Advance of Molecularly Imprinted on-Line Solid Phase Extraction and its Application in Sample Pretreatment - A Mini Review, 
In: Advanced Materials Research, Bu JL, Jiang ZY, Jiao SH (Eds.), 1799-1805, (2011)
   

Review - MIPs in open tubuar electrochromatography

Book chapter, Cheong WJet al., Open Tubular Molecular Imprinted Phases in Chiral Capillary Electrochromatography, 
In: Chiral Separations, Methods and Protocols, Scriba GKE (Ed.) Humana Press: 469-487, (2013)
   

Review - MIPs in optical chemosensors

Book chapter, Moreno-Bondi MCet al., Molecularly Imprinted Polymer-based Optical Chemosensors for Selective Chemical Determinations, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 227-281, (2018)
   

Review - MIPs in optical sensing

Moreno-Bondi MC et al., Molecularly imprinted polymers as selective recognition elements in optical sensing.
Current Analytical Chemistry, 4, (4), 316-340, (2008)
   

Review - MIPs in optical sensors

Al-Kindy S et al., Molecularly imprinted polymers and optical sensing applications.
Critical Reviews in Analytical Chemistry, 30, (4), 291-309, (2000)
   

Review - MIPs in optical sensors

Book chapter, Gao SHet al., Molecularly imprinted polymers as recognition elements in optical sensors, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 701-726, (2005)
   

review - MIPs in optical sensors

Rico-Yuste A et al., Molecularly Imprinted Polymer-Based Hybrid Materials for the Development of Optical Sensors.
Polymers, 11, (7), ArticleNo1173-(2019)
   

Review - MIPs inorganic matrices

Book chapter, Defreese JLet al., Imprinting in inorganic matrices, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 307-327, (2005)
   

Review - MIPs in organic synthesis

Yuan XY et al., Molecularly imprinted polymer and its application in organic synthesis.
Journal of Hubei University (Natural Science Edition), 24, (3), 250-255+266, (2002)
   

review - MIPs in paper-based analytical devices

Li W et al., Molecularly imprinted polymer-enhanced biomimetic paper-based analytical devices: A review.
Analytica Chimica Acta, 1148, Article238196-(2021)
   

review - MIPs in paper-based sensors

Mamipour Z et al., Molecularly imprinted polymer grafted on paper and flat sheet for selective sensing and diagnosis: a review.
Microchimica Acta, 188, (8), Article279-(2021)
   

Review - MIPs in pesticide detection

Farooq S et al., Molecularly imprinted polymers’ application in pesticide residue detection.
Analyst, 143, (17), 3971-3989, (2018)
   

Review - MIPs in pesticide residue detection

Yang XH et al., Progress of molecular imprinting technique on the determination of pesticides residues.
Journal of Food Safety and Quality, 8, (2), 462-467, (2017)
   

Review - MIPs in pharmaceutical analysis

Baggiani C et al., Molecular imprinted polymers: Useful tools for pharmaceutical analysis.
Current Pharmaceutical Analysis, 2, (3), 219-247, (2006)
   

Review - MIPs in pharmaceutical analysis

Zhang CL et al., Study and Application of Molecular Imprinting Technique in Pharmaceutical Analysis.
Journal of Taishan University, 30, (6), 60-64, (2008)
   

Review - MIPs in pharmaceutical analysis

Book chapter, Lulinski P, Molecularly Imprinted Polymers for Pharmaceutical Analysis, 
In: Handbook of Polymers for Pharmaceutical Technologies, Bioactive and Compatible Synthetic/Hybrid Polymers, Thakur VK, Thakur MK (Eds.) John Wiley & Sons: 179-202, (2015)
   

Review - MIPs in pharmaceutical analysis

Kubo T et al., Recent progress for the selective pharmaceutical analyses using molecularly imprinted adsorbents and their related techniques: A review.
Journal of Pharmaceutical and Biomedical Analysis, 130, (Review Issue 2016), 68-80, (2016)
   

Review - MIPs in pharmaceutical aplications

van Nostrum CF, Molecular imprinting: A new tool for drug innovation.
Drug Discovery Today: Technologies, 2, (1), 119-124, (2005)
   

Review - MIPs in pharmaceutical applications

Book chapter, Singh AKet al., Molecularly Imprinted Polymers for Pharmaceutical Applications, 
In: Handbook of Polymers for Pharmaceutical Technologies, Bioactive and Compatible Synthetic/Hybrid Polymers, Thakur VK, Thakur MK (Eds.) John Wiley & Sons: 17-66, (2015)
   

Review - MIPs in pharmaceutical processing

Yilmaz E et al., MIP-based processing.
Innovations in Pharmaceutical Technology, (27), 88-91, (2009)
   

Review - MIPs in pharmaceutical science

Cao YB et al., Advance of Application of Molecular Imprinting Technique in Pharmaceutical Science.
Guangzhou Chemistry, 33, (4), 56-60, (2008)
   

Review - MIPs in pharmaceutical science

Li L, Application of Molecular Imprinting Technique in Pharmaceutical Science.
Journal of Hebei Institute of Technology, 32, (2), 87-89,96, (2010)
   

Review - MIPs in pharmaceutical science

Lulinski P, Molecularly imprinted polymers in pharmaceutical sciences. Part II. Applications in pharmaceutical analysis.
Polimery, 56, (1), 3-10, (2011)
   

Review - MIPs in pharmaceutical separation and analysis

Su JH et al., Application of Molecular Imprinting Technique in Separation and Analysis of Pharmaceutical.
Journal of Hebei Institute of Technology, 32, (3), 99-101, (2010)
   

Review - MIPs in photonic devices

Han XY et al., Recent Progress of Imprinted Polymer Photonic Waveguide Devices and Applications.
Polymers, 10, (6), ArticleNo603-(2018)
   

review - MIPs in photopolymerisation and photostructuring

Paruli E et al., Photopolymerization and Photostructuring of Molecularly Imprinted Polymers.
ACS Applied Polymer Materials, 3, (10), 4769-4790, (2021)
   

Review - MIPs in piezoelectric sensors

Ávila M et al., Molecularly imprinted polymers for selective piezoelectric sensing of small molecules.
TrAC Trends in Analytical Chemistry, 27, (1), 54-65, (2008)
   

review - MIPs in potentiometric sensors

Kamel AH et al., Survey on the Integration of Molecularly Imprinted Polymers as Artificial Receptors in Potentiometric Transducers for pharmaceutical Drugs.
International Journal of Electrochemical Science, 14, 2085-2124, (2019)
   

Review - MIPs in proteiin chemosensing

Book chapter, Cieplak Met al., Protein Determination Using Molecularly Imprinted Polymer (MIP) Chemosensors, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 282-329, (2018)
   

review - MIPs in protein analysis

Halvorsen TG et al., Affinity capture in bottom-up protein analysis - Overview of current status of proteolytic peptide capture using antibodies and molecularly imprinted polymers.
Analytica Chimica Acta, 1182, Article338714-(2021)
   

review - MIPs in protein chromatography

Bereli N et al., Protein chromatography by molecular imprinted cryogels.
Journal of Liquid Chromatography & Related Technologies, 43, (15-16), 657-670, (2020)
   

review - MIPs in protein sensing

Yarman A et al., Simple and robust: The claims of protein sensing by molecularly imprinted polymers.
Sensors and Actuators B: Chemical, 330, Article129369-(2021)
   

review - MIPs in proteomics

Xing RR et al., Recent progress in the combination of molecularly imprinted polymer-based affinity extraction and mass spectrometry for targeted proteomic analysis.
TrAC Trends in Analytical Chemistry, 110, 417-428, (2019)
   

Review - MIPs in QCM sensors

Diltemiz SE et al., Molecular Imprinting Technology in Quartz Crystal Microbalance (QCM) Sensors.
Sensors, 17, (3), ArticleNo454-(2017)
   

Review - MIPs in regenerative engineering

Clegg JR et al., Vision for Functionally Decorated and Molecularly Imprinted Polymers in Regenerative Engineering.
Regenerative Engineering and Translational Medicine, 3, (3), 166-175, (2017)
   

Review - MIPs in sample preparation

Haginaka J, Molecularly imprinted polymers as affinity-based separation media for sample preparation.
Journal of Separation Science, 32, (10), 1548-1565, (2009)
   

Review - MIPs in sample preparation

Kloskowski A et al., Progress in Development of Molecularly Imprinted Polymers as Sorbents for Sample Preparation.
Critical Reviews in Analytical Chemistry, 39, (1), 43-58, (2009)
   

Review - MIPs in sample preparation

Martin-Esteban A, Molecularly Imprinted Polymers: Providing Selectivity to Sample Preparation.
Journal of Chromatographic Science, 47, (3), 254-256, (2009)
   

Review - MIPs in sample preparation

Book chapter, Sellergren Bet al., The Use of Molecularly Imprinted Polymers for Sampling and Sample Preparation, 
In: Handbook of Sample Preparation, Pawliszyn J, Lord HL (Eds.) John Wiley & Sons: Hoboken, New Jersey, 445-474, (2010)
   

Review - MIPs in sample preparation

Turiel E et al., Molecularly imprinted polymers for sample preparation: A review.
Analytica Chimica Acta, 668, (2), 87-99, (2010)
   

Review - MIPs in sample preparation

Book chapter, Carro-Diaz AMet al., Molecularly Imprinted Polymers for Sample Preparation, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 87-140, (2013)
   

Review - MIPs in sample preparation

Hu YL et al., Novel applications of molecularly-imprinted polymers in sample preparation.
TrAC Trends in Analytical Chemistry, 43, 37-52, (2013)
   

Review - MIPs in sample preparation

Martín-Esteban A, Molecularly-imprinted polymers as a versatile, highly selective tool in sample preparation.
TrAC Trends in Analytical Chemistry, 45, 169-181, (2013)
   

Review - MIPs in sample preparation

Gama MR et al., Molecularly imprinted polymers for bioanalytical sample preparation.
Journal of Chromatography B, 1043, 107-121, (2017)
   

Review - MIPs in sample preparation

Book chapter, Kyzas GZet al., Advances in Sample Preparation for Molecular Imprinting in Environmental Applications, 
In: Chromatographic Analysis of the Environment: Mass Spectrometry Based Approaches, Nollet LML, Lambropoulou DA (Eds.) CRC Press: Boca Raton, 221-235, (2017)
   

Review - MIPs in sample preparation

Book chapter, Martín-Esteban A, Molecularly Imprinted Polymers: Providing Selectivity to Sample Preparation, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 379-411, (2018)
   

review - MIPs in sample preparation

Pichon V et al., Sample Preparation Using Molecularly Imprinted Polymers.
Analytical Chemistry, 92, (1), 16-33, (2020)
   

Review - MIPs in sensing

Sharma PS et al., Bioinspired intelligent molecularly imprinted polymers for chemosensing: A mini review.
Electrochemistry Communications, 50, 81-87, (2015)
   

Review - MIPs in sensing and diagnostics

Book chapter, Zhang HQet al., Molecular Imprinting Technique for Biomimetic Sensing and Diagnostics, 
In: Biomedical Nanomaterials, Zhao YL, Shen YQ (Eds.) Wiley: Weinheim, 283-326, (2016)
   

Review - MIPs in sensing and separation

Advincula RC, Engineering molecularly imprinted polymer (MIP) materials: Developments and challenges for sensing and separation technologies.
Korean Journal of Chemical Engineering, 28, (6), 1313-1321, (2011)
   

Review - MIPs in sensor arrays

Shimizu KD et al., Molecularly imprinted polymer sensor arrays.
Current Opinion in Chemical Biology, 14, (6), 743-750, (2010)
   

Review - MIPs in sensors

Liu Q et al., Recent progresses in research on molecular imprinting sensors.
Chinese Journal of Analytical Chemistry, 27, (11), 1341-1347, (1999)
   

Review - MIPs in sensors

Xu WJ et al., Biomimetic chemsensor based on molecular imprinting technology.
Polymer Materials Science and Engineering, 18, (6), 16-19, (2002)
   

Review - MIPs in sensors

Xong L et al., Molecular Imprinting Technique and its Application in Sensors.
Meteorological, Hydrological and Marine Instruments, 20, (2), 12-17, (2003)
   

Review - MIPs in sensors

He YH et al., The progress of the study on molecular imprinting-based biomimetic sensors.
Chinese Journal of Analytical Chemistry, 32, (10), 1407-1412, (2004)
   

Review - MIPs in sensors

Tarley CRT et al., Biomimetic polymers in analytical chemistry. Part 2: Applications of MIP (Molecularly Imprinted Polymers) in the development of chemical sensors.
Quimica Nova, 28, (6), 1087-1101, (2005)
   

Review - MIPs in sensors

Holthoff EL et al., Molecularly templated materials in chemical sensing.
Analytica Chimica Acta, 594, (2), 147-161, (2007)
   

Review - MIPs in sensors

Liu YQ et al., Development of Molecularly Imprinted Polymer Sensor.
Journal of Instrumental Analysis, 26, (3), 450-454, (2007)
   

Review - MIPs in sensors

BelBruno JJ et al., Amazing pores: Processing, morphology and functional states of molecularly imprinted polymers as sensor materials.
Molecular Crystals And Liquid Crystals, 483, 179-190, (2008)
   

Review - MIPs in sensors

Guan GJ et al., Imprinting of Molecular Recognition Sites on Nanostructures and Its Applications in Chemosensors.
Sensors, 8, (12), 8291-8320, (2008)
   

Review - MIPs in sensors

Book chapter, Meier Fet al., Molecularly Imprinted Polymers as Artificial Receptors, 
In: Artificial Receptors for Chemical Sensors, Mirsky VM, Yatsimirsky AK (Eds.) Wiley-VCH Verlag GmbH & Co. KGaA: Weinheim, 391-437, (2010)
   

Review - MIPs in sensors

Book chapter, Zhang YGet al., Molecular Imprinting and Sensor Development, 
In: Chemosensors, Wang B, Anslyn EV (Eds.) John Wiley & Sons, Inc.: Hoboken, N.J., 107-120, (2011)
   

Review - MIPs in sensors

Book chapter, Suriyanarayanan Set al., Chemosensors Based on Molecularly Imprinted Polymers, 
In: Molecular Imprinting, Haupt K (Ed.) Springer: Berlin / Heidelberg, 165-265, (2012)
   

Review - MIPs in sensors

Book chapter, Muti Met al., Molecularly Imprinted Polymer-Based Biosensors, 
In: Portable Biosensing of Food Toxicants and Environmental Pollutants, Nikolelis DP, Varzakas T, Erdem A, Nikoleli GP (Eds.) CRC Press: Boca Raton, Fl., 373-394, (2014)
   

Review - MIPs in sensors

Book chapter, Gupta BDet al., Molecular-Imprinting-Based Sensors, 
In: Optical Sensors for Biomedical Diagnostics and Environmental Monitoring, Gupta BD, Shrivastav AM, Usha SP (Eds.) CRC Press: Boca Raton, (2017)
   

Review - MIPs in sensors

Pohanka M, Sensors Based on Molecularly Imprinted Polymers.
International Journal of Electrochemical Science, 12, 8082-8094, (2017)
   

Review - MIPs in sensors

Book chapter, Puiu Met al., Biomimetic Sensors Based on Molecularly Imprinted Interfaces, 
In: Past, Present and Future Challenges of Biosensors and Bioanalytical Tools in Analytical Chemistry: A Tribute to Professor Marco Mascini, Palchetti I, Hansen PD, Barcelo D (Eds.) Elsevier: 147-177, (2017)
   

review - MIPs in sensors

Leibl N et al., Molecularly Imprinted Polymers for Chemical Sensing: A Tutorial Review.
Chemosensors, 9, (6), ArticleNo123-(2021)
   

Review - MIPs in sensors and arrays

Book chapter, Southard GEet al., Molecularly Imprinted Polymer Receptors for Sensors and Arrays, 
In: Recognition Receptors in Biosensors, Zourob M (Ed.) Springer: 751-775, (2010)
   

review - MIPs in sensors and assays

Lowdon JW et al., MIPs for commercial application in low-cost sensors and assays - An overview of the current status quo.
Sensors and Actuators B: Chemical, 325, Article128973-(2020)
   

Review - MIPs in sensors and diagnostics

Book chapter, Aktas-Uygun Det al., Applications of Molecularly Imprinted Nanostructures in Biosensors and Medical Diagnosis, 
In: Biosensors and Nanotechnology, Altintas Z (Ed.) John Wiley & Sons, Inc.: 201-218, (2018)
   

Review - MIPs in sensors, assays and catalysis

Proceeding, Zhang LM et al, The Applications of Molecularly Imprinted Polymer in Immunoassay, Biosensor and Enzyme Mimic Catalyst-A Critical Review, 
In: Advanced Materials Research, Wu JH, Zhao MT, Wu B (Eds.), 84-87, (2012)
   

review - MIPs in sensors for antibiotics

Benachio I et al., Employing molecularly imprinted polymers in the development of electroanalytical methodologies for antibiotic determination.
Journal of Molecular Recognition, 34, (3), Article_e2878-(2021)
   

Review - MIPs in sensors for environmental applications

Lieberzeit PA et al., Chemosensors in environmental monitoring: challenges in ruggedness and selectivity.
Analytical and Bioanalytical Chemistry, 393, (2), 467-472, (2009)
   

Review - MIPs in sensors for macromolecules

Saylan Y et al., Molecular Imprinting of Macromolecules for Sensor Applications.
Sensors, 17, (4), ArticleNo898-(2017)
   

Review - MIPs in sensors for therapeutic applications

Hillberg AL et al., Molecular imprinted polymer sensors: Implications for therapeutics.
Advanced Drug Delivery Reviews, 57, (12), 1875-1889, (2005)
   

review - MIPs in separation

Book chapter, Rhouati Aet al., MIPs and Aptamers as Artificial Receptors in Advanced Separation Techniques, 
In: Handbook of Smart Materials in Analytical Chemistry, de la Guardia M, Esteve-Turrillas FA (Eds.) Wiley: 825-857, (2019)
   

Review - MIPs in separation of chiral drugs

Ma JJ et al., Application of Molecularly Imprinted Polymers in Separation of Chiral Drugs and Determination of Medicines.
Chemical Industry Times, 18, (1), 5-8, (2004)
   

Review - MIPs in separations

Ding ZT et al., Research Advance of Molecularly Imprinted Polymers in the Separation Technique.
Yunnan Chemical Technology, 29, (2), 16-19, (2002)
   

review - MIPs in SERS-based sensing

Ma J et al., An overview on molecular imprinted polymers combined with surface-enhanced Raman spectroscopy chemical sensors toward analytical applications.
Talanta, 225, Article122031-(2021)
   

Review - MIPs in silica

Book chapter, Katada Net al., Re-birth of molecular imprinting on silica, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 26-40, (2006)
   

Review - MIPs in silica

Kan XW et al., The Preparation and Applications of Molecularly Imprinted Polymers Based on Silica Materials.
Progress In Chemistry, 22, (1), 107-112, (2010)
   

Review - MIPs in sol-gels

Díaz-García ME et al., Molecular imprinting in sol-gel materials: Recent developments and applications.
Microchimica Acta, 149, (1-2), 19-36, (2005)
   

Review - MIPs in solid phase extraction

Mitrowska K et al., New high selective sorbents for solid-phase extraction. Molecularly imprinted polymers.
Wiadomosci Chemiczne, 58, (2004)
   

Review - MIPs in solid phase extraction

Li HL et al., Applications of Molecular Imprinted Monolithic Material in Solid-phase Extraction and Its Prospect.
Materials Review, 22, (z3), 131-134,141, (2008)
   

Review - MIPs in solid phase extraction

Lasáková M et al., Molecularly imprinted polymers and their application in solid phase extraction.
Journal of Separation Science, 32, (5-6), 799-812, (2009)
   

Review - MIPs in solid phase extraction

Proceeding, Jin YZ et al, Application and Development of Molecularly Imprinted Polymer to Solid Phase Extraction, 
In: Advanced Materials Research, Yu L, Guo JW, Yi GB, Yu Q (Eds.), 1359-1365, (2013)
   

Review - MIPs in solid phase extraction

Wu ZY et al., Study of online molecularly imprinted solid phase extraction techniques in food safety analysis.
Journal of Food Safety and Quality, 5, (5), 1297-1304, (2014)
   

Review - MIPs in solid phase extraction

Soledad-Rodríguez B, Use of Molecularly Imprinted Polymers as Sample Pre-concentrators in Chemical Trace Analysis (Empleo De Polímeros De Impronta Molecular Como Pre-Concentradores De Muestras En El Análisis Químico De Trazas).
Revista Techné, 20, (2), 3-22, (2017)
   

review - MIPs in solid phase extraction

Hu TL et al., Recent advances and applications of molecularly imprinted polymers in solid-phase extraction for real sample analysis.
Journal of Separation Science, 44, (1), 274-309, (2021)
   

review - MIPs in solid phase extraction

Wan QQ et al., A critical review of molecularly imprinted solid phase extraction technology.
Journal of Polymer Research, 28, (10), Article401-(2021)
   

Review - MIPs in solid phase microextraction

Turiel E et al., Molecularly imprinted polymers for solid-phase microextraction.
Journal of Separation Science, 32, (19), 3278-3284, (2009)
   

Review - MIPs in solid-phase microextraction

Zhang MS et al., Developments and Trends of Molecularly Imprinted Solid-Phase Microextraction.
Journal of Chromatographic Science, 51, (7), 577-586, (2013)
   

Review - MIPs in solid phase microextraction

Sarafraz-Yazdi A et al., Application of molecularly-imprinted polymers in solid-phase microextraction techniques.
TrAC Trends in Analytical Chemistry, 73, 81-90, (2015)
   

Review - MIPs in SPE

Masqué N et al., Molecularly imprinted polymers: new tailor-made materials for selective solid-phase extraction.
TrAC Trends in Analytical Chemistry, 20, (9), 477-486, (2001)
   

Review - MIPs in SPE

Dong XC, Application of Molecular Imprinted Polymers to Complex Sample Separation.
Journal of Instrumental Analysis, 23, (6), 119-123, (2004)
   

Review - MIPs in SPE

Liu YC et al., Applications and progress of molecular imprinting technology in solid phase extraction.
Journal of Chemical Industry and Engineering (China), 55, (10), 1602-1607, (2004)
   

Review - MIPs in SPE

Cai YQ et al., Advances in Molecularly Imprinted Solid Phase Extraction.
Journal of Instrumental Analysis, 24, (5), 116-121, (2005)
   

Review - MIPs in SPE

Hu SG et al., Molecularly imprinted polymers: A new kind of sorbent with high selectivity in solid phase extraction.
Progress In Chemistry, 17, (3), 531-543, (2005)
   

Review - MIPs in SPE

Book chapter, Ye L, Solid phase extraction and by-product removal, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 603-618, (2005)
   

Review - MIPs in SPE

Caro E et al., Application of molecularly imprinted polymers to solid-phase extraction of compounds from environmental and biological samples.
TrAC Trends in Analytical Chemistry, 25, (2), 143-154, (2006)
   

Review - MIPs in SPE

Hu XG et al., Application of molecular imprinting technique in sample pretreatment.
Chinese Journal of Analytical Chemistry, 34, (7), 1035-1041, (2006)
   

Review - MIPs in SPE

Widstrand C et al., Selective extractions by molecularly imprinted polymers (MIPs).
The Column, 2, (2), 20-24, (2006)
   

Review - MIPs in SPE

He CY et al., Application of molecularly imprinted polymers to solid-phase extraction of analytes from real samples.
Journal of Biochemical and Biophysical Methods, 70, (2), 133-150, (2007)
   

Review - MIPs in SPE

Pichon V, Selective sample treatment using molecularly imprinted polymers.
Journal of Chromatography A, 1152, (1-2), 41-53, (2007)
   

Review - MIPs in SPE

Tamayo FG et al., Molecularly imprinted polymers for solid-phase extraction and solid-phase microextraction: Recent developments and future trends.
Journal of Chromatography A, 1152, (1-2), 32-40, (2007)
   

Review - MIPs in SPE

Gao HY et al., Molecularly Imprinted Technique Coupled with Solid Phase Microextraction.
Chemical World, 49, (4), 252-254, (2008)
   

Review - MIPs in SPE

Meng FP et al., Molecularly Imprinted Polymers and Their Application to Solid-Phase Extraction.
Journal of Ocean University of Qingdao, 38, (2), 237-243, (2008)
   

Review - MIPs in SPE

Beltran A et al., Molecularly-imprinted polymers: useful sorbents for selective extractions.
TrAC Trends in Analytical Chemistry, 29, (11), 1363-1375, (2010)
   

Review - MIPs in SPE

Wang JP et al., Molecularly Imprinted Polymers Solid Phase Extraction Preconcentration Coupled with HPLC.
Food Research and Development, 32, (2), 171-175, (2011)
   

Review - MIPs in SPE

Li JH et al., Advances of Molecularly Imprinted Polymers for Solid Phase Extraction.
Chinese Journal of Chromatography, 31, (3), 181-184, (2013)
   

Review - MIPs in SPE

Yi LX et al., Molecularly Imprinted Solid-Phase Extraction in the Analysis of Agrochemicals.
Journal of Chromatographic Science, 51, (7), 608-618, (2013)
   

Review - MIPs in SPE

Proceeding, Shen GJ et al, Recent Developments in Molecularly Imprinted Solid Phase Extraction Technology, 
In: Applied Mechanics and Materials, Matsuda K, Pa PS, Yun W (Eds.), 131-134, (2014)
   

Review - MIPs in SPE and Traditional Chinese Medicine

Proceeding, Liu QS et al, Molecularly Imprinted Solid-Phase Extraction: Extraction of Traditional Chinese Medicine Active Ingredients, 
In: Applied Mechanics and Materials, Hegde G (Ed.), 311-313, (2014)
   

Review - MIPs in SPE of active compounds

Chen FF et al., Application of molecularly imprinted solid phase extraction in the separation and determination of active constituents from natural compounds.
Chinese Journal of Chromatography, 31, (7), 626-633, (2013)
   

Review - MIPs in SPE of pesticides

Tang KJ et al., Applications of Molecular Imprinted Solid Phase Extraction in Pesticide Residue Analysis.
Food and Fermentation Industries, 33, (9), 156-160, (2007)
   

Review - MIPs in SPR

Lépinay S et al., In-situ polymerized molecularly imprinted polymeric thin films used as sensing layers in surface plasmon resonance sensors: Mini-review focused on 2010-2011.
Chemical Papers, 66, (5), 340-351, (2012)
   

Review - MIPs in SPR sensors for food safety

Yao T et al., Recent Advances in Application of Surface Plasmon Resonance Sensors Based on Molecular Imprinted Polymers in Food Safety Detection.
Journal of Instrumental Analysis, 34, (2), 237-244, (2015)
   

Review - MIPs in stir bar extration

Hashemi SH et al., Molecularly Imprinted Polymers for Stir Bar Sorptive Extraction: Synthesis, Characterization, and Application.
Analytical Letters, 48, (12), 1815-1829, (2015)
   

Review - MIPs in synthesis

Chen JX et al., Application of Molecular Imprinting Technique in Chemical Reactions.
Chemical Industry and Engineering Progress, 22, (12), 1296-1303, (2003)
   

Review - MIPs in synthesis and catalysis

Book chapter, Mirata Fet al., Molecularly Imprinted Polymers for Catalysis and Synthesis, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 107-129, (2015)
   

Review - MIPs in the analysis of drug residues in food

Lv KQ et al., Application and Research Development of Molecular Imprinting in Analysis of Drug Residues in Food.
Guangzhou Chemical Industry, 45, (2), 18-19,44, (2017)
   

Review - MIPs in the analysis of food and drugs

Zhang LM et al., Recent Advances in the Application of Innovative Molecularly Imprinted Polymers in the Analysis of Foods and Drugs.
Food Science, 35, (15), 314-320, (2014)
   

Review - MIPs in the analysis of myco- and phyco-toxins

Baggiani C et al., Molecular imprinted polymers as synthetic receptors for the analysis of myco- and phyco-toxins.
Analyst, 133, (6), 719-730, (2008)
   

Review - MIPs in the analysis of phenolic environmental estrogens

Xie XY et al., Molecularly imprinting: a tool of modern chemistry for analysis and monitoring of phenolic environmental estrogens.
Reviews In Analytical Chemistry, 35, (2), 87-97-(2016)
   

review - MIPs in the analysis of protein biomarkers

Mostafa AM et al., Review on molecularly imprinted polymers with a focus on their application to the analysis of protein biomarkers.
TrAC Trends in Analytical Chemistry, 144, Article116431-(2021)
   

review - MIPs in the analysis of veterinary drugs

Ibarra IS et al., Sample treatment based on molecularly imprinted polymers for the analysis of veterinary drugs in food samples: a review.
Analytical Methods, 12, (23), 2958-2977, (2020)
   

Review - MIPs in the determination of environmental estrogens

Wang S et al., Determination of Environmental Estrogens by Molecular Imprinting Technique.
Journal of Food Science and Biotechnology, 26, (6), 99-104, (2007)
   

Review - MIPs in the determination of pollutants

Pichon V et al., Role of molecularly imprinted polymers for selective determination of environmental pollutants--A review.
Analytica Chimica Acta, 622, (1-2), 48-61, (2008)
   

Review - MIPs in the quantification of pharmaceutticals

Book chapter, Maciejewska Det al., Molecularly Imprinted Polymer-based Materials for Quantifying Pharmaceuticals, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 145-166, (2018)
   

Review - MIPs in the tobacco industry

Liu CB et al., Application progress of molecular imprinting techniques in the tobacco industry.
Applied Chemical Industry, 39, (9), 1401-1404,418, (2010)
   

review - MIPs in thin film sensors

Unger C et al., Molecularly imprinted thin film surfaces in sensing: Chances and challenges.
Reactive and Functional Polymers, 161, Article104855-(2021)
   

Review - MIPs in tissue engineering

Neves MI et al., Molecularly imprinted intelligent scaffolds for tissue engineering applications.
Tissue Engineering Part B: Reviews, 23, (1), 27-43, (2017)
   

Review - MIPs in trace analysis

Peng T et al., Molecular Imprinting and Its Application to Trace Analysis.
Chinese Journal of Pesticide Science, 3, (4), 1-14, (2001)
   

Review - MIPs in trace analysis of drugs

Ansari S et al., Recent progress, challenges and trends in trace determination of drug analysis using molecularly imprinted solid-phase microextraction technology.
Talanta, 164, 612-625, (2017)
   

Review - MIPs in veterinary drug residue analysis

Zhu XL et al., Research Progress of Molecular Imprinting Technique in the Determination of Veterinary Drug Residues.
Chinese Journal of Veterinary Drug, 41, (6), 34-37, (2007)
   

Review - MIPs in veterinary medicine

Hu YL et al., Application of Molecular Imprinting Technique in Veterinary Drug Residue Analysis.
Progress in Veterinary Medicine, 32, (1), 103-106, (2011)
   

Review - MIPs in voltametric sensors

Book chapter, Muzyka Ket al., Molecularly Imprinted Polymer-based Voltammetric Sensors, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 197-228, (2013)
   

Review - MIPs in wastewater treatment

Huang DL et al., Application of molecularly imprinted polymers in wastewater treatment: a review.
Environmental Science and Pollution Research, 22, (2), 963-977, (2015)
   

review - MIPs in water

Zhou TY et al., Recent advances and trends of molecularly imprinted polymers for specific recognition in aqueous matrix: Preparation and application in sample pretreatment.
TrAC Trends in Analytical Chemistry, 114, 11-28, (2019)
   

Review - MIPs in water treatment

Liu YY et al., Preparation of Surface Molecular Imprinting Microspheres and Its Application in Water Treatment.
Materials Review, 25, (7), 131-134, (2011)
   

Review - MIPs in water treatment

Murray A et al., Application of molecularly imprinted and non-imprinted polymers for removal of emerging contaminants in water and wastewater treatment: a review.
Environmental Science and Pollution Research, 19, (9), 3820-3830, (2012)
   

Review - MIPs isotherm and kinetic models

Kyzas GZ et al., New Biosorbent Materials: Selectivity and Bioengineering Insights.
Processes, 2, (2), 419-440, (2014)
   

Review - MIPs luminescent nanocomposites

Ma YX et al., Luminescent molecularly-imprinted polymer nanocomposites for sensitive detection.
TrAC Trends in Analytical Chemistry, 67, 209-216, (2015)
   

Review - MIPs (magnetic)

Deng F et al., Preparation and Research Progress of Magnetic Molecularly Imprinted Polymers.
Polymer Materials Science and Engineering, 27, (4), 171-174, (2011)
   

Review - MIPs magnetic core-shell particles

Yang WH et al., Preparation and Application of Core-Shell Magnetic Molecularly Imprinted Polymer Microspheres.
Progress In Chemistry, 22, (9), 1819-1825, (2010)
   

Review - MIPs magnetic for protein

Boitard C et al., Magnetic protein imprinted polymers: a review.
Journal of Materials Chemistry B, 6, (11), 1563-1580, (2018)
   

Review - MIPs (magnetic) in food and environmental analysis

Ansari S, Application of magnetic molecularly imprinted polymer as a versatile and highly selective tool in food and environmental analysis: Recent developments and trends.
TrAC Trends in Analytical Chemistry, 90, 89-106, (2017)
   

Review - MIPs (magnetic) in sample preparation

Huang SY et al., Synthesis and application of magnetic molecularly imprinted polymers in sample preparation.
Analytical and Bioanalytical Chemistry, 410, (17), 3991-4014, (2018)
   

Review - MIPs (magnetic) in separation and purification

Li G et al., Applications of Magnetic Molecularly Imprinted Polymers (MMIPs) in the Separation and Purification Fields.
Chromatographia, 81, (1), 73-88, (2018)
   

Review - MIPs membranes

Book chapter, Ulbricht M, Molecularly imprinted membranes, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 80-94, (2006)
   

Review - MIPs membranes

Yang ZG et al., Research progress of molecularly imprinted membrane.
Chemical Industry and Engineering Progress, 25, (2), 131-135, (2006)
   

Review - MIPs membranes

Hao MY et al., Review of Prepartion of Molecularly Imprinted Membrane.
Chinese Polymer Bulletin, (6), 8-14, (2007)
   

Review - MIPs membranes

Li JX et al., Progress in Preparation of Molecularly Imprinted Membrane.
Chinese Polymer Bulletin, (1), 40-44, (2007)
   

Review - MIPs membranes

Zhang HH et al., Progress of the Preparation of Molecularly Imprinted Polymers.
Hunan Agricultural Sciences, (6), 59-60,63, (2007)
   

Review - MIPs micro and nanofabrication aspects

Book chapter, Bokeloh Fet al., Micro and Nanofabrication of Molecularly Imprinted Polymers, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 167-196, (2018)
   

Review - MIPs microspheres

Zheng XM et al., Particle Size and Size Distribution of Molecularly Imprinted Polymeric Microspheres.
Chemical Industry Times, 18, (6), 12-15, (2004)
   

Review - MIPs microspheres

Zhu L et al., Progress of Preparation and Characteristics of Molecularly Imprinted Polymeric Microspheres.
Chinese Polymer Bulletin, (11), 60-66, (2007)
   

Review - MIPs microspheres

Tu RL et al., Progress of the preparation of molecularly imprinted polymeric microspheres by seed swelling and suspension polymerization.
Chemical Industry and Engineering Progress, 28, (6), 978-981, (2009)
   

Review - MIPs modelling

Levi L et al., A brief review of coarse-grained and other computational studies of molecularly imprinted polymers.
Journal of Molecular Recognition, 24, (6), 883-891, (2011)
   

Review - MIPs modified by post-imprinting modifications

Takeuchi T et al., Preparation of Multi-Functional Molecularly Imprinted Polymer Receptors via Post-Imprinting Modifications.
Kobunshi Ronbunshu, 73, (1), 19-29, (2016)
   

Review - MIPs modified post-polymerisation

Book chapter, Shimizu KD, Post modification of imprinted polymers, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 329-345, (2005)
   

Review - MIPs monolayers

Balamurugan S et al., Molecular imprinting in monolayer surfaces.
Journal of Molecular Recognition, 24, (6), 915-929, (2011)
   

Review - MIPs monolithic CEC

Liang Z et al., Development of Molecularly Imprinted Monolithic Column for Capillary Electrochromatography.
Journal of Instrumental Analysis, 26, (5), 757-762, (2007)
   

Review - MIPs monolithic columns in HPLC

Li YR et al., Progress of Molecularly Imprinted Monolithic Column for HPLC.
Chinese Journal of Pharmaceuticals, 38, (4), 313-317, (2007)
   

Review - MIPs monoliths in chrotography

Feng T et al., Applications of Molecularly Imprinted Monolithic Columns in Sample Preparation and Chromatographic Analysis.
Journal of Instrumental Analysis, 30, (10), 1191-1198, (2011)
   

Review - MIPs morphology and performance - sol-gels

Lofgreen JE et al., Controlling morphology and porosity to improve performance of molecularly imprinted sol-gel silica.
Chemical Society Reviews, 43, (3), 911-933, (2014)
   

Review - MIPs(nano) in food analysis

Book chapter, Tothill IEet al., Nano Molecular Imprinted Polymers (NanoMIPs) for Food Diagnostics and Sensor, 
In: Nanotechnology: Food and Environmental Paradigm , Prasad R, Kumar V, Kumar M (Eds.) Springer Singapore: Singapore, 131-151, (2017)
   

Review - MIPs nanomaterials in biosensing

Book chapter, Ju HXet al., Biosensing Applications of Molecularly Imprinted Nanomaterials, 
In: NanoBiosensing: Principles, Development and Applications, Ju HX, Zhang XJ, Wang J (Eds.) Springer: New York, 265-303, (2011)
   

Review - MIPs noncovalent imprinting

Zhang HQ et al., Non-covalent molecular imprinting with emphasis on its application in separation and drug development.
Journal of Molecular Recognition, 19, (4), 248-259, (2006)
   

Review - MIP sol-gels in medicine

Concu R et al., Molecularly Imprinted Sol-Gel Materials for Medical Applications.
Current Topics in Medicinal Chemistry, 15, (3), 199-222, (2015)
   

Review - MIPs on inorganic supports

Polyanina DA et al., Molecularly imprinted inorganic supports in high-performance liquid chromatography and solid-phase extraction.
Journal of Analytical Chemistry, 70, (3), 277-286, (2015)
   

Review - MIPs on silica gel

Zhang SH et al., Progress in Syntheses and Investigation of Molecular Imprinting Polymers on Silica-Gel Surface.
Chinese Polymer Bulletin, (4), 17-29, (2010)
   

review - MIPs on TiO2 matrices

Sajini T et al., A brief overview of molecularly imprinted polymers supported on titanium dioxide matrices.
Materials Today Chemistry, 11, 283-295, (2019)
   

Review - MIPs optimisation and characterisation

Spivak DA, Optimization, evaluation, and characterization of molecularly imprinted polymers.
Advanced Drug Delivery Reviews, 57, (12), 1779-1794, (2005)
   

Review - MIPs patents

Book chapter, McIntyre JB, A general survey of patents in the field of molecularly imprinted polymers, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 199-204, (2006)
   

Review - MIP-SPE

Qiao FX et al., Molecularly Imprinted Polymers for Solid Phase Extraction.
Chromatographia, 64, (11), 625-634, (2006)
   

Review - MIP-SPE in food analysis

Book chapter, Manesiotis Pet al., 4.20 - Applications of SPE-MIP in the Field of Food Analysis, 
In: Comprehensive Sampling and Sample Preparation, Pawliszyn J (Ed.) Academic Press: Oxford, 457-471, (2012)
   

Review - MIP-SPE of food contaminants

Baggiani C et al., Solid phase extraction of food contaminants using molecular imprinted polymers.
Analytica Chimica Acta, 591, (1), 29-39, (2007)
   

Review - MIPs performance indicators

Castell OK et al., Current practices for describing the performance of molecularly imprinted polymers can be misleading and may be hampering the development of the field.
Journal of Molecular Recognition, 24, (6), 1115-1122, (2011)
   

Review - MIPs post functionalization

Book chapter, Takeuchi Tet al., Post-imprinting and In-Cavity Functionalization, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 95-106, (2015)
   

Review - MIPs prepared by gamma irrdiation

Akbulut-Söylemez M et al., Radiation induced synthesis of molecularly imprinted polymers.
Hacettepe Journal of Biology and Chemistry, 42, (1), 99-104, (2014)
   

Review - MIPs protein imprinting in patents

Mao XA et al., Recent Progress in Protein Imprinting Technology.
Recent Patents on Nanotechnology, 4, (2), 85-99, (2010)
   

Review - MIPs sensors

Book chapter, Piletsky Set al., A new generation of chemical sensors based on MIPs, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 64-79, (2006)
   

Review - MIPs sensors

Jin Y et al., Study on Sensors Based on Molecular Imprinting Polymers.
Chinese Polymer Bulletin, (6), 52-56, (2007)
   

Review - MIPs sensors and sensor arrays

Xu XH et al., Molecular imprinting in chemical sensors and sensor arrays.
Chemical Industry and Engineering Progress, 32, (12), 2901-2909, (2013)
   

Review - MIPs sensors for environmental and biotechological applications

Piletsky SA et al., Application of molecularly imprinted polymers in sensors for the environment and biotechnology.
Sensor Review, 21, (4), 292-296, (2001)
   

Review - MIPs silica overlayers

Book chapter, Katada Net al., Chemical vapour deposition of silica overlayer using an organic molecule as template surface: Application to molecular seiving sensor and adsorbent, 
In: Molecular imprinting of polymers, Piletsky S, Turner A (Eds.) Landes Bioscience: Georgetown, Texas, 41-49, (2006)
   

Review - MIPs sol-gels

Gupta R et al., Molecular imprinting in sol-gel matrix.
Biotechnology Advances, 26, (6), 533-547, (2008)
   

Review - MIPs (sol-gels) in sensors

Mujahid A et al., Chemical Sensors Based on Molecularly Imprinted Sol-Gel Materials.
Materials, 3, (4), 2196-2217, (2010)
   

Review - MIPs spheres

Zhang LY et al., Progress in Preparation and Application of Spherical Molecularly Imprinted Polymers.
Journal of Functional Polymers, 15, (2), 214-218, (2002)
   

Review - MIPs stimuli-responsive

Puoci F et al., Stimuli-responsive molecularly imprinted polymers for drug delivery: A review.
Current Drug Delivery, 5, (2), 85-96, (2008)
   

Review - MIPs, stimuli responsive

Chen W et al., Molecularly Imprinted Polymers with Stimuli-Responsive Affinity: Progress and Perspectives.
Polymers, 7, (9), 1689-1715, (2015)
   

Review - MIPs surface imprinted

Xu FF et al., Advance in surface molecularly imprinted carriers.
Chemical Industry and Engineering Progress, 30, (5), 1033-1038,1134, (2011)
   

Review - MIPs surface imprinted

Schirhagl R et al., Surface-imprinted polymers in microfluidic devices.
SCIENCE CHINA Chemistry, 55, (4), 469-483, (2012)
   

Review - MIPs surface imprinted with protein

Zhang XF et al., Protein surface-imprinting technology.
Progress In Chemistry, 28, (1), 149-162, (2016)
   

Review - MIPS surface imprinting

Book chapter, Cunliffe Det al., Surface imprinting, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 249-283, (2005)
   

Review - MIPs synthesis and applications

Lisichkin GV et al., Molecularly imprinted materials: Synthesis, properties, applications.
Russian Chemical Reviews, 75, (10), 901-918, (2006)
   

Review - MIPs - synthesis of

Book chapter, Moreno-Bondi MCet al., Preparation of Molecularly Imprinted Polymers, 
In: Handbook of Molecularly Imprinted Polymers, Alvarez-Lorenzo C, Concheiro A (Eds.) Smithers Rapra: 23-86, (2013)
   

Review - MIPs synthetic chemistry aspects

Book chapter, Huynh TPet al., Synthetic Chemistry for Molecular Imprinting, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 28-64, (2018)
   

Review - MIPs synthetic methods

Mayes AG et al., Synthetic strategies for the generation of molecularly imprinted organic polymers.
Advanced Drug Delivery Reviews, 57, (12), 1742-1778, (2005)
   

Review - MIPs targeting cell surface receptors

Pan JM et al., Molecularly imprinted polymers as receptor mimics for selective cell recognition.
Chemical Society Reviews, 47, (15), 5574-5587, (2018)
   

Review - MIPs temperature sensitive

Xia LW et al., Temperature-sensitive molecular imprinted polymers based on N-isopropylacrylamide.
Chemistry Bulletin, 70, (7), 489-493, (2007)
   

Review - MIPs temperature-sensitive hydrogels

Yang ZC et al., Temperature-sensitive molecularly imprinted hydrogels.
Chemical Industry and Engineering Progress, 33, (1), 117-123, (2014)
   

Review - MIPs the next generation

Si BJ et al., New-Generation of Molecular Imprinting Technique.
Progress In Chemistry, 21, (9), 1813-1819, (2009)
   

Review - MIPs theoretical and computational design

Book chapter, Nicholls IAet al., Theoretical and Computational Strategies in Molecularly Imprinted Polymer Development, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 197-226, (2018)
   

Review - MIPs thermosensitive

Du ZF et al., Technology and application progress of thermosensitive molecularly imprinted polymer.
Modern Chemical Industry, 35, (11), 27-31, (2015)
   

Review - MIPs using ligand-metal interactions

Book chapter, Iacob BCet al., Metal-Ligand Interactions in Molecular Imprinting, 
In: Ligand, Saravanan C (Ed.) InTech: Rijeka, 3-28, (2018)
   

Review - MIPs with aqueous compatiility

Book chapter, Zhang HQ, Water-compatible Molecularly Imprinted Polymers, 
In: Molecularly Imprinted Polymers for Analytical Chemistry Applications, Kutner W, Sharma PS (Eds.) Royal Society of Chemistry: 330-358, (2018)
   

Review - MIPs with controlled architecture

DiPasquale SA et al., Controlled architecture for improved macromolecular memory within polymer networks.
Current Opinion in Biotechnology, 40, 170-176, (2016)
   

review - MIPs with dual templates

Shen R et al., Progress in Application of Dual/Multi-Template Molecularly Imprinted Polymers.
Chinese Journal of Analytical Chemistry, 49, (10), e21205-e21215, (2021)
   

review - MIPs with dummy templates/epitopes

Wang YX et al., Recent advances in applications of fragment/dummy molecularly imprinted polymers.
Chinese Journal of Chromatography, 39, (2), 134-141, (2021)
   

Review - MIPs with fluorescent detection

Wan W et al., Fluorescent monomers: "bricks" that make a molecularly imprinted polymer "bright".
Analytical and Bioanalytical Chemistry, 408, (7), 1753-1771, (2016)
   

review - MIPs with ionic liquids

Ding SC et al., Integrating ionic liquids with molecular imprinting technology for biorecognition and biosensing: A review.
Biosensors and Bioelectronics, 149, Article111830-(2020)
   

Review - MIPs with ionic liquids as porogens

Book chapter, Booker Ket al., Ionic Liquids as Porogens in the Synthesis of Molecularly Imprinted Polymers, 
In: Applications of Ionic Liquids in Science and Technology, Handy S (Ed.) InTech: 197-212, (2011)
   

Review - MIPs with ion templates

Branger C et al., Recent advances on ion-imprinted polymers.
Reactive and Functional Polymers, 73, (6), 859-875, (2013)
   

Review - MIPs with metal coodinative bonds

Hu YL, The Application of Metal-Coordinative Bonds in Molecular Imprinting Technique.
Guangdong Chemical Industry, 35, (12), 61-64,119, (2008)
   

Review - MIPs with metal coordinate binding

Huang JX et al., Application Development of Complex Imprinted Polymer in Analytical Chemistry.
Chinese Journal of Analytical Chemistry, 40, (4), 643-650, (2012)
   

Review - MIPs with metal coordination

Book chapter, Conrad PGIet al., The use of metal coordination for controlling the microenvironment of imprinted polymers, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 123-180, (2005)
   

Review - MIPs with mixed templates

Proceeding, Xu ZG et al, Mixed-Template Molecularly Imprinted Technique and its Application Research, 
In: Advanced Materials Research, Tan HH (Ed.), 99-105, (2013)
   

Review - MIPs with multiple functionalities

Ye L, Molecularly imprinted polymers with multi-functionality.
Analytical and Bioanalytical Chemistry, 408, (7), 1727-1733, (2016)
   

review - MIPs with multiple templates

Li S et al., Multi-template molecularly imprinted solid phase extraction and its application in the extraction and separation of multi-components from traditional Chinese medicine.
Acta Pharmaceutica Sinica, 56, (3), 751-760, (2021)
   

Review - MIPs with novel functional monomers

Yuan QH et al., Progress on molecularly imprinted polymers with novel functional monomers.
Chemistry Bulletin, 72, (8), 707-712, (2009)
   

Review - MIPs with photoresponsive properties

Wei YB et al., Review of the recent progress in photoresponsive molecularly imprinted polymers containing azobenzene chromophores.
Analytica Chimica Acta, 900, 10-20, (2015)
   

review - MIPs with post-imprinting modifications

Sunayama H et al., Multi-Functional Nanocavities Fabricated Using Molecular Imprinting and Post-Imprinting Modifications for Efficient Biomarker Detection.
Chromatography, 42, (2), 73-81, (2021)
   

review - MIPs with quantum dots

Ma JX et al., Application of novel quantum dot-based molecularly imprinted fluorescence sensor in rapid detection.
Chinese Journal of Chromatography, 39, (8), 775-780, (2021)
   

Review - MIPs with surface imprints

Sharma PS et al., Surface development of molecularly imprinted polymer films to enhance sensing signals.
TrAC Trends in Analytical Chemistry, 51, 146-157, (2013)
   

review - MIPs with surface imprints

Dong CY et al., Molecularly imprinted polymers by the surface imprinting technique.
European Polymer Journal, 145, Article110231-(2021)
   

Review - MIPs xerogels in sensing

Holthoff EL et al., Molecularly Imprinted Xerogels as Platforms for Sensing.
Accounts of Chemical Research, 40, (9), 756-767, (2007)
   

Review - MIP synthesis

Rimmer S, Synthesis of molecular imprinted polymer networks.
Chromatographia, 47, (7-8), 470-474, (1998)
   

Review - MIP synthesis

Book chapter, Ye L, Synthetic Strategies in Molecular Imprinting, 
In: Molecularly Imprinted Polymers in Biotechnology, Mattiasson B, Ye L (Eds.) Springer: Berlin,Heidelberg, 1-24, (2015)
   

review - MIP thin-film electrochemical sensors

Book chapter, Granado VLVet al., Molecularly Imprinted Polymer Thin-Film Electrochemical Sensors, 
In: Biomimetic Sensing: Methods and Protocols, Fitzgerald JE, Fenniri H (Eds.) Springer New York: New York, NY, 151-161, (2019)
   

Review - MI-SPE

Yang M et al., Development of Molecular Imprinted Solid Phase Extraction on the Detection for Trace Amounts of Analytes.
Materials Review, 26, (7), 69-73 (final page number not verified), (2012)
   

Review - MISPE in food analysis

Hu J et al., Molecularly imprinted solid phase extraction technique and the application in food contaminants analysis.
China Condiment, (6), 95-102, (2012)
   

Review - modelling adsorption processes

Alberti G et al., Beyond the synthesis of novel solid phases: Review on modelling of sorption phenomena.
Coordination Chemistry Reviews, 256, (1-2), 28-45, (2012)
   

Review - modelling the separation of enantiomers

Szabelski P et al., Phenomenological Modeling of Separation of Enantiomers by Nonlinear Chromatography.
Acta Chromatographica, 20, (4), 513-547, (2008)
   

Review - modification of PES membranes

Zhao CS et al., Modification of polyethersulfone membranes - A review of methods.
Progress in Materials Science, 58, (1), 76-150, (2013)
   

review - MOF and MIPs

Book chapter, Rocío-Bautista Pet al., Solid-Phase Microextraction Coatings Based on Tailored Materials: Metal–Organic Frameworks and Molecularly Imprinted Polymers, 
In: Advanced Coating Materials, Li L, Yang Q (Eds.) Scrivener Publishing: Beverly, 317-347, (2019)
   

Review - molecular recognition

Ariga K et al., Molecular recognition: from solution science to nano/materials technology.
Chemical Society Reviews, 41, (17), 5800-5835, (2012)
   

Review - molecular recognition and catalysis

Karakhanov EA et al., Molecular recognition and catalysis: from macrocyclic receptors to molecularly imprinted metal complexes.
Macromolecular Symposia, 235, (1), 39-51, (2006)
   

Review - molecular recognition in agriculture

Mastronardi E et al., Personalized Medicine for Crops? Opportunities for the Application of Molecular Recognition in Agriculture.
Journal of Agricultural and Food Chemistry, 66, (26), 6457-6461, (2018)
   

Review - molecular recognition in membranes

Book chapter, Donato Let al., Molecular recognition-driven membrane processes, 
In: Smart Membranes and Sensors: Synthesis, Characterization, and Applications, Gugliuzza A (Ed.) John Wiley & Sons: 269-300, (2014)
   

Review - molecular recognition of caffeine

Sahoo P, Molecular recognition of caffeine in solution and solid state.
Bioorganic Chemistry, 58, 26-47, (2015)
   

Review - molecular recognition of mycotoxins

Book chapter, Baggiani Cet al., Artificial Systems for Molecular Recognition of Mycotoxins, 
In: Mycotoxins in Food, Feed and Bioweapons, Rai M, Varma A (Eds.) Springer: Berlin, Heidelberg, 3-20, (2010)
   

Review - molecular recognition with coordinative bonds

Kruppa M et al., Reversible Coordinative Bonds in Molecular Recognition.
Chemical Reviews, 106, (9), 3520-3560, (2006)
   

Review - monitoring of organophosphate pesticide residues

Zhang HT et al., Food safety: Monitoring of organophosphate pesticide residues in crops and food.
Phosphorus Sulfur And Silicon And The Related Elements, 183, (2-3), 280-290, (2008)
   

Review - monolithic affinity chromatographic media

Sproß J et al., Monolithic media for applications in affinity chromatography.
Journal of Separation Science, 34, (16-17), 1958-1973, (2011)
   

Review - monolithic chiral CE phases

Qin F et al., Monolithic enantiomer-selective stationary phases for capillary electrochromatography.
Journal of Separation Science, 29, (10), 1332-1343, (2006)
   

Review - monolithic chiral stationary phases

Al-Othman ZA et al., Advances in enantiomeric resolution on monolithic chiral stationary phases in liquid chromatography and electrochromatography.
Journal of Separation Science, 37, (9-10), 1033-1057, (2014)
   

Review - monolithic columns for residue analysis in food

Díaz-Bao M et al., Recent Advances and Uses of Monolithic Columns for the Analysis of Residues and Contaminants in Food.
Chromatography, 2, (1), 79-95, (2015)
   

Review - monolithic columns in HPLC

Guiochon G, Monolithic columns in high-performance liquid chromatography.
Journal of Chromatography A, 1168, (1-2), 101-168, (2007)
   

Review - monolithic matrices for microcolumns

Zhu GJ et al., Recent development of monolithic materials as matrices in microcolumn separation systems.
Journal of Separation Science, 30, (6), 792-803, (2007)
   

Review - monolithic SPE materials

Nema T et al., Applications of monolithic materials for sample preparation.
Journal of Pharmaceutical and Biomedical Analysis, 87, 130-141, (2014)
   

Review - monolithic stationary phases

Klodzinska E et al., Monolithic continuous beds as a new generation of stationary phase for chromatographic and electro-driven separations.
Journal of Chromatography A, 1109, (1), 51-59, (2006)
   

Review - monolithic stationary phases

Yang GL et al., Application of Monolithic Stationary Phases in Solid-Phase Extraction and Pharmaceutical Analysis.
Current Pharmaceutical Analysis, 6, (3), 213-224, (2010)
   

Review - monolithic stationary phases

Zhu T et al., Monolithic materials and their applications in HPLC for purification and analysis of bioactive compounds from natural plants: a review.
Instrumentation Science & Technology, 40, (2-3), 78-89, (2012)
   

Review - multichannel QCM

Tuantranont A et al., A review of monolithic multichannel quartz crystal microbalance: A review.
Analytica Chimica Acta, 687, (2), 114-128, (2011)
   

Review - multilayer films

Zhang X, Surface molecular engineering of polymer multilayer films.
Acta Polymerica Sinica, (10), 905-912, (2007)
   

Review - mycotoxin analysis

Krska R et al., Advances in the analysis of mycotoxins and its quality assurance.
Food Additives and Contaminants, 22, (4), 345-353, (2005)
   

Review - mycotoxin analysis

Book chapter, Krska Ret al., Mycotoxin analysis: An overview of classical, rapid and emerging techniques, 
In: Mycotoxin Factbook: Food & Feed Topics, Barug D, Bhatnagar D, van Egmond HP, van der Kamp JW, van Osenbruggen WA, Visconti A (Eds.) Wageningen Academic Publishers: Wageningen, 225-247, (2006)
   

Review - mycotoxin analysis

Maragos CM, Recent advances in the development of novel materials for mycotoxin analysis.
Analytical and Bioanalytical Chemistry, 395, (5), 1205-1213, (2009)
   

review - mycotoxin detection

Chauhan R et al., Recent advances in mycotoxins detection.
Biosensors and Bioelectronics, 81, 532-545, (2016)
   

Review - Mycotoxins analysis

Lattanzio VMT et al., Current analytical methods for trichothecene mycotoxins in cereals.
TrAC Trends in Analytical Chemistry, 28, (6), 758-768, (2009)
   

Review - mycotxin analysis

Cigic IK et al., An Overview of Conventional and Emerging Analytical Methods for the Determination of Mycotoxins.
International Journal of Molecular Sciences, 10, (1), 62-115, (2009)
   

review - nanMIPs in medicine

Zhang HQ, Molecularly Imprinted Nanoparticles for Biomedical Applications.
Advanced Materials, 32, (3), Article1806328-(2020)
   

Review - nanoadsorbents for pollutants

Kyzas GZ et al., Nanoadsorbents for pollutants removal: A review.
Journal of Molecular Liquids, 203, 159-168, (2015)
   

Review - nanogels

Book chapter, Ghosal Aet al., Design and Engineering of Nanogels, 
In: Nanogels for Biomedical Applications, Vashist A, Kaushik AK, Ahmad S, Nair M (Eds.) RSC: 9-28, (2018)
   

Review - nano-LC

Rocco A et al., Enantiomeric separations by means of nano-LC.
Journal of Separation Science, 36, (3), 421-444, (2013)
   

Review - nanomaterials and personalised medicine

Koutsopoulos S, Molecular fabrications of smart nanobiomaterials and applications in personalized medicine.
Advanced Drug Delivery Reviews, 64, (13), 1459-1476, (2012)
   

Review - Nanomaterials for elemental speciation

Karadjova I et al., Nanomaterials for elemental speciation.
Journal of Analytical Atomic Spectrometry, 31, (10), 1949-1973, (2016)
   

Review - nanomaterials for enantiomeric resolution

Wang HS et al., Emerging enantiomeric resolution materials with homochiral nano-fabrications.
Nanoscale, 7, (28), 11815-11832, (2015)
   

Review - nanomaterials for sample preparation

Xu LN et al., Recent advances in applications of nanomaterials for sample preparation.
Talanta, 146, 714-726, (2016)
   

Review - nanomaterials in detection of food contaminants

Liu JM et al., Emerging functional nanomaterials for the detection of food contaminants.
Trends In Food Science & Technology, 71, 94-106, (2018)
   

Review - nanomaterials in enantioseparation

Chang CL et al., Applications of nanomaterials in enantioseparation and related techniques.
TrAC Trends in Analytical Chemistry, 39, 195-206, (2012)
   

Review - nanomaterials in sample preparation

Ahmadi M et al., Nanomaterials as sorbents for sample preparation in bioanalysis: A review.
Analytica Chimica Acta, 958, 1-21, (2017)
   

Review - nanomaterials in sensor applications

Zamora-Gálvez A et al., Nanomaterials connected to antibodies and molecularly imprinted polymers as bio/receptors for bio/sensor applications.
Applied Materials Today, 9, 387-401, (2017)
   

Review - nanomaterilas in CE

Wang YQ et al., Use of nanomaterials in capillary and microchip electrophoresis.
Expert Review of Proteomics, 4, (2), 287-298, (2007)
   

Review - nanomedicine

Joshi G, Nanomedicine "A Future Medicine".
Journal of Today’s Biological Sciences : Research & Review, 1, (1), 179-185, (2012)
   

Review - nanomedicine

Joshi M et al., Nanomedicine to improve drug delivery outcomes.
Chronicles of Young Scientists, 3, (4), 258-268, (2012)
   

Review - nanomedicine

Culver HR et al., Intelligent recognitive systems in nanomedicine.
Current Opinion in Chemical Engineering, 4, 105-113, (2014)
   

Review - nanoMIPs in pharmaceutical analysis

Li J et al., Research and Application of Nanostructured Molecularly Imprinted Polymers in Pharmaceutical Analysis.
Chinese Journal of Analytical Chemistry, 40, (9), 1461-1468, (2012)
   

Review - nanoparticle detoxification

Graham LM et al., Nanodetoxification: emerging role of nanomaterials in drug intoxication treatment.
Nanomedicine, 6, (5), 921-928, (2011)
   

Review - nanoparticle pseudostationary phases in CEC

Nilsson C et al., Nanoparticle-based pseudostationary phases in capillary electrochromatography.
Electrophoresis, 27, (1), 76-83, (2006)
   

Review - nanoparticles for optical sensing

Canfarotta F et al., Polymeric nanoparticles for optical sensing.
Biotechnology Advances, 31, (8), 1585-1599, (2013)
   

Review - nanoparticles in biomedical applications

Book chapter, Maximilien Jet al., Nanoparticles in Biomedical Applications, 
In: Measuring Biological Impacts of Nanomaterials, Wegener J (Ed.) Springer International Publishing: Cham, 177-210, (2016)
   

Review - nanoparticles in biosensors

Warriner K et al., Developments in nanoparticles for use in biosensors to assess food safety and quality.
Trends In Food Science & Technology, 40, (2), 183-199, (2014)
   

Review - nanoparticles in CEC

Nilsson C et al., Use of nanoparticles in capillary and microchip electrochromatography.
Journal of Chromatography A, 1168, (1-2), 212-224, (2007)
   

Review - nanoparticles in elemental speciation

Liu CT et al., Applications of Nanoparticles in Elemental Speciation.
Analytical Letters, 48, (7), 1031-1043, (2015)
   

Review - nanoparticles in microextraction

Book chapter, Ríos-Gómez Jet al., Selective Nanoparticles in Microextraction, 
In: Encyclopedia of Analytical Chemistry, Wiley: (2016)
   

Review - nanoparticles in sample preparation

Lucena R et al., Potential of nanoparticles in sample preparation.
Journal of Chromatography A, 1218, (4), 620-637, (2011)
   

Review - nanoparticles in separation science

Guihen E et al., Nanoparticles in separation science - Recent developments.
Analytical Letters, 36, (15), 3309-3336, (2003)
   

Review - nanoporous materials

Polarz S et al., Nanoporous materials.
Journal of Nanoscience and Nanotechnology, 2, (6), 581-612, (2002)
   

Review - nanoporous materials

Cheung MC et al., Porous nanostructured encapsulation and immobilization materials for optical biosensors.
IEEE Journal on Selected Topics in Quantum Electronics, 18, (3), 1147-1159, (2012)
   

Review - nanosensors

El Idrissi M et al., Nanosensors based on polymer vesicles and planar membranes: a short review.
Journal of Nanobiotechnology, 16, (1), ArticleNo63-(2018)
   

Review - nanosensors using plastic antibodies

Volkert AA et al., Advancements in nanosensors using plastic antibodies.
Analyst, 139, (1), 21-31, (2014)
   

Review - nanoSPE of trace elements

Hu B et al., Nanometer-sized materials for solid-phase extraction of trace elements.
Analytical and Bioanalytical Chemistry, 407, (10), 2685-2710, (2015)
   

Review - nanostructured catalysts

Shiju NR et al., Recent developments in catalysis using nanostructured materials.
Applied Catalysis A: General, 356, (1), 1-17, (2009)
   

Review - nanostructured electrochemical sensors for mycotoxin detection

Goud KY et al., Progress on nanostructured electrochemical sensors and their recognition elements for detection of mycotoxins: A review.
Biosensors and Bioelectronics, 121, 205-222, (2018)
   

Review - nanotechnology-based sensors for pathogens

Mustafa F et al., Multifunctional Nanotechnology-Enabled Sensors for Rapid Capture and Detection of Pathogens.
Sensors, 17, (9), ArticleNo2121-(2017)
   

Review - nanotechnology in glycomics

Dosekova E et al., Nanotechnology in Glycomics: Applications in Diagnostics, Therapy, Imaging, and Separation Processes.
Medicinal Research Reviews, 37, (3), 514-626, (2017)
   

Review - Nanotechnology in waste water treatment

Prachi et al., Nanotechnology in Waste Water Treatment: A Review.
International Journal of ChemTech Research, 5, (5), 2303-2308, (2013)
   

Review - natural product drug discovery

Potterat O et al., Natural products in drug discovery - Concepts and approaches for tracking bioactivity.
Current Organic Chemistry, 10, (8), 899-920, (2006)
   

Review - New materials in sample preparation

Nazario CED et al., New materials for sample preparation techniques in bioanalysis.
Journal of Chromatography B, 1043, 81-95, (2017)
   

Review - new media for solid-phase extraction

Plotka-Wasylka J et al., Modern trends in solid phase extraction: New sorbent media.
TrAC Trends in Analytical Chemistry, 77, 23-43, (2016)
   

Review - New Sample Preparation Techniques

Costa R, Newly Introduced Sample Preparation Techniques: Towards Miniaturization.
Critical Reviews in Analytical Chemistry, 44, (4), 299-310, (2014)
   

Review - new solid adsorbents

Majors RE, Novel Sorbents for Solid-Liquid Extraction.
Lc Gc North America, 31, (12), 984-991, (2013)
   

Review - new sorbents for extraction

Augusto F et al., New sorbents for extraction and microextraction techniques.
Journal of Chromatography A, 1217, (16), 2533-2542, (2010)
   

Review - nucleation and crystallisation of proteins

Zhou RB et al., A review on recent advances for nucleants and nucleation in protein crystallization.
CrystEngComm, 19, (8), 1143-1155, (2017)
   

Review - Ochratoxin A detection

Meulenberg EP, Immunochemical Methods for Ochratoxin A Detection: A Review.
Toxins, 4, (4), 244-266, (2012)
   

Review - ocular delivery of antifungal agents

Phan CM et al., Contact lenses for antifungal ocular drug delivery: a review.
Expert Opinion on Drug Delivery, 11, (4), 537-546, (2014)
   

Review - online preconcentration in CE analysis of agricultural chemicals

Fang R et al., On-line preconcentration in capillary electrophoresis for analysis of agrochemical residues.
Journal of Liquid Chromatography & Related Technologies, 37, (10), 1465-1497, (2014)
   

Review - online sampling in biopharmaceutical analysis

Peng J et al., New techniques of on-line biological sample processing and their application in the field of biopharmaceutical analysis.
Acta Pharmaceutica Sinica B, 6, (6), 540-551, (2016)
   

Review - online SPE

Pyrzynska K et al., On-line coupling of solid phase extraction sample processing with high-performance liquid chromatography.
Critical Reviews in Analytical Chemistry, 32, (3), 227-243, (2002)
   

Review - online SPE in LC analysis

Oliferova LA et al., On-line coupling of sorption preconcentration to liquid-chromatographic methods of analysis.
Journal of Analytical Chemistry, 61, (5), 416-441, (2006)
   

Review - online SPE-LC

Rogeberg M et al., On-line solid phase extraction-liquid chromatography, with emphasis on modern bioanalysis and miniaturized systems.
Journal of Pharmaceutical and Biomedical Analysis, 87, 120-129, (2014)
   

Review - online SPE of pesticides

Lucci P et al., On-line solid-phase extraction for liquid chromatography-mass spectrometry analysis of pesticides.
Journal of Separation Science, 37, (20), 2929-2939, (2014)
   

Review - open tubular capillary chromatography

Cheong WJ et al., Comprehensive overview of recent preparation and application trends of various open tubular capillary columns in separation science.
Journal of Chromatography A, 1308, 1-24, (2013)
   

Review - opthalmic drug delivery

Barbu E et al., Polymeric materials for ophthalmic drug delivery: trends and perspectives.
Journal of Materials Chemistry, 16, (34), 3439-3443, (2006)
   

review - optical biosensors

Peltomaa R et al., Optical Biosensors for Label-Free Detection of Small Molecules.
Sensors, 18, (12), (2018)
   

Review - optical chemosensors

Martin MA et al., Trends in the design and application of optical chemosensors in pharmaceutical and biomedical analysis.
Current Pharmaceutical Analysis, 4, (3), 106-117, (2008)
   

Review - optical detection by covalent modification

Mohr GJ, Covalent bond formation as an analytical tool to optically detect neutral and anionic analytes.
Sensors and Actuators B: Chemical, 107, (1), 2-13, (2005)
   

Review - optical detection of paralytic shellfish poisoning toxins

Campbell K et al., Paralytic shellfish poisoning (PSP) toxin binders for optical biosensor technology: problems and possibilities for the future: a review.
Food Additives & Contaminants: Part A: Chemistry, Analysis, Control, Exposure & Risk Assessment, 28, (6), 711-725, (2011)
   

Review - Optical measurements in flow

Rocha FRP et al., Direct Solid-Phase Optical Measurements in Flow Systems: A Review.
Analytical Letters, 44, (1), 528-559, (2011)
   

Review - optical sensing

Book chapter, Kasper Met al., Optical Sensing of Enantiomers, 
In: Frontiers in Chemical Sensors, Orellana G, Moreno-Bondi MC (Eds.) Springer: Berlin, 323-341, (2005)
   

Review - optical sensing of pesticides

Yan X et al., Review of optical sensors for pesticides.
TrAC Trends in Analytical Chemistry, 103, 1-20, (2018)
   

Review - optical sensors

Gauglitz G, Direct optical sensors: principles and selected applications.
Analytical and Bioanalytical Chemistry, 381, (1), 141-155, (2005)
   

Review - optical sensors

Book chapter, Fink JK, Optical Sensors, 
In: Polymeric Sensors and Actuators, John Wiley & Sons, Inc.: 139-224, (2012)
   

Review - optical sensors and hybrid sol-gel nanoreactors

Tran-Thi TH et al., Optical chemical sensors based on hybrid organic-inorganic sol-gel nanoreactors.
Chemical Society Reviews, 40, (2), 621-639, (2011)
   

Review - oral drug delivery

Fox CB et al., Micro/nanofabricated platforms for oral drug delivery.
Journal of Controlled Release, 219, 431-444, (2015)
   

Review - oral drug delivery systems

Tiwari S et al., Oral Drug Delivery System: A Review.
American Journal of Life Science Researches, 2, (1), 27-35, (2014)
   

Review - organic-inorganic hybrid materials

Martínez-Máñez R et al., Mimicking tricks from nature with sensory organic-inorganic hybrid materials.
Journal of Materials Chemistry, 21, (34), 12588-12604, (2011)
   

Review - organocatalysis

Dalko PI, Do We Need Asymmetric Organocatalysis?
Chimia, 61, (5), 213-218, (2007)
   

Review - oriented proteins in sensing

Liu YS et al., Oriented immobilization of proteins on solid supports for use in biosensors and biochips: a review.
Microchimica Acta, 183, (1), 1-19, (2016)
   

Review - paracetamol determination

Espinosa-Bosch M et al., Determination of paracetamol: Historical evolution.
Journal of Pharmaceutical and Biomedical Analysis, 42, (3), 291-321, (2006)
   

Review - peptides as molecular receptors

Book chapter, Tothill IE, Peptides as Molecular Receptors, 
In: Recognition Receptors in Biosensors, Zourob M (Ed.) Springer: 249-274, (2010)
   

Review - perfect reactors

Özkan L et al., Towards Perfect Reactors: Gaining full control of chemical transformations at molecular level.
Chemical Engineering and Processing: Process Intensification, 51, (1), 109-116, (2012)
   

Review - permselective membranes

Aoki T et al., New macromolecular architectures for permselective membranes - Gas permselective membranes from dendrimers and enantioselectively permeable membranes from one-handed helical polymers.
Polymer Journal, 37, (10), 717-735, (2005)
   

Review - pesticide analysis of cereal products

González-Curbelo MÁ et al., Sample-preparation methods for pesticide-residue analysis in cereals and derivatives.
TrAC Trends in Analytical Chemistry, 38, 32-51, (2012)
   

Review - pesticide biosensors

Liu SQ et al., Advances in pesticide biosensors: current status, challenges, and future perspectives.
Analytical and Bioanalytical Chemistry, 405, (1), 63-90, (2013)
   

Review - pesticide immunoassay

Book chapter, Fan MTet al., Pesticide immunoassay, 
In: Pesticides - Strategies for Pesticides Analysis, Stoytcheva M (Ed.) InTech: Rikeka, Croatia, 293-314, (2011)
   

Review - photoactive nanomaterials

Sortino S, Photoactivated nanomaterials for biomedical release applications.
Journal of Materials Chemistry, 22, (2), 301-318, (2012)
   

Review - photo-initiated modification of membranes

He DM et al., Photo-irradiation for preparation, modification and stimulation of polymeric membranes.
Progress in Polymer Science, 34, (1), 62-98, (2009)
   

Review - photoresponsive dendrimers baased on azobenzene

Deloncle R et al., Stimuli-responsive dendritic structures: The case of light-driven azobenzene-containing dendrimers and dendrons.
Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 11, (1), 25-45, (2010)
   

Review - photoresponsive hydrogels

Tomatsu I et al., Photoresponsive hydrogels for biomedical applications.
Advanced Drug Delivery Reviews, 63, (14-15), 1257-1266, (2011)
   

Review - photoswitching azobenzene-based polymers

Goulet-Hanssens A et al., Photo-control of biological systems with azobenzene polymers.
Journal of Polymer Science Part A: Polymer Chemistry, 51, (14), 3058-3070, (2013)
   

Review - piezoelectric sensors

Book chapter, Fink JK, Piezoelectric Sensors, 
In: Polymeric Sensors and Actuators, Wiley: Somerset, NJ, USA, 317-329, (2012)
   

Review - piezoelectric sensors

Pohanka M, Overview of Piezoelectric Biosensors, Immunosensors and DNA Sensors and Their Applications.
Materials, 11, (3), ArticleNo448-(2018)
   

Review - piezoelectric sensors for pesticides

Marrazza G, Piezoelectric Biosensors for Organophosphate and Carbamate Pesticides: A Review.
Biosensors, 4, (3), 310-317, (2014)
   

Review - plant pathogen detection

Skottrup PD et al., Towards on-site pathogen detection using antibody-based sensors.
Biosensors and Bioelectronics, 24, (3), 339-348, (2008)
   

Review - plasma fractionation

Denizli A, Plasma fractionation: conventional and chromatographic methods for albumin purification.
Hacettepe Journal of Biology and Chemistry, 39, (4), 315-341, (2011)
   

Review - plasmonics and templated systems

Tiu BDB et al., Plasmonics and templated systems for bioapplications.
Rendiconti Lincei, 26, (2 Supplement), 143-160, (2015)
   

review - polydopamine

Palladino P et al., Polydopamine: surface coating, molecular imprinting, and electrochemistry - successful applications and future perspectives in (bio)analysis.
Analytical and Bioanalytical Chemistry, 411, (19), 4327-4338, (2019)
   

Review - polymer antidotes

Weisman A et al., Polymer antidotes for toxin sequestration.
Advanced Drug Delivery Reviews, 90, 81-100, (2015)
   

Review - polymer-graphene composites in electrochemical sensing

Sobolewski P et al., Polymer-Graphene Nanocomposite Materials for Electrochemical Biosensing.
Macromolecular Bioscience, 16, (7), 944-957, (2016)
   

Review - polymeric bile acid sequestrants

Mendonça PV et al., Polymeric bile acid sequestrants - Synthesis using conventional methods and new approaches based on ’’controlled’’/living radical polymerization.
Progress in Polymer Science, 38, (3-4), 445-461, (2013)
   

Review - polymeric bile acid sequestrants

Hermánková E et al., Polymeric bile acid sequestrants: Review of design, in vitro binding activities, and hypocholesterolemic effects.
European Journal of Medicinal Chemistry, 144, 300-317, (2018)
   

Review - polymeric catalysts

Dioos BML et al., Aspects of Immobilisation of Catalysts on Polymeric Supports.
Advanced Synthesis & Catalysis, 348, (12-13), 1413-1446, (2006)
   

Review - polymeric materials in solid phase extraction

Plotka-Wasylka J et al., New Polymeric Materials for Solid Phase Extraction.
Critical Reviews in Analytical Chemistry, 47, (5), 373-383, (2017)
   

Review - polymeric membrane surface modification

Khulbe KC et al., The art of surface modification of synthetic polymeric membranes.
Journal of Applied Polymer Science, 115, (2), 855-895, (2010)
   

Review - Polymeric reagent for lanthanides

Yang YJ et al., Affinity of Polymer-Supported Reagents for Lanthanides as a Function of Donor Atom Polarizability.
Industrial & Engineering Chemistry Research, 48, (13), 6173-6187, (2009)
   

Review - polymeric stationary phases

Book chapter, Palmer CP, Polymeric Pseudostationary Phases and Dendrimers, 
In: Electrokinetic Chromatography, Pyell U (Ed.) Wiley: 137-151, (2006)
   

Review - polymer in electrochemical sensors

Welch M et al., Polymer brushes for electrochemical biosensors.
Soft Matter, 7, (2), 297-302, (2011)
   

Review - Polymer in separations

Khodakarami M et al., High-Performance Polymers for Separation and Purification Processes: An Overview.
Polymer-Plastics Technology and Engineering, 56, (18), 2019-2042, (2017)
   

Review - polymers for capturing microorganisms

Pasparakis G et al., Synthetic polymers for capture and detection of microorganisms.
Analyst, 132, (11), 1075-1082, (2007)
   

Review - polymers in biosensors

Book chapter, Davis Fet al., Polymers in biosensors, 
In: Biomedical Polymers, Jenkins M (Ed.) Woodhead Publishing Ltd.: Cambridge, UK, 174-196, (2007)
   

Review - polymers in biosensors

Book chapter, Tjong Vet al., Stimulus-Responsive Polymers as Intelligent Coatings for Biosensors: Architectures, Response Mechanisms, and Applications, 
In: Intelligent Surfaces in Biotechnology, Grandin HM, Textor M (Eds.) John Wiley & Sons, Inc.: Hoboken, 1-30, (2012)
   

Review - polymers in combinatorial chemistry

Book chapter, Wietor JLet al., Polymers Formed by Dynamic Combinatorial Chemistry, 
In: Dynamic Combinatorial Chemistry, Reek JNH, Otto S (Eds.) Wiley-VCH: Weinheim, Germany, 151-168, (2010)
   

Review - polymers in drug delivery

Book chapter, Alvarez-Lorenzo Cet al., Modular biomimetic drug delivery systems, 
In: Polymeric Materials, Medicinal and Pharmaceutical Applications, Dumitriu S, Popa V (Eds.) CRC Press: Boca Raton, 85-122, (2013)
   

Review - polymers in luminescent sensing

Kim H et al., Polymers for Luminescent Sensing Applications.
Macromolecular Chemistry And Physics, 215, (13), 1274-1285, (2014)
   

Review - polymer-supported catalysts

Dell’Anna MM et al., Polymer Supported Catalysts Obtained from Metal-Containing Monomers.
Current Organic Chemistry, 17, (12), 1236-1273, (2013)
   

Review - polymethacrylates

Holmes PF et al., Exploration of polymethacrylate structure-property correlations: Advances towards combinatorial and high-throughput methods for biomaterials discovery.
Progress in Polymer Science, 33, (8), 787-796, (2008)
   

Review - polythiophenes in sensors

Huynh TP et al., Functionalized polythiophenes: Recognition materials for chemosensors and biosensors of superior sensitivity, selectivity, and detectability.
Progress in Polymer Science, 47, 1-25, (2015)
   

Review - porous materials from deep eutectic solvents

Li XX et al., Preparation and Application of Porous Materials based on Deep Eutectic Solvents.
Critical Reviews in Analytical Chemistry, 48, (1), 73-85, (2018)
   

Review - porous polymers

Berro S et al., From Plastic to Silicone: The Novelties in Porous Polymer Fabrications.
Journal of Nanomaterials, ArticleID142195-(2015)
   

Review - porous polymers in environmental analytical chmeistry

Gros P et al., Chemical structure, synthesis, and physical and chemical properties of porous polymers as materials applied in analytical chemistry and environmental protection.
Environmental Protection and Natural Resources, 27, (4), 32-36, (2016)
   

Review - potentiometric sensors

Book chapter, Banica FG, Potentiometric Sensors, 
In: Chemical Sensors and Biosensors, John Wiley & Sons, Ltd: 165-216, (2012)
   

Review - preconcentration of uranium and thorium

Rao TP et al., Preconcentration techniques for uranium(VI) and thorium(IV) prior to analytical determination--an overview.
Talanta, 68, (4), 1047-1064, (2006)
   

Review - preparation of particles by membrane emulsification

Vladisavljevic GT, Structured microparticles with tailored properties produced by membrane emulsification.
Advances in Colloid and Interface Science, 225, 53-87, (2015)
   

Review - protein assemblies

van Rijn P, Polymer Directed Protein Assemblies.
Polymers, 5, (2), 576-599, (2013)
   

Review - protein biosensors

Luo XL et al., Electrical biosensors and the label free detection of protein disease biomarkers.
Chemical Society Reviews, 42, (13), 5944-5962, (2013)
   

Review - protein imprinting

Pei CY et al., Progress in the study on proteins imprinted technique.
Journal of Zhoukou Normal University, 23, (5), 77-81, (2006)
   

Review - protein monoliths for chiral separation

Zheng Y et al., Monoliths with proteins as chiral selectors for enantiomer separation.
Talanta, 91, (1), 7-17, (2012)
   

Review - proteins in chiral separations

Proceeding, Zheng Y et al, Monoliths with Proteins as Chiral Selectors for Enatiomer Separation, 
Ao SI, Douglas C, Grundfest WS, Burgstone J (Eds.), 679-684, (2011)
   

Review - Prussian blue in sensing applications

Kong B et al., New faces of porous Prussian blue: interfacial assembly of integrated hetero-structures for sensing applications.
Chemical Society Reviews, 44, (22), 7997-8018, (2015)
   

Review - QCM sensor literature survey

Speight RE et al., A Survey of the 2010 Quartz Crystal Microbalance Literature.
Journal of Molecular Recognition, 25, (9), 451-473, (2012)
   

Review - QCM sensors

Vashist SK et al., Recent Advances in Quartz Crystal Microbalance-Based Sensors.
Journal of Sensors, Article ID 571405-(2011)
   

Review - QCM sensors for virus detection

Afzal A et al., Gravimetric Viral Diagnostics: QCM Based Biosensors for Early Detection of Viruses.
Chemosensors, 5, (1), ArticleNo7-(2017)
   

Review - quantification methods for C-reactive protein

Algarra M et al., Current analytical strategies for C-reactive protein quantification in blood.
Clinica Chimica Acta, 415, 1-9, (2013)
   

Review - quantum dots in metal ion sensing

Lou YB et al., Metal ions optical sensing by semiconductor quantum dots.
Journal of Materials Chemistry C, 2, (4), 595-613, (2014)
   

Review - quantum dots in proteomics

Wu HF et al., Quantum dot applications endowing novelty to analytical proteomics.
Proteomics, 12, (19-20), 2949-2961, (2012)
   

Review - quantum dots in sensing

Wu P et al., Doped quantum dots for chemo/biosensing and bioimaging.
Chemical Society Reviews, 42, (12), 5489-5521, (2013)
   

Review - quantum dots in sensing biomolecules

Miao YM et al., Construction of biomolecular sensors based on quantum dots.
RSC Advances, 6, (110), 109009-109022, (2016)
   

Review - RAM-MIPs

Fleischer CT et al., Bioanalytical solid-phase extraction. A classic in a new made-to-measure form.
GIT Labor-Fachzeitschrift, (2 (Special issue)), 89-92, (2000)
   

Review - receptor-ligand interactions

Guryanov I et al., Receptor-ligand interactions: Advanced biomedical applications.
Materials Science and Engineering: C, 68, 890-903, (2016)
   

Review - recognition elements in sensing

Justino CIL et al., Recent developments in recognition elements for chemical sensors and biosensors.
TrAC Trends in Analytical Chemistry, 68, 2-17, (2015)
   

Review - recognition material for sensors

Book chapter, Jaworski J, Biomimetic Molecular Recognition Elements for Chemical Sensing, 
In: Biomimetic Approaches for Biomaterials Development, Mano JF (Ed.) Wiley-VCH Verlag GmbH & Co. KGaA: 117-156, (2012)
   

Review - recognition of uracil and 5-fluorouracil

Pandey K et al., A Critical Review on Clinical Application of Separation Techniques for Selective Recognition of Uracil and 5-Fluorouracil.
Indian Journal of Clinical Biochemistry, 31, (1), 3-12, (2016)
   

Review - recognition with synthetic macromolecules

Mahon CS et al., Mimicking nature with synthetic macromolecules capable of recognition.
Nature Chemistry, 6, (8), 665-672, (2014)
   

Review - recovery of vanillin

Mota MIF et al., Recovery of Vanillin and Syringaldehyde from Lignin Oxidation: A Review of Separation and Purification Processes.
Separation & Purification Reviews, 45, (3), 227-259, (2016)
   

Review - remediation of chromium and nickel in environmental water

Kumar A et al., Remediation techniques applied for aqueous system contaminated by toxic Chromium and Nickel ion.
Geology, Ecology, and Landscapes, 1, (2), 143-153, (2017)
   

Review - removal of endocrine disruptors

Sun SD et al., Polymeric Particles for the Removal of Endocrine Disruptors.
Separation & Purification Reviews, 40, (4), 312-337, (2011)
   

Review - removal of estrogens from water

Silva CP et al., Processes for the elimination of estrogenic steroid hormones from water: A review.
Environmental Pollution, 165, (1), 38-58, (2012)
   

Review - removal of heavy metal ions from water

Book chapter, Mamba BBet al., Advances in Nanostructured Polymers and Membranes for Removal of Heavy Metals in Water, 
In: Aquananotechnology: Global Prospects, Reisner DE, Pradeep T (Eds.) CRC Press: Boca Raton, 399-418, (2014)
   

Review - removal or destruction of encrine disruptors

Kralchevska RP et al., Some endocrine disrupting compounds in the environment and possibilities for their removal / degradation.
Bulgarian Chemical Communications, 45, (2), 131-143, (2013)
   

Review - research methods in chinese traditional medicine

Wei YY et al., Progress on the updated methods and sophisticated technics used in research of Chinese traditional medicinal compound recipes.
Chinese Journal of Integrated Traditional and Western Medicine, 25, (11), 1050-1052, (2005)
   

Review - resins for extraction of rare eaths

Li XZ et al., Progress in solid-liquid extraction resin for separation of rare earth elements.
Journal of Rare Earths, 23, (Supplement 1), 581-592, (2005)
   

Review - responsive biomaterials

Peppas NA et al., The challenge to improve the response of biomaterials to the physiological environment.
Regenerative Biomaterials, 3, (2), 67-71, (2016)
   

Review - responsive hydrogels

Matsumoto K et al., Stimuli-Responsive Hydrogels Using Biomolecular Functions.
Kobunshi Ronbunshu, 71, (4), 125-142, (2014)
   

Review - Resposive hydrogels

Gawel K et al., Responsive Hydrogels for Label-Free Signal Transduction within Biosensors.
Sensors, 10, (5), 4381-4409, (2010)
   

Review - restricted access materials in sample preparation

de Faria HD et al., New advances in restricted access materials for sample preparation: A review.
Analytica Chimica Acta, 959, 43-65, (2017)
   

Review - restricted access media (RAM)

Yang SH et al., Restricted access media as a streamlined approach toward on-line sample preparation: Recent advancements and applications.
Journal of Separation Science, 36, (17), 2922-2938, (2013)
   

Review - reversible covalent chemistry in analytical applications

Siegel D, Applications of reversible covalent chemistry in analytical sample preparation.
Analyst, 137, (23), 5457-5482, (2012)
   

Review - Review fluorescent sensor arrays

Book chapter, Paolesse Ret al., Fluorescence Based Sensor Arrays, 
In: Luminescence Applied in Sensor Science, Prodi L, Montalti M, Zaccheroni N (Eds.) Springer: Berlin / Heidelberg, 139-174, (2011)
   

Review - RT phosphorescence in optical sensing

Sánchez-Barragán I et al., Room-temperature phosphorescence (RTP) for optical sensing.
TrAC Trends in Analytical Chemistry, 25, (10), 958-967, (2006)
   

Review - sample clean-up for mycotoxin analysis

Cichna-Markl M, New strategies in sample clean-up for mycotoxin analysis.
World Mycotoxin Journal, 4, (3), 203-215, (2011)
   

Review - sample enrichment in CE

Wen YY et al., Recent advances in enrichment techniques for trace analysis in capillary electrophoresis.
Electrophoresis, 33, (19-20), 2933-2952, (2012)
   

Review - sample extraction

Tang S et al., Advances in Sample Extraction.
Analytical Chemistry, 88, (1), 228-249, (2016)
   

Review - sample preparation

Haginaka J, Pretreatment procedures of trace samples for chromatography.
Bunseki, (5), 259-264, (2000)
   

Review - sample preparation

Moldoveanu SC, Solutions and challenges in sample preparation for chromatography.
Journal of Chromatographic Science, 42, (1), 1-14, (2004)
   

Review - sample preparation

Book chapter, Arruda MAZet al., Strategies for Sample Preparation Focusing Biomolecules Determination/Characterization, 
In: Trends in Sample Preparation, Arruda MAZ (Ed.) Nova Science Publishers: 245-288, (2006)
   

Review - sample preparation

Wille SMR et al., Recent developments in extraction procedures relevant to analytical toxicology.
Analytical and Bioanalytical Chemistry, 388, (7), 1381-1391, (2007)
   

Review - sample preparation

Ashri NY et al., Sample treatment based on extraction techniques in biological matrices.
Bioanalysis, 3, (17), 2003-2018, (2011)
   

Review sample preparation

Cobzac SC et al., Sample preparation for high performance liquid chromatography: Recent progress.
Journal of Liquid Chromatography & Related Technologies, 34, (13), 1157-1267, (2011)
   

Review - Sample preparation

Cassiano NM et al., New Trends in Sample Preparation in Brazil: an Overview of Bioanalytical Applications by Liquid Chromatography.
Journal of the Brazilian Chemical Society, 25, (1), 9-19, (2014)
   

Review - sample preparation for bioanalysis

Kole PL et al., Recent advances in sample preparation techniques for effective bioanalytical methods.
Biomedical Chromatography, 25, (1-2), 199-217, (2011)
   

Review - sample preparation for endocrine disruptor analysis

Singh B et al., Recent Advances in Sample Preparation Methods for Analysis of Endocrine Disruptors from Various Matrices.
Critical Reviews in Analytical Chemistry, 44, (3), 255-269, (2014)
   

Review - Sample preparation for environmental analysis

Book chapter, Lucci Pet al., Current Trends in Sample Treatment Techniques for Environmental and Food Analysis, 
In: Chromatography - The Most Versatile Method of Chemical Analysis, de Azevedo Calderon A (Ed.) InTech: 127-164, (2012)
   

Review - sample preparation for proteins and peptides

Visser N et al., Sample preparation for peptides and proteins in biological matrices prior to liquid chromatography and capillary zone electrophoresis.
Analytical and Bioanalytical Chemistry, 382, (3), 535-558, (2005)
   

Review - sample preparation for residue analysis in food

Zhang LJ et al., A review of sample preparation methods for the pesticide residue analysis in foods.
Central European Journal of Chemistry, 10, (3), 900-925, (2012)
   

Review - sample preparation in bioanalysis

Theodoridis GA et al., Novel advanced approaches in sample preparation and analyte detection for bioanalysis.
Current Pharmaceutical Analysis, 2, (4), 385-404, (2006)
   

Review - sample preparation in carbohydrate analysis

Sanz ML et al., Recent developments in sample preparation for chromatographic analysis of carbohydrates.
Journal of Chromatography A, 1153, (1-2), 74-89, (2007)
   

Review - sample preparation in chlorophenols analysis

Quintana MC et al., Sample preparation for the determination of chlorophenols.
TrAC Trends in Analytical Chemistry, 27, (5), 418-436, (2008)
   

Review - sample preparation in forensic toxicology

Samanidou V et al., Novel strategies for sample preparation in forensic toxicology.
Bioanalysis, 3, (17), 2019-2046, (2011)
   

Review - sample preparation methods for ion mobility spectrometry

Sorribes-Soriano A et al., Trace analysis by ion mobility spectrometry: From conventional to smart sample preconcentration methods. A review.
Analytica Chimica Acta, 1026, 37-50, (2018)
   

Review - sample preparation techniques

Ramos L, Critical overview of selected contemporary sample preparation techniques.
Journal of Chromatography A, 1221, (1), 84-98, (2012)
   

Review - sample preparation techniques

Kokosa JM, Advances in solvent-microextraction techniques.
TrAC Trends in Analytical Chemistry, 43, 2-13, (2013)
   

Review - sample preparation techniques

Hialemariam T et al., Recent Advances in Sample Preparation Techniques Using SFE; MAE & MIP In Environmental Matrice: A Critical Overview.
Research Journal of Chemical and Environmental Sciences, 4, (1), 11-27, (2016)
   

Review - sample pretreatment in urine analysis

Cruz-Vera M et al., Highly selective and non-conventional sorbents for the determination of biomarkers in urine by liquid chromatography.
Analytical and Bioanalytical Chemistry, 397, (3), 1029-1038, (2010)
   

Review - scaffold imprinting

Book chapter, Kobayashi T, Scaffold imprinting, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 285-306, (2005)
   

Review - screen-printed electrochemical sensors

Book chapter, Hart JPet al., Screen-printed electrochemical (bio)sensors in biomedical, environmental and industrial applications, 
In: Electrochemical Sensor Analysis, Alegret S, Merkoçi A (Eds.) Elsevier: 497-557, (2007)
   

Review - selecting functional monomers

Book chapter, Ramström O, Synthesis and selection of functional and structural monomers, 
In: Molecularly Imprinted Materials: Science and Technology, Yan M, Ramström O (Eds.) Marcel Dekker: New York, 181-224, (2005)
   

Review - selective binding of metal ions

Kaye PT, Designer ligands: The search for metal ion selectivity.
South African Journal of Science, 107, (3-4), Art. No. 439-(2011)
   

Review - selective catalysis

Tada M et al., Advanced chemical design with supported metal complexes for selective catalysis.
Chemical Communications, (27), 2833-2844, (2006)
   

Review - selective catalysis

Tada M et al., Advanced design of catalytically active reaction space at surfaces for selective catalysis.
Coordination Chemistry Reviews, 251, (21-24), 2702-2716, (2007)
   

Review - selective sol-gel materials in chemical analysis

Collinson MM, Sol-gel strategies for the preparation of selective materials for chemical analysis.
Critical Reviews in Analytical Chemistry, 29, (4), 289-311, (1999)
   

Review - Selectivity of chemical sensors

Book chapter, Janata J, Selectivity, 
In: Principles of Chemical Sensors, Springer US: 13-50, (2009)
   

Review - selenoenzyme mimics

Book chapter, Huang Xet al., Nanoenzymes as Selenoprotein Mimics, 
In: Selenoproteins and Mimics, Liu JQ, Luo GM, Mu Y (Eds.) Springer: Berlin Heidelberg, 289-302, (2012)
   

Review - self-organization and sensing

Book chapter, Dickert FLet al., Chemical Recognition and Sensing by Self-Organization, 
In: Encyclopedia of Supramolecular Chemistry, Atwood JL, Steed JW (Eds.) Taylor & Francis: 1-13, (2005)
   

Review - sensing and destruction of pesticides

Aragay G et al., Nanomaterials for Sensing and Destroying Pesticides.
Chemical Reviews, 112, (10), 5317-5338, (2012)
   

Review - sensing by heat transfer methods

Book chapter, Eersels Ket al., Heat Transfer as a New Sensing Technique for the Label-Free Detection of Biomolecules, 
In: Label-Free Biosensing: Advanced Materials, Devices and Applications, Schöning MJ, Poghossian A (Eds.) Springer International Publishing: Cham, 383-407, (2018)
   

Review - sensing engine oil quality

Mujahid A et al., Monitoring automotive oil degradation: analytical tools and onboard sensing technologies.
Analytical and Bioanalytical Chemistry, 404, (4), 1197-1209, (2012)
   

Review - sensing of bisphenols

Dhanjai et al., Advances in sensing and biosensing of bisphenols: A review.
Analytica Chimica Acta, 998, 1-27, (2018)
   

Review - sensing of ’phenicol’ antibiotics

Pilehvar S et al., (Electro)Sensing of Phenicol Antibiotics - A Review.
Critical Reviews in Food Science and Nutrition, 56, (14), 2416-2429, (2016)
   

Review - sensing organophosphate pesticides

Kumar P et al., Recent advancements in sensing techniques based on functional materials for organophosphate pesticides.
Biosensors and Bioelectronics, 70, 469-481, (2015)
   

Review - sensing with graphene

Liu JQ et al., Molecularly engineered graphene surfaces for sensing applications: A review.
Analytica Chimica Acta, 859, 1-19, (2015)
   

Review - sensing with polymeric systems

Sanjuán AM et al., Recent developments in sensing devices based on polymeric systems.
Reactive and Functional Polymers, 133, 103-125, (2018)
   

Review - sensor arrays

Askim JR et al., Optical sensor arrays for chemical sensing: the optoelectronic nose.
Chemical Society Reviews, 42, (22), 8649-8682, (2013)
   

Review - sensor development in Spain

Plata MR et al., State-of-the-Art of (Bio)Chemical Sensor Developments in Analytical Spanish Groups.
Sensors, 10, (4), 2511-2576, (2010)
   

Review - sensor fabrication

Book chapter, Fink JK, Methods of Fabrication, 
In: Polymeric Sensors and Actuators, Wiley: Somerset, NJ, USA, 43-66, (2012)
   

Review - sensor for detection of melamine

Li Y et al., Chemical sensors and biosensors for the detection of melamine.
RSC Advances, 5, (2), 1125-1147, (2015)
   

Review - sensors

Proceeding, Turner APF et al, Biosensors and biomimetic sensors for the detection of drugs, toxins and biological agents, 
Morrison D, Milanovich F, Ivnitski D, Austin TR (Eds.), 261-272, (2005)
   

Review - sensors

Book chapter, Farré Met al., Sensor, biosensors and MIP based sensors, 
In: Food Toxicants Analysis, Picó Y (Ed.) Elsevier: Amsterdam, 599-636, (2007)
   

Review - Sensors

Kimmel DW et al., Electrochemical Sensors and Biosensors.
Analytical Chemistry, 84, (2), 685-707, (2012)
   

Review - sensors and assays for small molecules

Fodey T et al., Developments in the production of biological and synthetic binders for immunoassay and sensor-based detection of small molecules.
TrAC Trends in Analytical Chemistry, 30, (2), 254-269, (2011)
   

Review - sensors based on carbon nanomaterials and polymers

Salavagione HJ et al., Chemical sensors based on polymer composites with carbon nanotubes and graphene: the role of the polymer.
Journal of Materials Chemistry A, 2, (35), 14289-14328, (2014)
   

Review - sensors based on polypyrrole

Ramanavicius A et al., Electrochemical sensors based on conducting polymer--polypyrrole.
Electrochimica Acta, 51, (27), 6025-6037, (2006)
   

Review - sensors for antineoplastic drugs

Lima HRS et al., Electrochemical sensors and biosensors for the analysis of antineoplastic drugs.
Biosensors and Bioelectronics, 108, 27-37, (2018)
   

Review - sensors for bacteria detection

Tokonami S et al., Review: Novel sensing strategies for bacterial detection based on active and passive methods driven by external field.
Analytica Chimica Acta, 988, 1-16, (2017)
   

Review - sensors for bisphenol A

Ragavan KV et al., Sensors and biosensors for analysis of bisphenol-A.
TrAC Trends in Analytical Chemistry, 52, 248-260, (2013)
   

Review - sensors for creatinine

Pundir CS et al., Creatinine sensors.
TrAC Trends in Analytical Chemistry, 50, 42-52, (2013)
   

Review - sensors for detection of chemical warfare agents

Burnworth M et al., Fluorescent Sensors for the Detection of Chemical Warfare Agents.
Chemistry - A European Journal, 13, (28), 7828-7836, (2007)
   

Review - sensors for endocrine disruptors

Book chapter, Bezbaruah ANet al., Sensors and biosensors for endocrine disrupting chemicals: State-of-the-art and future trends, 
In: Treatment of Micropollutants in Water and Wastewater, Virkutyte J, Jegatheesan V, Varma RS (Eds.) IWA Publishing: London, 93-128, (2010)
   

Review - sensors for explosives

Salinas Y et al., Optical chemosensors and reagents to detect explosives.
Chemical Society Reviews, 41, (3), 1261-1296, (2012)
   

Review - sensors for heavy metals

Malitesta C et al., From Electrochemical Biosensors to Biomimetic Sensors Based on Molecularly Imprinted Polymers in Environmental Determination of Heavy Metals.
Frontiers in Chemistry, 5, ArticleNo47-(2017)
   

Review - sensors for in-flight monitoring of astronaut’s health

Aponte VM et al., Considerations for non-invasive in-flight monitoring of astronaut immune status with potential use of MEMS and NEMS devices.
Life Sciences, 79, (14), 1317-1333, (2006)
   

Review - sensors for mycotoxin analysis

Peltomaa R et al., Bioinspired recognition elements for mycotoxin sensors.
Analytical and Bioanalytical Chemistry, 410, (3), 747-771, (2018)
   

Review - sensors for pesticide detection in foods

Capoferri D et al., Affinity Sensing Strategies for the Detection of Pesticides in Food.
Foods, 7, (9), ArticleNo148-(2018)
   

Review - sensors for pesticides and inorganics

Rao TP et al., Biomimetic Sensors for Toxic Pesticides and Inorganics based on Optoelectronic/Electrochemical Transducers-An Overview.
Critical Reviews in Analytical Chemistry, 37, (3), 191-210, (2007)
   

Review - sensors for phosphate

Warwick C et al., Sensing and analysis of soluble phosphates in environmental samples: A review.
Biosensors and Bioelectronics, 41, 1-11, (2013)
   

Review - sensors for toxins

Xu H et al., Application of the new recognition molecular sensors in the small toxins.
Science and Technology of Food Industry, 33, (18), 367-370, (2012)
   

Review - sensors for water pollution monitoring

Proceeding, Rickerby DG et al, Biosensor networks for monitoring water pollution, 
276-282, (2011)
   

Review - sensors in environmental analysis

Lieberzeit PA et al., Sensor technology and its application in environmental analysis.
Analytical and Bioanalytical Chemistry, 387, (1), 237-247, (2007)
   

Review - Separation materials synthesis

Wang HS et al., Development of separation materials using controlled/living radical polymerization.
TrAC Trends in Analytical Chemistry, 31, (1), 96-108, (2012)
   

Review - separation of radioactive metals

Pan JM et al., Progress in the study of separation, enrichment and analysis of mid-low radioactive metallic elements.
Metallurgical Analysis, 30, (8), 35-44, (2010)
   

Review - separations and supercritical fluids

Yoon SD et al., Application of Separation Technology and Supercritical Fluids Process.
Clean Technology, 18, (2), 123-143, (2012)
   

Review - SERS detection of chemical hazards in food

Liao W et al., Determination of chemical hazards in foods using surface-enhanced Raman spectroscopy coupled with advanced separation techniques.
Trends In Food Science & Technology, 54, 103-113, (2016)
   

Review - silica aerogels

Patel RP et al., An overview of silica aerogels.
International Journal of ChemTech Research, 1, (4), 1052-1057, (2009)
   

Review - silica-based sol-gels

Benvenutti EV et al., Silica based hybrid materials obtained by the sol-gel method.
Quimica Nova, 32, (7), 1926-1933, (2009)
   

Review - silica materials in food analysis for xenobiotics

Casado N et al., Current development and applications of ordered mesoporous silicas and other sol-gel silica-based materials in food sample preparation for xenobiotics analysis.
TrAC Trends in Analytical Chemistry, 88, 167-184, (2017)
   

Review - silica nanoparticles for pesticide detection

Bapat G et al., Silica nanoparticle based techniques for extraction, detection, and degradation of pesticides.
Advances in Colloid and Interface Science, 237, 1-14, (2016)
   

Review - silica nanotubes

García-Calzón JA et al., Synthesis and analytical potential of silica nanotubes.
TrAC Trends in Analytical Chemistry, 35, (1), 27-38, (2012)
   

Review - Silica sol-gels in analytical chemistry

Walcarius A et al., Analytical Chemistry with Silica Sol-Gels: Traditional Routes to New Materials for Chemical Analysis.
Annual Review of Analytical Chemistry, 2, 121-143, (2009)
   

Review - silicate materials

Proceeding, Johnson BJ et al, Functional and functionalized silicate materials, 
19-24, (2011)
   

Review - smart drug delivery systems

Alvarez-Lorenzo C et al., Smart drug delivery systems: from fundamentals to the clinic.
Chemical Communications, 50, (58), 7743-7765, (2014)
   

Review - smart MIPs

Ge Y et al., Smart Molecularly Imprinted Polymers: Recent Developments and Applications.
Macromolecular Rapid Communications, 34, (11), 903-915, (2013)
   

Review - smart polymer gels

Chaterji S et al., Smart polymeric gels: Redefining the limits of biomedical devices.
Progress in Polymer Science, 32, (8-9), 1083-1122, (2007)
   

Review - smart polymers in drug delivery

Bayer CL et al., Advances in recognitive, conductive and responsive delivery systems.
Journal of Controlled Release, 132, (3), 216-221, (2008)
   

Review - sol-gel materials in electrochemistry

Walcarius A et al., Exciting new directions in the intersection of functionalized sol-gel materials with electrochemistry.
Journal of Materials Chemistry, 15, (35-36), 3663-3689, (2005)
   

Review - sol-gel materials in optical sensing

Monton MR et al., Tailoring Sol-Gel-Derived Silica Materials for Optical Biosensing.
Chemistry of Materials, 24, (5), 796-811, (2012)
   

Review - sol-gel MIPs

Lü YK et al., Preparation and application of molecularly imprinted sol-gel materials.
Chinese Journal of Analytical Chemistry, 33, (2), 254-260, (2005)
   

Review - sol-gel MIPs

Book chapter, Lee SWet al., Molecular Imprinting by the Surface Sol-Gel Process: Templated Nanoporous Metal Oxide Thin Films for Molecular Recognition, 
In: Self-Organized Nanoscale Materials, Adachi M, Lockwood CJ (Eds.) Springer: New York, 186-220, (2006)
   

Review - Sol-gels

Kloskowski A et al., Sol-Gel Technique A Versatile Tool for Adsorbent Preparation.
Critical Reviews in Analytical Chemistry, 40, (3), 172-186, (2010)
   

Review - sol-gel solid phase microextraction

Amiri A, Solid-phase microextraction-based sol-gel technique.
TrAC Trends in Analytical Chemistry, 75, 57-74, (2016)
   

Review - solid phase extraction

Zwir-Ferenc A et al., Solid Phase Extraction Technique - Trends, Opportunities and Applications.
Polish Journal of Environmental Studies, 15, (5), 677-690, (2006)
   

Review - solid phase extraction

Book chapter, Dean JR, Solid Phase Extraction, 
In: Extraction Techniques in Analytical Sciences, John Wiley & Sons Ltd.: Chichester, 49-84, (2009)
   

Review - solid-phase extraction

Huang YR et al., Research progress of solid phase extraction adsorbent.
Metallurgical Analysis, 32, (12), 22-28, (2012)
   

Review - solid phase extraction

Book chapter, Poole CFet al., 2.14 - Principles and Practice of Solid-Phase Extraction, 
In: Comprehensive Sampling and Sample Preparation, Pawliszyn J (Ed.) Academic Press: Oxford, 273-297, (2012)
   

Review - solid phase extraction

Fan HX et al., Development of new solid phase extraction techniques in the last ten years.
Journal of Chinese Pharmaceutical Sciences, 22, (4), 293-302, (2013)
   

Review - solid phase extraction

Book chapter, Buszewski Bet al., Solid phase extraction - principles, trends and applications, 
In: MEMBRANY TEORIA I PRAKTYKA (Membrane Theory and Practice), Wodzki R (Ed.) Stowarzyszenie na Rzecz Rozwoju Wydzialu Chemii Uniwersytet Mikolaja Kopernika: Torun, Poland, 99-131, (2014)
   

Review - Solid phase extraction

Gilart N et al., Selective materials for solid-phase extraction in environmental analysis.
Trends in Environmental Analytical Chemistry, 1, e8-e18, (2014)
   

Review - solid-phase extraction

Book chapter, Moldoveanu Set al., Solid-Phase Extraction, 
In: Modern Sample Preparation for Chromatography, David SMV (Ed.) Elsevier: Amsterdam, 191-286, (2015)
   

review - solid phase extraction

Madikizela LM et al., Recent Developments in Selective Materials for Solid Phase Extraction.
Chromatographia, 82, (8), 1171-1189, (2019)
   

Review - solid phase extraction from biological samples

Bylda C et al., Recent advances in sample preparation techniques to overcome difficulties encountered during quantitative analysis of small molecules from biofluids using LC-MS/MS.
Analyst, 139, (10), 2265-2276, (2014)
   

Review - solid phase extraction in environmental analysis

Xiao JP et al., Recent advances of adsorbents in solid phase extraction for environmental samples.
International Journal of Environmental Analytical Chemistry, 96, (5), 407-435, (2016)
   

Review - solid-phase extraction of ochratoxin A

Pichon V et al., Selective tools for the solid-phase extraction of Ochratoxin A from various complex samples: immunosorbents, oligosorbents, and molecularly imprinted polymers.
Analytical and Bioanalytical Chemistry, 408, (25), 6983-6999, (2016)
   

Review - solid phase extraction of organic compounds

Andrade-Eiroa A et al., Solid-phase extraction of organic compounds: A critical review (Part I).
TrAC Trends in Analytical Chemistry, 80, 641-654, (2016)
   

Review - solid phase extraction (SPE)

Buszewski B et al., Past, Present, and Future of Solid Phase Extraction: A Review.
Critical Reviews in Analytical Chemistry, 42, (3), 198-213, (2012)
   

Review - solid-phase extration

Hennion MC, Solid-phase extraction: method development, sorbents, and coupling with liquid chromatography.
Journal of Chromatography A, 856, (1-2), 3-54, (1999)
   

Review - Solid-phase microextraction

Jiang GB et al., Progress of solid-phase microextraction coatings and coating techniques.
Journal of Chromatographic Science, 44, (6), 324-332, (2006)
   

Review - solid-phase microextraction

Chen JM et al., Development of new coatings for solid-phase microextraction.
Progress In Chemistry, 21, (9), 1922-1929, (2009)
   

Review - solid phase microextraction

Kataoka H et al., Recent advances in SPME techniques in biomedical analysis.
Journal of Pharmaceutical and Biomedical Analysis, 54, (5), 926-950, (2011)
   

Review - solid phase microextraction

Kataoka H, Current Developments and Future Trends in Solid-phase Microextraction Techniques for Pharmaceutical and Biomedical Analyses.
Analytical Sciences, 27, (9), 893-905, (2011)
   

Review - solid-phase microextraction

Abdulra’uf LB et al., Applications of solid-phase microextraction for the analysis of pesticide residues in fruits and vegetables: A review.
Journal of AOAC International, 95, (5), 1272-1290, (2012)
   

Review - solid-phase microextraction

Bagheri H et al., Towards greater mechanical, thermal and chemical stability in solid-phase microextraction.
TrAC Trends in Analytical Chemistry, 34, (1), 126-139, (2012)
   

Review - solid-phase microextraction

Mehdinia A et al., Advances for sensitive, rapid and selective extraction in different configurations of solid-phase microextraction.
TrAC Trends in Analytical Chemistry, 51, 13-22, (2013)
   

Review - solid-phase microextraction

Spietelun A et al., Understanding Solid-Phase Microextraction: Key Factors Influencing the Extraction Process and Trends in Improving the Technique.
Chemical Reviews, 113, (3), 1667-1685, (2013)
   

Review - solid-phase microextraction

Xu JQ et al., New materials in solid-phase microextraction.
TrAC Trends in Analytical Chemistry, 47, 68-83, (2013)
   

Review - solid phase microextraction

Aziz-Zanjani MO et al., A review on procedures for the preparation of coatings for solid phase microextraction.
Microchimica Acta, 181, (11-12), 1169-1190, (2014)
   

Review - solid phase microextraction

Li J et al., Advances in different configurations of solid-phase microextraction and their applications in food and environmental analysis.
TrAC Trends in Analytical Chemistry, 72, 141-152, (2015)
   

Review - solid-phase microextraction

Hou XD et al., Recent Developments in Solid-phase Microextraction Coatings for Environmental and Biological Analysis.
Chemistry Letters, 46, (10), 1444-1455, (2017)
   

Review - solid-phase microextraction fibres

Spietelun A et al., Current trends in solid-phase microextraction (SPME) fibre coatings.
Chemical Society Reviews, 39, (11), 4524-4537, (2010)
   

Review - solid-phase microextraction of food contaminants

Book chapter, Souza-Silva ÉAet al., Recent Advances in Solid-Phase Microextraction for Contaminant Analysis in Food Matrices, 
In: Green Extraction Techniques Principles, Advances and Applications, Ibáñez E, Cifuentes A (Eds.) Elsevier: 483-517, (2017)
   

Review - solid-phase microextraction (SPME)

Book chapter, Pawliszyn J, Development of SPME Devices and Coatings, 
In: Handbook of Solid Phase Microextraction, Pawliszyn J (Ed.) Elsevier: Oxford, 61-97, (2012)
   

Review - solid phase microextraction techniques

Moein MM et al., Solid Phase Microextraction and Related Techniques for Drugs in Biological Samples.
Journal of Analytical Methods in Chemistry, 2014, Article ID 921350-(2014)
   

Review - solid phase spectrometry

Matsuoka S et al., Recent trends in solid phase spectrometry: 2003-2009. A Review.
Analytica Chimica Acta, 664, (1), 1-18, (2010)
   

Review - Sorbents for platinum

Book chapter, Pyrzynska K, Application of Solid Sorbents for Enrichment and Separation of Platinum Metal Ions, 
In: Platinum Metals in the Environment, Zereini F, Wiseman CLS (Eds.) Springer-Verlag: Berlin, Heidelberg, 67-78, (2015)
   

Review - sorbents for sample preparation

Wen YY et al., Recent advances in solid-phase sorbents for sample preparation prior to chromatographic analysis.
TrAC Trends in Analytical Chemistry, 59, 26-41, (2014)
   

Review - sorbents for solid-phase extraction

Augusto F et al., New materials and trends in sorbents for solid-phase extraction.
TrAC Trends in Analytical Chemistry, 43, 14-23, (2013)
   

Review - sorbents for SPE

Peng Y et al., Polymer sorbents used for solid phase extraction.
Polymer Materials Science and Engineering, 23, (4), 1-5, (2007)
   

Review - sorbents for SPE and SPME

Hashemi B et al., Recent developments and applications of different sorbents for SPE and SPME from biological samples.
Talanta, 187, 337-347, (2018)
   

Review - Sorptive microextraction of drugs

Cruz-Vera M et al., Sorptive microextraction for liquid-chromatographic determination of drugs in urine.
TrAC Trends in Analytical Chemistry, 28, (10), 1164-1173, (2009)
   

Review - SPE

Chapuis F et al., Preconcentration by solid phase extraction: Principles and applications in the environmental and petroleum industries.
Oil & Gas Science and Technology-Revue de l’Institut Francais du Petrole, 60, (6), 899-912, (2005)
   

Review - SPE

Majors RE, Advanced topics in solid-phase extraction: Chemistries. Lc Gc Europe, 
20, (5), 266-279, (2007)
   

Review - SPE

Book chapter, Pyrzynska K, The Use of Novel Materials as Solid-Phase Extractors for Chromatographic Analysis, 
In: Advances in Chromatography, Volume 49, Grushka E, Grinberg N (Eds.) CRC Press: Boca Raton, Fl., 365-399, (2011)
   

Review - speciation analysis for atomic spectroscopy

Wang ZH et al., The progress in speciation analysis of trace elements by atomic spectrometry.
Spectroscopy and Spectral Analysis, 33, (12), 3377-3382, (2013)
   

Review - SPE coupled methods in water analysis

Rodriguez-Mozaz S et al., Advantages and limitations of on-line solid phase extraction coupled to liquid chromatography-mass spectrometry technologies versus biosensors for monitoring of emerging contaminants in water.
Journal of Chromatography A, 1152, (1-2), 97-115, (2007)
   

Review - SPE for analysis of herbicides

Book chapter, Pyrzynska K, Solid-Phase Extraction for Enrichment and Separation of Herbicides, 
In: Herbicides, Theory and Applications, Soloneski S, Larramendy ML (Eds.) InTech: 325-344, (2011)
   

Review - SPE for copper

Tobiasz A et al., Solid-phase-extraction procedures for atomic spectrometry determination of copper.
TrAC Trends in Analytical Chemistry, 62, 106-122, (2014)
   

Review - SPE in flow analysis

Rocha FRP et al., Solid-phase extractions in flow analysis.
Anais da Academia Brasileira de Ciências, 90, (1 Suppl. 1), 803-824, (2018)
   

Review - SPE in food

Li G et al., Recent applications of solid-phase extraction techniques for analysis of trace residues and contaminants in food.
Chinese Journal of Chromatography, 29, (7), 606-612, (2011)
   

Review - SPE in pesticide residue analysis

Picó Y et al., Current trends in solid-phase-based extraction techniques for the determination of pesticides in food and environment.
Journal of Biochemical and Biophysical Methods, 70, (2), 117-131, (2007)
   

Review - SPE-LC methods

Chen LG et al., On-line Coupling of Solid-Phase Extraction to Liquid Chromatography-A Review.
Journal of Chromatographic Science, 47, (8), 614-623, (2009)
   

Review - SPE of Au,Pd and Pt

Mladenova E et al., Solid-phase extraction in the determination of gold, palladium, and platinum.
Journal of Separation Science, 35, (10-11), 1249-1265, (2012)
   

Review - SPE of food contaminents

Ridgway K et al., Sample preparation techniques for the determination of trace residues and contaminants in foods.
Journal of Chromatography A, 1153, (1-2), 36-53, (2007)
   

Review - SPE of metal ions

Türker AR, Separation, Preconcentration and Speciation of Metal Ions by Solid Phase Extraction.
Separation & Purification Reviews, 41, (3), 169-206, (2012)
   

Review - SPE of trace elements

Ibrahim WAW et al., Application of Solid-Phase Extraction for Trace Elements in Environmental and Biological Samples: A Review.
Critical Reviews in Analytical Chemistry, 44, (3), 233-254, (2014)
   

Review - SPE of xenobiotics

Kumazawa T et al., New and unique methods of solid-phase extraction for use before instrumental analysis of xenobiotics in human specimens.
Forensic Toxicology, 28, (2), 61-68, (2010)
   

Review - SPR

Book chapter, Fink JK, Surface Plasmon Resonance, 
In: Polymeric Sensors and Actuators, Wiley: Somerset, NJ, USA, 225-239, (2012)
   

Review - SPR and nanomaterials for biosensing

Zeng SW et al., Nanomaterials enhanced surface plasmon resonance for biological and chemical sensing applications.
Chemical Society Reviews, 43, (10), 3426-3452, (2014)
   

Review - Spreader-bar systems for artificial receptor synthesis

Book chapter, Hirsch T, Artificial Receptors Based on Spreader-Bar Systems, 
In: Artificial Receptors for Chemical Sensors, Mirsky VM, Yatsimirsky AK (Eds.) Wiley-VCH Verlag GmbH & Co. KGaA: Weinheim, 319-332, (2010)
   

Review - SPR sensors for marine toxins

Book chapter, Campbell K, Surface Plasmon Resonance Biosensor Technology for Marine Toxin Analysis, 
In: Seafood and Freshwater Toxins: Pharmacology, Physiology, and Detection, Botana LM (Ed.) CRC Press: Boca Raton, 347-366, (2014)
   

Review - Staphylococcus aureus enterotoxin detection

Wu SJ et al., A Review of the Methods for Detection of Staphylococcus aureus Enterotoxins.
Toxins, 8, (7), ArticleNo176-(2016)
   

Review - stationary phases for TLC

Gocan S, Stationary phases for thin-layer chromatography.
Journal of Chromatographic Science, 40, (10), 538-549, (2002)
   

Review - stimuli-responsive catalysts

Zhang JL et al., Polymer-Based Stimuli-Responsive Recyclable Catalytic Systems for Organic Synthesis.
Small, 10, (1), 32-46, (2014)
   

Review - stimuli responsive gels

Miyata T, Design of Stimuli-Responsive Gels and Their Applications.
Nippon Gomu Kyokaishi, 78, (4), 135-141, (2005)
   

Review - stimuli responsive materials in separations

Lorenzo RA et al., Stimuli-responsive materials in analytical separation.
Analytical and Bioanalytical Chemistry, 407, (17), 4927-4948, (2015)
   

Review - stimuli-responsive membranes

Huda N et al., A Review on Stimuli-responsive grafted membranes Based on Facile Synthesis Process and Extensive Applications.
International Journal of Innovation and Applied Studies, 8, (3), 1296-1312, (2014)
   

Review - stimuli-responsive MIPs

Xu SF et al., Stimuli-responsive molecularly imprinted polymers: versatile functional materials.
Journal of Materials Chemistry C, 1, (29), 4406-4422, (2013)
   

Review - stimuli-responsive polymers

Islam MR et al., Responsive polymers for analytical applications: A review.
Analytica Chimica Acta, 789, 17-32, (2013)
   

Review - stimulus-resposive hydrogels

Koetting MC et al., Stimulus-responsive hydrogels: Theory, modern advances, and applications.
Materials Science and Engineering: R: Reports, 93, 1-49, (2015)
   

Review - stir bar extraction

Lucena R, Extraction and stirring integrated techniques: examples and recent advances.
Analytical and Bioanalytical Chemistry, 403, (8), 2213-2223, (2012)
   

Review - stir-bar extraction

He M et al., Recent developments in stir bar sorptive extraction.
Analytical and Bioanalytical Chemistry, 406, (8), 2001-2026, (2014)
   

Review - stir-bar sorptive extraction

Rykowska I et al., Advances in Stir Bar Sorptive Extraction Coating: A Review.
Acta Chromatographica, 25, (1), 27-46, (2013)
   

Review - Stir bar sorptive extraction

Abdulra’uf LB et al., Review of SBSE Technique for the Analysis of Pesticide Residues in Fruits and Vegetables.
Chromatographia, 77, (1-2), 15-24, (2014)
   

Review - styrene-DVB copolymers in inorganic analysis

Rao TP et al., Styrene-divinyl benzene copolymers: Synthesis, characterization, and their role in inorganic trace analysis.
Critical Reviews in Analytical Chemistry, 34, (3-4), 177-193, (2004)
   

Review - sulfated sugars

Kovensky J, Sulfated Oligosaccharides: New Targets for Drug Development?
Current Medicinal Chemistry, 16, (18), 2338-2344, (2009)
   

Review - supramolecular chemistry

Manna AK, Supramolecular Chemistry-Concepts and Applications.
International Journal of Science and Research (IJSR), 4, (4), PaperID:29031502-(2015)
   

Review - supramolecular systems in radiochemistry

Shen XH et al., Applications of Typical Supramolecular Systems in the Field of Radiochemistry.
Progress In Chemistry, 23, (7), 1386-1399, (2011)
   

Review - surface acoustic wave sensors

Wang W et al., Viscoelastic analysis of a surface acoustic wave gas sensor coated by a new deposition technique.
Chinese Journal of Chemical Physics, 19, (1), 47-53, (2006)
   

Review - surface acoustic wave sensors

Mujahid A et al., Surface Acoustic Wave (SAW) for Chemical Sensing Applications of Recognition Layers.
Sensors, 17, (12), ArticleNo2716-(2017)
   

Review - Surface-Enhanced Raman Spectroscopy Analysis

Wang F et al., Selectivity/Specificity Improvement Strategies in Surface-Enhanced Raman Spectroscopy Analysis.
Sensors, 17, (11), ArticleNo2689-(2017)
   

Review - surface imprinting in silica

Bing NC et al., Advances in Surface Molecular Imprinting Technique on Silica Material.
Chemical World, 48, (12), 754-757, (2007)
   

Review - surface modification by living radical polymerization

Liu P, Modification of polymeric materials via surface-initiated controlled/"living" radical polymerization.
E-Polymers, Art. No. 062-(2007)
   

Review - surface plasmon resonance biosensing

Wang XP et al., Review: Advances and Applications of Surface Plasmon Resonance Biosensing Instrumentation.
Instrumentation Science & Technology, 41, (6), 574-607, (2013)
   

Review - synthetic particle biomolecule interactions

Hoshino Y et al., Interaction between synthetic particles and biomacromolecules: fundamental study of nonspecific interaction and design of nanoparticles that recognize target molecules.
Polymer Journal, 46, (9), 537-545, (2014)
   

Review - synthetic receptors

Book chapter, Peck EMet al., Applications of Synthetic Receptors for Biomolecules, 
In: Synthetic Receptors for Biomolecules: Design Principles and Applications, Smith BD (Ed.) The Royal Society of Chemistry: Cambridge, 1-38, (2015)
   

Review - synthetic receptors for amino acids and peptides

Book chapter, Maity Det al., Synthetic Receptors for Amino Acids and Peptides, 
In: Synthetic Receptors for Biomolecules: Design Principles and Applications, Smith BD (Ed.) The Royal Society of Chemistry: Cambridge, 326-368, (2015)
   

Review - synthetic receptors for nucleosides and nucleotides

Book chapter, Oh Jet al., Synthetic Receptors for Nucleosides and Nucleotides, 
In: Synthetic Receptors for Biomolecules: Design Principles and Applications, Smith BD (Ed.) The Royal Society of Chemistry: Cambridge, 204-252, (2015)
   

Review - synthetic receptors for saccharides

Shinkai S et al., Molecular design of synthetic receptors with dynamic, imprinting, and allosteric functions.
Bulletin of the Chemical Society of Japan, 78, (1), 40-51, (2005)
   

Review - systems for landmine detection

Habib MK, Controlled biological and biomimetic systems for landmine detection.
Biosensors and Bioelectronics, 23, (1), 1-18, (2007)
   

Review - technologies for wastewater treatment

Book chapter, Kaur Jet al., Need for the Advanced Technologies for Wastewater Treatment, 
In: Advances in Environmental Biotechnology, Kumar R, Sharma AK, Ahluwalia SS (Eds.) Springer: Singapore, 39-52, (2017)
   

Review - templated porous silica

Albela B et al., Surface molecular engineering in the confined space of templated porous silica.
New Journal of Chemistry, 40, (5), 4115-4131, (2016)
   

Review - therapeutic contact lenses

González-Chomón C et al., Soft contact lenses for controlled ocular delivery: 50 years in the making.
Therapeutic Delivery, 4, (9), 1141-1161, (2013)
   

Review - therapeutic contact lenses

Poonam D et al., Therapeutic contact lens: a recent review.
Journal of Drug Discovery and Therapeutics, 1, (3), 36-39, (2013)
   

Review - TiO2 in sensors

Qiu JX et al., Recent applications of TiO2 nanomaterials in chemical sensing in aqueous media.
Sensors and Actuators B: Chemical, 160, (1), 875-890, (2011)
   

Review - Tissue repair

Book chapter, Rosellini Eet al., Engineering of Multifunctional Scaffolds for Myocardial Repair Through Nanofunctionalization and Microfabrication of Novel Polymeric Biomaterials, 
In: Myocardial Tissue Engineering, Boccaccini AR, Harding SE (Eds.) Springer Berlin Heidelberg: 187-214, (2011)
   

Review - trace analysis

Chapuis-Hugon F et al., Selective tools for trace analysis in complex samples (Utilisation d’outils sélectifs pour l’analyse de traces dans des échantillons complexes).
Annales de Toxicologie Analytique, 22, (2), 97-101, (2010)
   

Review - trifluoromethylacrylate polymers

Patil Y et al., Advances in the (co)polymerization of alkyl 2-trifluoromethacrylates and 2-(trifluoromethyl)acrylic acid.
Progress in Polymer Science, 38, (5), 703-739, (2013)
   

Review - Uranium removal

Aly MM et al., A Review: Studies on Uranium Removal Using Different Techniques. Overview.
Journal of Dispersion Science and Technology, 34, (2), 182-213, (2013)
   

Review - uses of chitin & chitosan in wastewater treatment

Proceeding, Yang SF et al, The Latest Applications of Chitin and Chitosan in Wastewater Treatment, 
In: Advanced Materials Research, Shi YX, Wan AJ (Eds.), 151-157, (2013)
   

Review - UV graft polymerization

Deng JP et al., Developments and new applications of UV-induced surface graft polymerizations.
Progress in Polymer Science, 34, (2), 156-193, (2009)
   

Review - vapor-phase sensors

Afzal A et al., Advanced vapor recognition materials for selective and fast responsive surface acoustic wave sensors: A review.
Analytica Chimica Acta, 787, 36-49, (2013)
   

Review - voltammetric sensing at modified electrodes

Chillawar RR et al., Voltammetric techniques at chemically modified electrodes.
Journal of Analytical Chemistry, 70, (4), 399-418, (2015)
   

Review - water analysis

Rickerby DG, Potental application of biosensor networks for monitoring aquatic sytems in support of the water framework directive.
Bollettino di Geofisica Teorica ed Applicata, 50, (4), 341-360, (2009)
   

Review - water treatment by MIPs

Book chapter, Kotrotsiou Oet al., Water Treatment by Molecularly Imprinted Materials, 
In: Nanoscale Materials in Water Purification, Thomas S, Pasquini D, Leu SY, Gopakumar DA (Eds.) Elsevier: 179-230, (2019)
   

Re(VII)

Xiong Y et al., Adsorption-controlled preparation of anionic imprinted amino-functionalization chitosan for recognizing rhenium(VII).
Separation and Purification Technology, 177, 142-151, (2017)
   

Re(VII)

Chen ZC et al., Structure, adsorption and separation comparison between the thermosensitive block segment polymer modified ReO4- ion imprinted polymer and traditional ReO4- ion imprinted polymer.
Reactive and Functional Polymers, 164, Article104929-(2021)
   

RF

He H et al., Controllably prepared molecularly imprinted core-shell plasmonic nanostructure for plasmon-enhanced fluorescence assay.
Biosensors and Bioelectronics, 146, Article111733-(2019)
   

(R)-Fc

Fireman-Shoresh S et al., Chiral electrochemical recognition by very thin molecularly imprinted sol-gel films.
Langmuir, 21, (17), 7842-7847, (2005)
   

RFP

Zhang CL et al., Synthesis of molecularly imprinted polymer for Rifampicin and its adsorption.
The Chinese Journal of Process Engineering, 9, (3), 608-612, (2009)
   

RFP

Zhang CL et al., Study on Recognition Mechanism of Molecularly Imprinted Microsphere Using Rifampicin as Template.
Journal of Henan University (Natural Science), 40, (5), 483-488, (2010)
   

Rg1

Hou SY et al., Multi-templates Molecularly Imprinted Polymer for the Specific Solid-Phase Extraction of Saponins from Panax notoginseng Herbal Extract.
Current Pharmaceutical Analysis, 11, (4), 292-299, (2015)
   

R6G

Li HJ et al., Preparation of a self-cleanable molecularly imprinted sensor based on surface-enhanced Raman spectroscopy for selective detection of R6G.
Analytical and Bioanalytical Chemistry, 409, (19), 4627-4635, (2017)
   

R6G

Li HJ et al., A high performance and highly-controllable core-shell imprinted sensor based on the surface-enhanced Raman scattering for detection of R6G in water.
Journal of Colloid and Interface Science, 501, 86-93, (2017)
   

R6G

Li HJ et al., Thermo-responsive molecularly imprinted sensor based on the surface-enhanced Raman scattering for selective detection of R6G in the water.
Dalton Transactions, 46, (34), 11282-11290, (2017)
   

Rg1

Sun CH et al., The Multi-Template Molecularly Imprinted Polymer Based on SBA-15 for Selective Separation and Determination of Panax notoginseng Saponins Simultaneously in Biological Samples.
Polymers, 9, (12), ArticleNo653-(2017)
   

R6G

Cui CF et al., Carbon-dot-encapsulated molecularly imprinted mesoporous organosilica for fluorescent sensing of rhodamine 6G.
Research on Chemical Intermediates, 44, (8), 4633-4640, (2018)
   

RGD

Papaioannou E et al., Molecularly imprinted polymers for RGD selective recognition and separation.
Amino Acids, 36, (3), 563-569, (2009)
   

RGD

Gupta N et al., A Highly Sensitive and Selective Piezoelectric Molecularly Imprinted Sensor for RGD Peptides.
Sensor Letters, 14, (6), 616-622, (2016)
   

RGD

Pan GQ et al., An Epitope-Imprinted Biointerface with Dynamic Bioactivity for Modulating Cell-Biomaterial Interactions.
Angewandte Chemie International Edition, 56, (50), 15959-15963, (2017)
   

RGDS peptide

Pan GQ et al., Thermo-Responsive Hydrogel Layers Imprinted with RGDS Peptide: A System for Harvesting Cell Sheets.
Angewandte Chemie International Edition, 52, (27), 6907-6911, (2013)
   

RH

Duan YQ et al., Selective Separation of Rhein by Molecular Imprinting Polymer and Solid-phase Extraction.
Chemistry and Industry of Forest Products, 29, (5), 35-40, (2009)
   

RH

Zhang XL et al., Determination of Ropivacaine Hydrochloride with Graphene Quantum Dots-Molecularly Imprinted Polymer Electrochemical Sensor.
Journal of Instrumental Analysis, 34, (2), 159-163, (2015)
   

rhaponticin

Chen FF et al., Magnetic molecularly imprinted polymer for the detection of rhaponticin in Chinese patent medicines.
Journal of Chromatography A, 1252, 8-14, (2012)
   

rhapontigenin

Chen FF et al., Preparation of magnetic molecularly imprinted polymer for selective recognition of resveratrol in wine.
Journal of Chromatography A, 1300, 112-118, (2013)
   

RhB

Ulbricht M et al., Insights into the mechanism of molecular imprinting by immersion precipitation phase inversion of polymer blends via a detailed morphology analysis of porous membranes.
Journal of Materials Chemistry, 15, (14), 1487-1497, (2005)
   

RhB

Liu RG et al., Effective removal of rhodamine B from contaminated water using non-covalent imprinted microspheres designed by computational approach.
Biosensors and Bioelectronics, 25, (3), 629-634, (2009)
   

RhB

Lei XL et al., Preparation of Rhodamine B Molecularly Imprinted Polymer Microspheres and Its Application in Solid Phase Extraction.
Chinese Journal of Applied Chemistry, 28, (5), 531-536, (2011)
   

RhB

Liu HQ et al., Electrospun Nanofiber Membranes Containing Molecularly Imprinted Polymer (MIP) for Rhodamine B (RhB).
Advances in Chemical Engineering and Science, 2, (2), 266-274, (2012)
   

RhB

Xu XZ et al., Surface molecular imprinting on polypropylene fibers for rhodamine B selective adsorption.
Journal of Colloid and Interface Science, 385, (1), 193-201, (2012)
   

RhB

Bao LL et al., Selective adsorption and degradation of rhodamine B with modified titanium dioxide photocatalyst.
Journal of Applied Polymer Science, 131, (20), Article No 40890-(2014)
   

RhB

He MQ et al., Synthesis of molecularly imprinted polypyrrole/titanium dioxide nanocomposites and its selective photocatalytic degradation of rhodamine B under visible light irradiation.
eXPRESS Polymer Letters, 8, (11), 850-861, (2014)
   

RhB

Ji SJ et al., Preparation and Adsorption Properties of Rhodamine B Molecularly Imprinted Polymers.
Food Science, 35, (6), 12-16, (2014)
   

RhB

Zhao C et al., Preparation and Fluorescence Microscopic Characterization of Surface Molecularly Imprinted Polymer of Rhodamine B.
Food Science, 35, (20), 236-241, (2014)
   

RhB

de Escobar CC et al., The sol-gel route effect on the preparation of molecularly imprinted silica-based materials for selective and competitive photocatalysis.
Colloids and Surfaces A: Physicochemical and Engineering Aspects, 486, 96-105, (2015)
   

RhB

Lu LL et al., Template-synthesized ultra-thin molecularly imprinted polymers membrane for the selective preconcentration of dyes.
Journal of Materials Chemistry A, 3, (20), 10959-10968, (2015)
   

RhB

Ge H et al., Preparation and Properties of Surface Imprinted Magnetic Cellulose Microsphere with Highly Selective Adsorption.
Chemical Journal of Chinese Universities, 37, (8), 1551-1558, (2016)
   

RhB

Liu Y et al., A convenient approach of MIP/Co-TiO2 nanocomposites with highly enhanced photocatalytic activity and selectivity under visible light irradiation.
RSC Advances, 6, (73), 69326-69333, (2016)
   

RhB

Long ZR et al., Nanosilica-based molecularly imprinted polymer nanoshell for specific recognition and determination of rhodamine B in red wine and beverages.
Journal of Chromatography B, 1029-1030, 230-238, (2016)
   

RhB

Li HY et al., Molecularly imprinted magnetic microparticles for the simultaneous detection and extraction of Rhodamine B.
Sensors and Actuators B: Chemical, 246, 286-292, (2017)
   

RhB

Liu JJ et al., Synthesis of molecularly imprinted polymer for strong adsorption of rhodamine B and the evaluation of its adsorption ability.
Journal of Food Safety and Quality, 8, (3), 958-962, (2017)
   

RhB

de Escobar CC et al., Effect of the amount and time of addition of a dye template on the adsorption and photocatalytic performance of molecularly imprinted silica.
Journal of Environmental Chemical Engineering, 6, (1), 190-196, (2018)
   

RhB

Arabi M et al., Hydrophilic molecularly imprinted nanospheres for the extraction of rhodamine B followed by HPLC analysis: A green approach and hazardous waste elimination.
Talanta, 215, Article120933-(2020)
   

RhB

Liu Y et al., Molecularly imprinted polymers hydrogel for the rapid risk-category-specific screening of food using SPE followed by fluorescence spectrometric detection.
Microchemical Journal, 159, Article105408-(2020)
   

RhB

Jahankhah S et al., Hydrophilic magnetic molecularly imprinted resin in PVDF membrane for efficient selective removal of dye.
Journal of Environmental Management, 300, Article113707-(2021)
   

rhein

Duan YQ et al., Selective Separation of Rhein by Molecular Imprinting Polymer and Solid-phase Extraction.
Chemistry and Industry of Forest Products, 29, (5), 35-40, (2009)
   

rhein

Fang YQ et al., Preparation and characterization of rhein molecularly imprinted polymeric microspheres.
Chinese Journal of Analysis Laboratory, 30, (12), 1-4, (2011)
   

rhein

Chen X et al., Novel molecularly imprinted polymers based on multiwalled carbon nanotubes with bifunctional monomers for solid-phase extraction of rhein from the root of kiwi fruit.
Journal of Separation Science, 35, (18), 2414-2421, (2012)
   

rhein

Liu YN et al., Preparation and Application of Rhein Magnetic Molecularly Imprinted Polymer.
Chemistry Bulletin, 75, (9), 842-847, (2012)
   

rhein

Yang CL et al., Synthesis and Properties of the Rhein Molecularly Imprinted Polymers.
Journal of Gansu Normal Colleges, (2), 33-36, (2013)
   

Rhenate ion

Chen ZC et al., Structure, adsorption and separation comparison between the thermosensitive block segment polymer modified ReO4- ion imprinted polymer and traditional ReO4- ion imprinted polymer.
Reactive and Functional Polymers, 164, Article104929-(2021)
   

rhenate ion

Zhao SY et al., Selective identification and separation of ReO4- by biomimetic flexible temperature-sensitive imprinted composite membranes.
Talanta, 235, Article122791-(2021)
   

rhenium ion

Xiong Y et al., Adsorption-controlled preparation of anionic imprinted amino-functionalization chitosan for recognizing rhenium(VII).
Separation and Purification Technology, 177, 142-151, (2017)
   

rhenium ions

Mamo SK et al., Computationally Designed Perrhenate Ion Imprinted Polymers for Selective Trapping of Rhenium Ions.
ACS Applied Polymer Materials, 2, (8), 3135-3147, (2020)
   

rhEPO

El-Aal MAA et al., Preparation and characterization of 96-well microplates coated with molecularly imprinted polymer for determination and biosimilarity assessment of recombinant human erythropoietin.
Journal of Chromatography A, 1641, Article462012-(2021)
   

rhEPO

Nadim AH et al., Facile imprinted polymer for label-free highly selective potentiometric sensing of proteins: case of recombinant human erythropoietin.
Analytical and Bioanalytical Chemistry, 413, (14), 3611-3623, (2021)
   

rhEPO

Nadim AH et al., Optimization of polydopamine imprinted polymer for label free sensitive potentiometric determination of proteins: Application to recombinant human erythropoietin sensing in different matrices.
Microchemical Journal, 167, Article106333-(2021)
   

Rh6G

Li YY et al., Aggregation-induced emission luminogen based molecularly imprinted ratiometric fluorescence sensor for the detection of Rhodamine 6G in food samples.
Food Chemistry, 287, 55-60, (2019)
   

Rh(III)

Zheng H et al., Highly selective determination of rhodium(III) using silica gel surface-imprinted solid-phase extraction.
International Journal of Environmental Analytical Chemistry, 91, (11), 1013-1023, (2011)
   

Rh(III)

Yang B et al., Determination of rhodium by resonance light-scattering technique coupled with solid phase extraction using Rh(III) ion-imprinted polymers as sorbent.
Talanta, 105, 124-130, (2013)
   

Rh(III)

Bai HP et al., Electrochemical Sensor Based on Rh(III) Ion-Imprinted Polymer as a New Modifying Agent for Rhodium Determination.
Journal of Nanoscience and Nanotechnology, 18, (5), 3577-3584, (2018)
   

rhodamine 123

Carrasco S et al., Cross-linkable linear copolymer with double functionality: resist for electron beam nanolithography and molecular imprinting.
Journal of Materials Chemistry C, 2, (8), 1400-1403, (2014)
   

rhodamine 123

Urraca JL et al., Molecular recognition with nanostructures fabricated by photopolymerization within metallic subwavelength apertures.
Nanoscale, 6, (15), 8656-8663, (2014)
   

rhodamine 123

Urraca JL et al., Magnetic Field-Induced Polymerization of Molecularly Imprinted Polymers.
The Journal of Physical Chemistry C, 122, (18), 10189-10196, (2018)
   

rhodamine B

Wang S et al., Studies on the molecular recognition and binding characteristics in rhodamine B molecularly imprinted polymer.
Journal of Lanzhou University (Natural Sciences), 39, (2), 57-60, (2003)
   

Rhodamine B

Ulbricht M et al., Insights into the mechanism of molecular imprinting by immersion precipitation phase inversion of polymer blends via a detailed morphology analysis of porous membranes.
Journal of Materials Chemistry, 15, (14), 1487-1497, (2005)
   

rhodamine B

Liu RG et al., Effective removal of rhodamine B from contaminated water using non-covalent imprinted microspheres designed by computational approach.
Biosensors and Bioelectronics, 25, (3), 629-634, (2009)
   

rhodamine B

Lei XL et al., Preparation of Rhodamine B Molecularly Imprinted Polymer Microspheres and Its Application in Solid Phase Extraction.
Chinese Journal of Applied Chemistry, 28, (5), 531-536, (2011)
   

Rhodamine B

Liu HQ et al., Electrospun Nanofiber Membranes Containing Molecularly Imprinted Polymer (MIP) for Rhodamine B (RhB).
Advances in Chemical Engineering and Science, 2, (2), 266-274, (2012)
   

rhodamine B

Xu XZ et al., Surface molecular imprinting on polypropylene fibers for rhodamine B selective adsorption.
Journal of Colloid and Interface Science, 385, (1), 193-201, (2012)
   

rhodamine B

Liu XY et al., Grafting of Molecularly Imprinted Polymers on to Carboxyl-Modified Multiwalled Carbon Nanotubes for the Extraction of Rhodamine B from Dried Chili Powder.
Analytical Letters, 46, (16), 2583-2596, (2013)
   

rhodamine B

Liu XY et al., Spectrometric Determination of Rhodamine B in Chili Powder After Molecularly Imprinted Solid Phase Extraction.
Bulletin of the Korean Chemical Society, 34, (11), 3381-3386, (2013)
   

rhodamine B

Bao LL et al., Selective adsorption and degradation of rhodamine B with modified titanium dioxide photocatalyst.
Journal of Applied Polymer Science, 131, (20), Article No 40890-(2014)
   

rhodamine B

de Coelho Escobar C et al., Effect of the sol-gel route on the textural characteristics of silica imprinted with Rhodamine B.
Journal of Separation Science, 37, (7), 868-875, (2014)
   

Rhodamine B

Proceeding, Escobar CE et al, The effect of the imprinted silicas prepared by sol-gel route on adsoption of rhodamine B: Textural and structural aspects, 
(2014)
   

rhodamine B

He MQ et al., Synthesis of molecularly imprinted polypyrrole/titanium dioxide nanocomposites and its selective photocatalytic degradation of rhodamine B under visible light irradiation.
eXPRESS Polymer Letters, 8, (11), 850-861, (2014)
   

rhodamine B

Ji SJ et al., Preparation and Adsorption Properties of Rhodamine B Molecularly Imprinted Polymers.
Food Science, 35, (6), 12-16, (2014)
   

rhodamine B

Liu XY et al., Preparation of a magnetic molecularly imprinted polymer for selective recognition of rhodamine B.
Applied Surface Science, 320, 138-145, (2014)
   

rhodamine B

Long ZR et al., Selective recognition and discrimination of water-soluble azo dyes by a seven-channel molecularly imprinted polymer sensor array.
Journal of Separation Science, 37, (19), 2764-2770, (2014)
   

Rhodamine B

Proceeding, Xuan GS et al, A New Molecularly Imprinted Polymer Prepared by Surface Imprinting Technique for Selective Adsorption towards Rhodamine B, 
In: Advanced Materials Research, Zhao XSG, Si HZ, Xu PL (Eds.), 19-22, (2014)
   

rhodamine B

Zhao C et al., Preparation and Fluorescence Microscopic Characterization of Surface Molecularly Imprinted Polymer of Rhodamine B.
Food Science, 35, (20), 236-241, (2014)
   

rhodamine B

Chen SN et al., Synthesis of surface-imprinted Ag nanoplates for detecting organic pollutants in water environments based on surface enhanced Raman scattering.
RSC Advances, 5, (121), 99914-99919, (2015)
   

rhodamine B

de Escobar CC et al., The sol-gel route effect on the preparation of molecularly imprinted silica-based materials for selective and competitive photocatalysis.
Colloids and Surfaces A: Physicochemical and Engineering Aspects, 486, 96-105, (2015)
   

rhodamine B

de Escobar CC et al., Effect of a Sol-Gel Route on the Preparation of Silica-Based Sorbent Materials Synthesized by Molecular Imprinting for the Adsorption of Dyes.
Industrial & Engineering Chemistry Research, 54, (1), 254-262, (2015)
   

Rhodamine B

Lu LL et al., Template-synthesized ultra-thin molecularly imprinted polymers membrane for the selective preconcentration of dyes.
Journal of Materials Chemistry A, 3, (20), 10959-10968, (2015)
   

Rhodamine B

Su XM et al., Synthesis and characterization of core-shell magnetic molecularly imprinted polymers for solid-phase extraction and determination of Rhodamine B in food.
Food Chemistry, 171, 292-297, (2015)
   

Rhodamine B

Carboni D et al., Improving the Selective Efficiency of Graphene-Mediated Enhanced Raman Scattering through Molecular Imprinting.
ACS Applied Materials & Interfaces, 8, (49), 34098-34107, (2016)
   

Rhodamine B

Ge H et al., Preparation and Properties of Surface Imprinted Magnetic Cellulose Microsphere with Highly Selective Adsorption.
Chemical Journal of Chinese Universities, 37, (8), 1551-1558, (2016)
   

rhodamine B

Liu Y et al., A convenient approach of MIP/Co-TiO2 nanocomposites with highly enhanced photocatalytic activity and selectivity under visible light irradiation.
RSC Advances, 6, (73), 69326-69333, (2016)
   

rhodamine B

Long ZR et al., Nanosilica-based molecularly imprinted polymer nanoshell for specific recognition and determination of rhodamine B in red wine and beverages.
Journal of Chromatography B, 1029-1030, 230-238, (2016)
   

rhodamine B

Li HY et al., Molecularly imprinted magnetic microparticles for the simultaneous detection and extraction of Rhodamine B.
Sensors and Actuators B: Chemical, 246, 286-292, (2017)
   

rhodamine B

Liu JJ et al., Synthesis of molecularly imprinted polymer for strong adsorption of rhodamine B and the evaluation of its adsorption ability.
Journal of Food Safety and Quality, 8, (3), 958-962, (2017)
   

rhodamine B

Long ZR et al., Highly selective coextraction of rhodamine B and dibenzyl phthalate based on high-density dual-template imprinted shells on silica microparticles.
Journal of Separation Science, 40, (2), 506-513, (2017)
   

rhodamine B

Zhai HY et al., Chip-based molecularly imprinted monolithic capillary array columns coated GO/SiO2 for selective extraction and sensitive determination of rhodamine B in chili powder.
Food Chemistry, 214, 664-669, (2017)
   

Rhodamine B

de Escobar CC et al., Effect of the amount and time of addition of a dye template on the adsorption and photocatalytic performance of molecularly imprinted silica.
Journal of Environmental Chemical Engineering, 6, (1), 190-196, (2018)
   

Rhodamine B

Bagheri AR et al., Synthesis of chitosan based molecularly imprinted polymer for pipette-tip solid phase extraction of Rhodamine B from chili powder samples.
International Journal of Biological Macromolecules, 139, 40-48, (2019)
   

rhodamine B

Hashemi SH et al., Application of response surface methodology to optimize pipette tip micro-solid phase extraction of dyes from seawater by molecularly imprinted polymer and their determination by HPLC.
Journal of the Iranian Chemical Society, 16, (12), 2613-2627, (2019)
   

rhodamine B

Arabi M et al., Hydrophilic molecularly imprinted nanospheres for the extraction of rhodamine B followed by HPLC analysis: A green approach and hazardous waste elimination.
Talanta, 215, Article120933-(2020)
   

rhodamine B

Liu Y et al., Molecularly imprinted polymers hydrogel for the rapid risk-category-specific screening of food using SPE followed by fluorescence spectrometric detection.
Microchemical Journal, 159, Article105408-(2020)
   

Rhodamine B

Jahankhah S et al., Hydrophilic magnetic molecularly imprinted resin in PVDF membrane for efficient selective removal of dye.
Journal of Environmental Management, 300, Article113707-(2021)
   

rhodamine 6G

Zheng H et al., Studies on the Molecular Recognition and Binding Characteristics in Rhodamine 6G MoLecularly Imprinted Polymer.
Journal of Qinghai Normal University (Natural Science Edition), (2), 72-75, (2006)
   

Rhodamine 6G

Su XM et al., Preparation and Adsorption Performance of Core-Shell Magnetic Molecularly Imprinted Polymer Microspheres for Solid Phase Extraction and Detection of Rhodamine 6G in Foods.
Food Science, 35, (24), 9-14, (2014)
   

Rhodamine 6G

Su XM et al., Synthesis and characterization of core-shell magnetic molecularly imprinted polymers for solid-phase extraction of Rhodamine 6G.
Journal of Functional Materials, 45, (23), 23080-23085+23090, (2014)
   

Rhodamine 6G

Guo Y et al., High performance surface-enhanced Raman scattering from molecular imprinting polymer capsulated silver spheres.
Physical Chemistry Chemical Physics, 17, (33), 21343-21347, (2015)
   

rhodamine 6G

Xie J et al., Computational design and fabrication of core-shell magnetic molecularly imprinted polymer for dispersive micro-solid-phase extraction coupled with high-performance liquid chromatography for the determination of rhodamine 6G.
Journal of Separation Science, 39, (12), 2422-2430, (2016)
   

rhodamine 6G

Li HJ et al., Preparation of a self-cleanable molecularly imprinted sensor based on surface-enhanced Raman spectroscopy for selective detection of R6G.
Analytical and Bioanalytical Chemistry, 409, (19), 4627-4635, (2017)
   

rhodamine 6G

Li HJ et al., A high performance and highly-controllable core-shell imprinted sensor based on the surface-enhanced Raman scattering for detection of R6G in water.
Journal of Colloid and Interface Science, 501, 86-93, (2017)
   

rhodamine 6G

Li HJ et al., Thermo-responsive molecularly imprinted sensor based on the surface-enhanced Raman scattering for selective detection of R6G in the water.
Dalton Transactions, 46, (34), 11282-11290, (2017)
   

rhodamine 6G

Cui CF et al., Carbon-dot-encapsulated molecularly imprinted mesoporous organosilica for fluorescent sensing of rhodamine 6G.
Research on Chemical Intermediates, 44, (8), 4633-4640, (2018)
   

rhodamine 6G

Jiang Y et al., Graphene Oxide-Silver Nanoparticles in Molecularly-Imprinted Hybrid Films Enabling SERS Selective Sensing.
Materials, 11, (9), ArticleNo1674-(2018)
   

rhodamine 6G

Li YY et al., Aggregation-induced emission luminogen based molecularly imprinted ratiometric fluorescence sensor for the detection of Rhodamine 6G in food samples.
Food Chemistry, 287, 55-60, (2019)
   

rhodium ion

Zheng H et al., Highly selective determination of rhodium(III) using silica gel surface-imprinted solid-phase extraction.
International Journal of Environmental Analytical Chemistry, 91, (11), 1013-1023, (2011)
   

rhodium ion

Yang B et al., Determination of rhodium by resonance light-scattering technique coupled with solid phase extraction using Rh(III) ion-imprinted polymers as sorbent.
Talanta, 105, 124-130, (2013)
   

rhodium ion

Bai HP et al., Electrochemical Sensor Based on Rh(III) Ion-Imprinted Polymer as a New Modifying Agent for Rhodium Determination.
Journal of Nanoscience and Nanotechnology, 18, (5), 3577-3584, (2018)
   

rhodizonic acid

Derz W et al., Guiding Molecularly Imprinted Polymer Design by Pharmacophore Modeling.
Molecules, 26, (16), ArticleNo5101-(2021)
   

Rhodobacter sphaeroide

Lee MH et al., Fabrication of Bacteria-imprinted Polymer Coated Electrodes for Microbial Fuel Cells.
ACS Sustainable Chemistry & Engineering, 3, (6), 1190-1196, (2015)
   

Rhodobacter sphaeroides

Lee MH et al., Recognition of Rhodobacter sphaeroides by microcontact-imprinted poly(ethylene-co-vinyl alcohol).
Colloids and Surfaces B: Biointerfaces, 135, 394-399, (2015)
   

Rib

Takeuchi T et al., Protein profiling by protein imprinted polymer array.
Analyst, 132, (2), 101-103, (2007)
   

ribavirin

Xu L et al., Molecularly imprinted polymer based on multiwalled carbon nanotubes for ribavirin recognition.
Journal of Polymer Research, 19, (8), 1-6, (2012)
   

ribavirin

Ma JK et al., Rapid determination of antiviral medication ribavirin in different feedstuffs using a novel magnetic molecularly imprinted polymer coupled with high-performance liquid chromatography.
Journal of Separation Science, 42, (21), 3372-3381, (2019)
   

ribavirin

Chen MN et al., Design of self-cleaning molecularly imprinted membrane with antibacterial ability for high-selectively separation of ribavirin.
Journal of Membrane Science, 642, Article119994-(2022)
   

riboflavin

Manesiotis P et al., An artificial riboflavin receptor prepared by a template analogue imprinting strategy.
Angewandte Chemie International Edition, 44, (25), 3902-3906, (2005)
   

riboflavin

Manesiotis P et al., Water-compatible imprinted polymers for selective depletion of riboflavine from beverages.
Journal of Materials Chemistry, 19, (33), 6185-6193, (2009)
   

riboflavin

Oliveira HM et al., Exploiting automatic on-line renewable molecularly imprinted solid-phase extraction in lab-on-valve format as front end to liquid chromatography: application to the determination of riboflavin in foodstuffs.
Analytical and Bioanalytical Chemistry, 397, (1), 77-86, (2010)
   

riboflavin

Borrelli C et al., Selective Depletion of Riboflavine from Beer Using Membranes Incorporating Imprinted Polymer Particles.
Journal of Food Processing and Preservation, 35, (1), 112-128, (2011)
   

riboflavin

Proceeding, Verma R et al, Surface plasmon resonance based optical fiber riboflavin sensor by using molecularly imprinted gel, 
Jaroszewicz LR (Ed.), Art No 87941D, (2013)
   

riboflavin

Osório MV et al., Fluorometric method based on molecular recognition solid-phase extraction for determination of riboflavin in milk and infant formula.
Journal of Food Composition and Analysis, 45, 141-146, (2016)
   

riboflavin

Li DJ et al., Efficient synthesis of riboflavin-imprinted magnetic nanoparticles by boronate affinity-based surface imprinting for the selective recognition of riboflavin.
Analyst, 143, (20), 4936-4943, (2018)
   

riboflavin

Ostovan A et al., Hydrophilic Multitemplate Molecularly Imprinted Biopolymers Based on a Green Synthesis Strategy for Determination of B-Family Vitamins.
ACS Applied Materials & Interfaces, 10, (4), 4140-4150, (2018)
   

riboflavin

Zhang ZX et al., A highly-sensitive VB2 electrochemical sensor based on one-step co-electrodeposited molecularly imprinted WS2-PEDOT film supported on graphene oxide-SWCNTs nanocomposite.
Materials Science and Engineering: C, 92, 77-87, (2018)
   

riboflavin

He H et al., Controllably prepared molecularly imprinted core-shell plasmonic nanostructure for plasmon-enhanced fluorescence assay.
Biosensors and Bioelectronics, 146, Article111733-(2019)
   

riboflavin

Mokhtari P et al., Water compatible molecularly imprinted polymer for controlled release of riboflavin as drug delivery system.
European Polymer Journal, 118, 614-618, (2019)
   

riboflavin tetraacetate

Manesiotis P et al., Water-compatible imprinted polymers for selective depletion of riboflavine from beverages.
Journal of Materials Chemistry, 19, (33), 6185-6193, (2009)
   

ribonuclease

Hjertén S et al., Gels mimicking antibodies in their selective recognition of proteins.
Chromatographia, 44, (5-6), 227-234, (1997)
   

ribonuclease

Shi HQ et al., Template-imprinted nanostructured surfaces for protein recognition.
Nature, 398, (6728), 593-597, (1999)
   

ribonuclease

Proceeding, Chou TC et al, Nanocavity protein biosensor - Fabricated by molecular imprinting, 
16-20, (2007)
   

ribonuclease

Book chapter, Sedzik Jet al., Gels Mimicking Antibodies in Their Selective Recognition of Proteins and Its Potential Use for Protein Crystallization, 
In: Molecules: Nucleation, Aggregation And Crystallization, Sedzik J, Riccio P (Eds.) World Scientific: 11-34, (2009)
   

ribonuclease

Feng XT et al., Molecularly imprinted nanoparticles for inhibiting ribonuclease in reverse transcriptase polymerase chain reaction.
Analyst, 143, (12), 2750-2754, (2018)
   

ribonuclease A

Proceeding, Hsu CY et al, The recognition of ribonuclease A by molecularly imprinted polymers, 
Abstract 1461, (2005)
   

Ribonuclease A

Hsu CY et al., Incorporation of styrene enhances recognition of ribonuclease A by molecularly imprinted polymers.
Biosensors and Bioelectronics, 22, (3), 355-363, (2006)
   

Ribonuclease A

Hsu CY et al., Synthesis of and recognition by ribonuclease A imprinted polymers.
Nanotechnology, 17, (4), S77-S83, (2006)
   

Ribonuclease A

Proceeding, Jin TC et al, Preparation of Ribonuclease A surface-imprinted nanoparticles with miniemulsion polymerization for protein recognition in aqueous media, 
(2006)
   

ribonuclease A

Lin HY et al., The microcontact imprinting of proteins: The effect of cross-linking monomers for lysozyme, ribonuclease A and myoglobin.
Biosensors and Bioelectronics, 22, (4), 534-543, (2006)
   

Ribonuclease A

Proceeding, Jin TC et al, Investigation of protein imprinting using miniemulsion polymerization through the epitope approach, 
(2007)
   

ribonuclease A

Takeuchi T et al., Protein profiling by protein imprinted polymer array.
Analyst, 132, (2), 101-103, (2007)
   

ribonuclease A

Tan CJ et al., Preparation of Superparamagnetic Ribonuclease A Surface-Imprinted Submicrometer Particles for Protein Recognition in Aqueous Media.
Analytical Chemistry, 79, (1), 299-306, (2007)
   

ribonuclease A

Tan CJ et al., The Effect of Protein Structural Conformation on Nanoparticle Molecular Imprinting of Ribonuclease A Using Miniemulsion Polymerization.
Langmuir, 23, (5), 2722-2730, (2007)
   

ribonuclease A

Tan CJ et al., Response to Comment on "Preparation of Superparamagnetic Ribonuclease A Surface-Imprinted Submicrometer Particles for Protein Recognition in Aqueous Media".
Analytical Chemistry, 80, (23), 9375-9376, (2008)
   

ribonuclease A

Inoue J et al., Protein imprinted TiO2-coated quantum dots for fluorescent protein sensing prepared by liquid phase deposition.
Soft Matter, 7, (20), 9681-9684, (2011)
   

ribonuclease A

Liu S et al., Construction of a novel macroporous imprinted biosensor based on quartz crystal microbalance for ribonuclease A detection.
Biosensors and Bioelectronics, 42, 80-86, (2013)
   

Ribonuclease A

Sankarakumar N et al., Protein adsorption behavior in batch and competitive conditions with nanoparticle surface imprinting.
RSC Advances, 3, (5), 1519-1527, (2013)
   

Ribonuclease A

Duan HM et al., Biorecognition and highly sensitive determination of Ribonuclease A with chemiluminescence sensor based on Fe3O4/multi-walled carbon nanotubes/SiO2-surface molecular imprinting polymer.
RSC Advances, 5, (24), 18850-18857, (2015)
   

ribonuclease A

Kuwata T et al., Molecularly Imprinted Polymer Arrays as Synthetic Protein Chips Prepared by Transcription-type Molecular Imprinting by Use of Protein-Immobilized Dots as Stamps.
Analytical Chemistry, 87, (23), 11784-11791, (2015)
   

ribonuclease A

Sasaki S et al., Molecularly imprinted protein recognition thin films constructed by controlled/living radical polymerization.
Journal of Bioscience and Bioengineering, 119, (2), 200-205, (2015)
   

ribonuclease B

Li L et al., Photolithographic Boronate Affinity Molecular Imprinting: A General and Facile Approach for Glycoprotein Imprinting.
Angewandte Chemie International Edition, 52, (29), 7451-7454, (2013)
   

ribonuclease B

Wu G et al., Template size matched film thickness for effectively in situ surface imprinting: a model study of glycoprotein imprints.
RSC Advances, 5, (58), 47010-47021, (2015)
   

ribonuclease B

Wang H et al., Boronate affinity molecularly imprinted inverse opal particles for multiple label-free bioassays.
Chemical Communications, 52, (16), 3296-3299, (2016)
   

ribonuclease B

Gao CM et al., Engineering anatase hierarchically cactus-like TiO2 arrays for photoelectrochemical and visualized sensing platform.
Biosensors and Bioelectronics, 90, 336-342, (2017)
   

ribonulease A

Lee K et al., Protein-imprinted polysiloxane scaffolds.
Acta Biomaterialia, 3, (4), 515-522, (2007)
   

ribosome

King HA et al., Generation of ribosome imprinted polymers for sensitive detection of translational responses.
Scientific Reports, 7, (1), ArticleNo6542-(2017)
   

R-ibuprofen

Dai WG et al., Selective Photoelectrochemical Oxidation of Chiral Ibuprofen Enantiomers.
Acta Physico-Chimica Sinica, 33, (5), 960-967, (2017)
   

ricin

Pradhan S et al., Molecularly imprinted nanopatterns for the recognition of biological warfare agent ricin.
Biosensors and Bioelectronics, 25, (3), 592-598, (2009)
   

ricin toxin chain A

Komarova E et al., Design of molecularly imprinted conducting polymer protein-sensing films via substrate-dopant binding.
Analyst, 140, (4), 1099-1106, (2015)
   

RIF

Rawool CR et al., A dual template imprinted polymer modified electrochemical sensor based on Cu metal organic framework/mesoporous carbon for highly sensitive and selective recognition of rifampicin and isoniazid.
Sensors and Actuators B: Chemical, 288, 493-506, (2019)
   

Rifampicin

Zhang CL et al., Synthesis of molecularly imprinted polymer for Rifampicin and its adsorption.
The Chinese Journal of Process Engineering, 9, (3), 608-612, (2009)
   

rifampicin

Zhang CL et al., Study on Recognition Mechanism of Molecularly Imprinted Microsphere Using Rifampicin as Template.
Journal of Henan University (Natural Science), 40, (5), 483-488, (2010)
   

rifampicin

Juric D et al., Molecular Imprinting of Cyclodextrin Supramolecular Hydrogels Improves Drug Loading and Delivery.
Macromolecular Bioscience, 19, (1), Article1800246-(2019)
   

rifampicin

Rawool CR et al., A dual template imprinted polymer modified electrochemical sensor based on Cu metal organic framework/mesoporous carbon for highly sensitive and selective recognition of rifampicin and isoniazid.
Sensors and Actuators B: Chemical, 288, 493-506, (2019)
   

R-IgG

Mohapatra S et al., Fabrication of flexible and economical plasmonic biosensor using gold nanograting imprinted on hot-melt adhesive film for label-free sensing of immunoglobulin proteins.
Sensors and Actuators B: Chemical, 301, Article127070-(2019)
   

rimantadine

Zhang T et al., Preparation of a molecularly imprinted polymer based chemiluminescence sensor for the determination of amantadine and rimantadine in meat.
Analytical Methods, 10, (41), 5025-5031, (2018)
   

rimantadine

Zhang T et al., Development of a molecularly imprinted microspheres-based microplate fluorescence method for detection of amantadine and rimantadine in chicken.
Food Additives & Contaminants: Part A, 38, (7), 1136-1147, (2021)
   

Ris

Abdulla NI et al., Potentiometric Transducers for the Selective Recognition of Risperidone Based on Molecularly Imprinted Polymer.
Iraqi Journal of Pharmaceutical Science, 24, (2), 30-40, (2015)
   

risperidone

Asadi E et al., Synthesis, recognition and evaluation of molecularly imprinted polymer nanoparticle using miniemulsion polymerization for controlled release and analysis of risperidone in human plasma samples.
Korean Journal of Chemical Engineering, 31, (6), 1028-1035, (2014)
   

risperidone

Abdulla NI et al., Potentiometric Transducers for the Selective Recognition of Risperidone Based on Molecularly Imprinted Polymer.
Iraqi Journal of Pharmaceutical Science, 24, (2), 30-40, (2015)
   

risperidone

Ji WH et al., A water-compatible magnetic molecularly imprinted polymer for the selective extraction of risperidone and 9-hydroxyrisperidone from human urine.
Talanta, 181, 392-400, (2018)
   

RIT

Wang PL et al., Synthesis of ractopamine molecularly imprinted membrane and its application in the rapid determination of three β-agonists in porcine urine samples.
Journal of Separation Science, 36, (8), 1455-1462, (2013)
   

RIT

Lei RL et al., A Novel Electrochemical Sensor for β2-Agonists with High Sensitivity and Selectivity Based on Surface Molecularly Imprinted Sol-gel Doped with Antimony-Doped Tin Oxide.
Electroanalysis, 26, (5), 1004-1012, (2014)
   

RIT

Ma M et al., A disposable molecularly imprinted electrochemical sensor based on screen-printed electrode modified with ordered mesoporous carbon and gold nanoparticles for determination of ractopamine.
Journal of Electroanalytical Chemistry, 775, 171-178, (2016)
   

RITO

Wang PL et al., Determination of β2-Agonists in Porcine Urine by Molecularly Imprinted Solid Phase Extraction Followed Ultra-Performance Liquid Chromatography-Tandem Mass Spectrometry Detection.
Analytical Letters, 46, (5), 734-744, (2013)
   

ritodrine

Wang PL et al., Determination of β2-Agonists in Porcine Urine by Molecularly Imprinted Solid Phase Extraction Followed Ultra-Performance Liquid Chromatography-Tandem Mass Spectrometry Detection.
Analytical Letters, 46, (5), 734-744, (2013)
   

ritodrine

Xiao XH et al., Rapid analysis of ractopamine in pig tissues by dummy-template imprinted solid-phase extraction coupling with surface-enhanced Raman spectroscopy.
Talanta, 138, 40-45, (2015)
   

ritodrine

Ma M et al., A disposable molecularly imprinted electrochemical sensor based on screen-printed electrode modified with ordered mesoporous carbon and gold nanoparticles for determination of ractopamine.
Journal of Electroanalytical Chemistry, 775, 171-178, (2016)
   

Ritodrine hydrochloride

Xu W et al., Electrochemical sensor based on a carbon nanotube-modified imprinted sol-gel for selective and sensitive determination of β2-agonists.
Microchimica Acta, 180, (11-12), 1005-1011, (2013)
   

ritodrine hydrochloride

Lei RL et al., A Novel Electrochemical Sensor for β2-Agonists with High Sensitivity and Selectivity Based on Surface Molecularly Imprinted Sol-gel Doped with Antimony-Doped Tin Oxide.
Electroanalysis, 26, (5), 1004-1012, (2014)
   

RIV

Arvand M et al., Voltammetric determination of rivastigmine in pharmaceutical and biological samples using molecularly imprinted polymer modified carbon paste electrode.
Sensors and Actuators B: Chemical, 188, 797-805, (2013)
   

RIV

Hemmati K et al., Synthesis and characterization of a novel magnetic molecularly imprinted polymer with incorporated graphene oxide for drug delivery.
Polymer, 101, 257-268, (2016)
   

rivastigmine

Arvand M et al., Man-Tailored Biomimetic Sensor of Molecularly Imprinted Materials for the Potentiometric Measurement of Rivastigmine in Tablets and Biological Fluids and Employing the Taguchi Optimization Methodology to Optimize the MIP-Based Membranes.
Electroanalysis, 24, (9), 1852-1863, (2012)
   

rivastigmine

Arvand M et al., Voltammetric determination of rivastigmine in pharmaceutical and biological samples using molecularly imprinted polymer modified carbon paste electrode.
Sensors and Actuators B: Chemical, 188, 797-805, (2013)
   

rivastigmine

Hemmati K et al., Synthesis and characterization of a novel magnetic molecularly imprinted polymer with incorporated graphene oxide for drug delivery.
Polymer, 101, 257-268, (2016)
   

rizatriptan

Soleimani M et al., Magnetic solid phase extraction of rizatriptan in human urine samples prior to its spectrofluorimetric determination.
Sensors and Actuators B: Chemical, 254, 1225-1233, (2018)
   

RM

Proceeding, Yu JY et al, Molecularly imprinted polymer microspheres prepared by precipitation polymerization for the binding and recognition of roxithromycin, 
Art. No. 5515319, (2010)
   

(R)-(-)-mandelic acid

Ramström O et al., Recognition sites incorporating both pyridinyl and carboxy functionalities prepared by molecular imprinting.
Journal of Organic Chemistry, 58, (26), 7562-7564, (1993)
   

R-mandelic acid

Bai LH et al., Chiral separation of racemic mandelic acids by use of an ionic liquid-mediated imprinted monolith with a metal ion as self-assembly pivot.
Analytical and Bioanalytical Chemistry, 405, (27), 8935-8943, (2013)
   

(R)-mandelic acid

Gao BJ et al., Preparation of surface imprinted material of single enantiomer of mandelic acid with a new surface imprinting technique and study on its chiral recognition and resolution properties.
Journal of Chromatography A, 1443, 10-20, (2016)
   

R-methamphetamine-sulfonamide phenolic derivative

Alatawi RAS et al., Chiral separation of (±)-methamphetamine racemate using molecularly imprinted sulfonic acid functionalized resin.
Journal of Colloid and Interface Science, 531, 654-663, (2018)
   

R-methylbenzylamine

Greene NT et al., Colorimetric molecularly imprinted polymer sensor array using dye displacement.
Journal of the American Chemical Society, 127, (15), 5695-5700, (2005)
   

(R)-α-methylbenzylamine

Binet C et al., Benefit of liquid crystal moieties in the MIP technique.
Analytica Chimica Acta, 591, (1), 1-6, (2007)
   

(R)-methylbenzylamine

Palaprat G et al., Enantioselective Absorption of Chirally Doped Liquid Crystalline Networks Studied by the Use of an Electronic Microbalance.
Journal of Physical Chemistry B, 111, (31), 9239-9243, (2007)
   

RNAase A

Proceeding, Jin TC et al, Investigation of protein imprinting using miniemulsion polymerization through the epitope approach, 
(2007)
   

R-1-(1-naphthyl) ethylamine

Zhou J et al., Enantiomeric recognition of continuous molecularly imprinted polymer rod prepared by in-situ method.
Chinese Journal of Analytical Chemistry, 28, (3), 296-299, (2000)
   

RNA polymerase

Bossi A et al., Patterned gallium surfaces as molecular mirrors.
Biosensors and Bioelectronics, 23, (2), 290-294, (2007)
   

RNas A

Duan HM et al., Biorecognition and highly sensitive determination of Ribonuclease A with chemiluminescence sensor based on Fe3O4/multi-walled carbon nanotubes/SiO2-surface molecular imprinting polymer.
RSC Advances, 5, (24), 18850-18857, (2015)
   

RNase

Hsu CY et al., Synthesis of and recognition by ribonuclease A imprinted polymers.
Nanotechnology, 17, (4), S77-S83, (2006)
   

RNase

Inoue J et al., Protein imprinted TiO2-coated quantum dots for fluorescent protein sensing prepared by liquid phase deposition.
Soft Matter, 7, (20), 9681-9684, (2011)
   

RNase

Sasaki S et al., Molecularly imprinted protein recognition thin films constructed by controlled/living radical polymerization.
Journal of Bioscience and Bioengineering, 119, (2), 200-205, (2015)
   

RNase

Feng XT et al., Molecularly imprinted nanoparticles for inhibiting ribonuclease in reverse transcriptase polymerase chain reaction.
Analyst, 143, (12), 2750-2754, (2018)
   

RNase A

Hishiya T et al., Protein-imprinted polymers by using metal complexes.
Polymer Preprints, Japan, 55, (2), 5006-5007, (2006)
   

RNase A

Hsu CY et al., Incorporation of styrene enhances recognition of ribonuclease A by molecularly imprinted polymers.
Biosensors and Bioelectronics, 22, (3), 355-363, (2006)
   

RNase A

Lee K et al., Protein-imprinted polysiloxane scaffolds.
Acta Biomaterialia, 3, (4), 515-522, (2007)
   

RNase A

Tan CJ et al., The Effect of Protein Structural Conformation on Nanoparticle Molecular Imprinting of Ribonuclease A Using Miniemulsion Polymerization.
Langmuir, 23, (5), 2722-2730, (2007)
   

RNase A

Gao RX et al., Preparation and characterization of uniformly sized molecularly imprinted polymers functionalized with core-shell magnetic nanoparticles for the recognition and enrichment of protein.
Journal of Materials Chemistry, 21, (44), 17863-17871, (2011)
   

RNase A

Sankarakumar N et al., Protein adsorption behavior in batch and competitive conditions with nanoparticle surface imprinting.
RSC Advances, 3, (5), 1519-1527, (2013)
   

RNase A

Xu JJ et al., Toward a Universal Method for Preparing Molecularly Imprinted Polymer Nanoparticles with Antibody-like Affinity for Proteins.
Biomacromolecules, 17, (1), 345-353, (2016)
   

RNase B

Li L et al., Photolithographic Boronate Affinity Molecular Imprinting: A General and Facile Approach for Glycoprotein Imprinting.
Angewandte Chemie International Edition, 52, (29), 7451-7454, (2013)
   

RNaseB

Wu G et al., Template size matched film thickness for effectively in situ surface imprinting: a model study of glycoprotein imprints.
RSC Advances, 5, (58), 47010-47021, (2015)
   

RNase B

Wang H et al., Boronate affinity molecularly imprinted inverse opal particles for multiple label-free bioassays.
Chemical Communications, 52, (16), 3296-3299, (2016)
   

RNase B

Gao CM et al., Engineering anatase hierarchically cactus-like TiO2 arrays for photoelectrochemical and visualized sensing platform.
Biosensors and Bioelectronics, 90, 336-342, (2017)
   

RNase B

Ma YY et al., Glycan-Imprinted Magnetic Nanoparticle-Based SELEX for Efficient Screening of Glycoprotein-Binding Aptamers.
ACS Applied Materials & Interfaces, 10, (47), 40918-40926, (2018)
   

(R)-N,N’-dimethylferrocenylethylamine

Fireman-Shoresh S et al., Chiral electrochemical recognition by very thin molecularly imprinted sol-gel films.
Langmuir, 21, (17), 7842-7847, (2005)
   

RNZ

Mohamed R et al., Use of Molecularly Imprinted Solid-Phase Extraction Sorbent for the Determination of Four 5-Nitroimidazoles and Three of Their Metabolites from Egg-Based Samples before Tandem LC-ESIMS/MS Analysis.
Journal of Agricultural and Food Chemistry, 56, (10), 3500-3508, (2008)
   

RNZ

Shimelis O et al., Extraction of Nitroimidazoles from Milk and Eggs using Molecularly Imprinted Polymers.
The Reporter, 27, (4), 15-17, (2010)
   

RNZ

Zhao HQ et al., Aluminum Doped Surface Imprinted Polymer Modified Electrode for Determination of Ronidazole Residue in Food.
Journal of Instrumental Analysis, 35, (8), 993-998, (2016)
   

RNZ

Guo XC et al., Molecularly imprinted solid phase extraction method for simultaneous determination of seven nitroimidazoles from honey by HPLC-MS/MS.
Talanta, 166, 101-108, (2017)
   

RNZ

Bustamante-Rangel M et al., Evaluation of the selectivity of molecularly imprinted polymer cartridges for nitroimidazoles. Application to the simultaneous extraction of nitroimidazoles and benzimidazoles from samples of animal origin.
Microchemical Journal, 172, Article107000-(2022)
   

(R)-1-(o-fluorophenyl)ethanol

Weng ZH et al., Preparation of surface molecularly imprinted Ru-complex catalysts for asymmetric transfer hydrogenation in water media.
Dalton Transactions, 40, (10), 2338-2347, (2011)
   

ronidazole

Mohamed R et al., Use of Molecularly Imprinted Solid-Phase Extraction Sorbent for the Determination of Four 5-Nitroimidazoles and Three of Their Metabolites from Egg-Based Samples before Tandem LC-ESIMS/MS Analysis.
Journal of Agricultural and Food Chemistry, 56, (10), 3500-3508, (2008)
   

ronidazole

Liao SL et al., Preparation and characterization of a molecularly imprinted monolithic column for pressure-assisted CEC separation of nitroimidazole drugs.
Electrophoresis, 31, (16), 2822-2830, (2010)
   

Ronidazole

Shimelis O et al., Extraction of Nitroimidazoles from Milk and Eggs using Molecularly Imprinted Polymers.
The Reporter, 27, (4), 15-17, (2010)
   

ronidazole

Mitrowska K et al., Selective Determination of Fourteen Nitroimidazoles in Honey by High-Performance Liquid Chromatography-Tandem Mass Spectrometry.
Analytical Letters, 47, (10), 1634-1649, (2014)
   

ronidazole

Zhao HQ et al., Aluminum Doped Surface Imprinted Polymer Modified Electrode for Determination of Ronidazole Residue in Food.
Journal of Instrumental Analysis, 35, (8), 993-998, (2016)
   

Ronidazole

Guo XC et al., Molecularly imprinted solid phase extraction method for simultaneous determination of seven nitroimidazoles from honey by HPLC-MS/MS.
Talanta, 166, 101-108, (2017)
   

ronidazole

Bustamante-Rangel M et al., Evaluation of the selectivity of molecularly imprinted polymer cartridges for nitroimidazoles. Application to the simultaneous extraction of nitroimidazoles and benzimidazoles from samples of animal origin.
Microchemical Journal, 172, Article107000-(2022)
   

ropivacaine

Andersson LI et al., Development of a molecularly imprinted polymer based solid-phase extraction of local anaesthetics from human plasma.
Analytica Chimica Acta, 526, (2), 147-154, (2004)
   

ropivacaine

Cobb Z et al., Determination of ropivacaine in human plasma using highly selective molecular imprint-based solid phase extraction and fast LC–MS analysis.
Analytical and Bioanalytical Chemistry, 383, (4), 645-650, (2005)
   

ropivacaine

Abdel-Rehim M et al., Microextraction in Packed Syringe Online with Liquid Chromatography-Tandem Mass Spectrometry: Molecularly Imprinted Polymer as Packing Material for MEPS in Selective Extraction of Ropivacaine from Plasma.
Journal of Liquid Chromatography & Related Technologies, 29, (12), 1725-1736, (2006)
   

ropivacaine

Cobb Z et al., Water-compatible molecularly imprinted polymers for efficient direct injection on-line solid-phase extraction of ropivacaine and bupivacaine from human plasma.
Analyst, 132, (12), 1262-1271, (2007)
   

ropivacaine

Daryanavard SM et al., Molecularly imprinted polymer in microextraction by packed sorbent for the simultaneous determination of local anesthetics: lidocaine, ropivacaine, mepivacaine and bupivacaine in plasma and urine samples.
Biomedical Chromatography, 27, (11), 1481-1488, (2013)
   

ropivacaine hydrochloride

Zhang XL et al., Determination of Ropivacaine Hydrochloride with Graphene Quantum Dots-Molecularly Imprinted Polymer Electrochemical Sensor.
Journal of Instrumental Analysis, 34, (2), 159-163, (2015)
   

rose bengal

Yuan KS et al., Sensitive determination of rose bengal in brown sugar by a molecularly imprinted solid-phase extraction monolithic capillary column coupled with capillary electrophoresis.
Analytical Methods, 7, (19), 8297-8303, (2015)
   

Rose Bengal

Ahmed MA et al., Molecular imprinted chitosan-TiO2 nanocomposite for the selective removal of Rose Bengal from wastewater.
International Journal of Biological Macromolecules, 107, (Part A), 1046-1053, (2018)
   

rosmarinic acid

Peng C et al., Facile Synthesis of Boronate Affinity-Based Molecularly Imprinted Monolith with Reduced Capturing pH Towards Cis-Diol-Containing Compounds.
Chromatographia, 82, (7), 1029-1040, (2019)
   

rosmarinic acid

Alipour S et al., Determination of Rosmarinic acid in plant extracts using a modified sensor based on magnetic imprinted polymeric nanostructures.
Sensors and Actuators B: Chemical, 323, Article128668-(2020)
   

rosmarinic acid

Saad EM et al., Molecularly imprinted polymers for selective extraction of rosmarinic acid from Rosmarinus officinalis L.
Food Chemistry, 335, Article127644-(2021)
   

rosmarinic acid

Zahara S et al., Molecular imprinting-based extraction of rosmarinic acid from Salvia hypoleuca extract.
Reactive and Functional Polymers, 166, Article104984-(2021)
   

rotenene

Yang M et al., Determination of trace rotenone by UV-Vis spectrophotometry using molecularly imprinted polymer microspheres.
Journal of Analytical Chemistry, 66, (9), 820-823, (2011)
   

rotenone

Yang M et al., Differential pulse voltammetric determination of trace rotenone using molecularly imprinted polymer microspheres.
Microchimica Acta, 166, (1), 95-99, (2009)
   

Rotenone

Proceeding, Zhang KC et al, Removal of Rotenone from Contaminated Water Using Molecularly Imprinted Polymeric Microspheres, 
In: Applied Mechanics and Materials, Sun DY, Sung WP, Chen R (Eds.), 1425-1428, (2011)
   

ROX

Song XQ et al., Molecularly imprinted solid-phase extraction for the determination of ten macrolide drugs residues in animal muscles by liquid chromatography-tandem mass spectrometry.
Food Chemistry, 208, 169-176, (2016)
   

Rox

Guo XY et al., Determination of roxithromycin residue in environmental water samples using molecularly imprinted solid phase extraction coupled with high performance liquid chromatography.
Chinese Journal of Analysis Laboratory, 37, (5), 533-536, (2018)
   

ROX

Song XQ et al., Determination of Ten Macrolide Drugs in Environmental Water Using Molecularly Imprinted Solid-Phase Extraction Coupled with Liquid Chromatography-Tandem Mass Spectrometry.
Molecules, 23, (5), ArticleNo1172-(2018)
   

ROX

Song XQ et al., Preparation and Application of Molecularly Imprinted Monolithic Extraction Column for the Selective Microextraction of Multiple Macrolide Antibiotics from Animal Muscles.
Polymers, 11, (7), ArticleNo1109-(2019)
   

roxarsone

Zhang GK et al., Preparation of Roxarsone Imprinted Polymers and Its Application to Solid Phase Extraction.
Chinese Journal of Analytical Chemistry, 41, (9), 1401-1405, (2013)
   

roxarsone

Fan WG et al., Functional organic material for roxarsone and its derivatives recognition via molecular imprinting.
Journal of Molecular Recognition, 31, (3), ArticleNoe2625-(2018)
   

roxarsone

Cavalera S et al., Stoichiometric molecular imprinting using polymerisable urea and squaramide receptors for the solid phase extraction of organo-arsenic compound roxarsone.
Analytical Methods, 12, (47), 5729-5736, (2020)
   

roxithromycin

Proceeding, Yu JY et al, Synthesis and properties of molecularly imprinted composite membranes of roxithromycin, 
Ma LX, Wang CS, Yang WM (Eds.), 80-85, (2009)
   

roxithromycin

Proceeding, Yu JY et al, Molecularly imprinted polymer microspheres prepared by precipitation polymerization for the binding and recognition of roxithromycin, 
Art. No. 5515319, (2010)
   

roxithromycin

Ding J et al., Determination of roxithromycin from human plasma samples based on magnetic surface molecularly imprinted polymers followed by liquid chromatography-tandem mass spectromer.
Journal of Chromatography B, 1021, 221-228, (2016)
   

roxithromycin

Song XQ et al., Molecularly imprinted solid-phase extraction for the determination of ten macrolide drugs residues in animal muscles by liquid chromatography-tandem mass spectrometry.
Food Chemistry, 208, 169-176, (2016)
   

roxithromycin

Guo XY et al., Determination of roxithromycin residue in environmental water samples using molecularly imprinted solid phase extraction coupled with high performance liquid chromatography.
Chinese Journal of Analysis Laboratory, 37, (5), 533-536, (2018)
   

roxithromycin

Ji SL et al., A hollow porous molecularly imprinted polymer as a sorbent for the extraction of 7 macrolide antibiotics prior to their determination by HPLC-MS/MS.
Microchimica Acta, 185, (3), ArticleNo203-(2018)
   

roxithromycin

Song XQ et al., Determination of Ten Macrolide Drugs in Environmental Water Using Molecularly Imprinted Solid-Phase Extraction Coupled with Liquid Chromatography-Tandem Mass Spectrometry.
Molecules, 23, (5), ArticleNo1172-(2018)
   

roxithromycin

Liu YH et al., Sensitive analysis of trace macrolide antibiotics in complex food samples by ambient mass spectrometry with molecularly imprinted polymer-coated wooden tips.
Talanta, 204, 238-247, (2019)
   

roxithromycin

Song XQ et al., Preparation and Application of Molecularly Imprinted Monolithic Extraction Column for the Selective Microextraction of Multiple Macrolide Antibiotics from Animal Muscles.
Polymers, 11, (7), ArticleNo1109-(2019)
   

RoxP

Ertürk G et al., Highly sensitive detection and quantification of the secreted bacterial benevolence factor RoxP using a capacitive biosensor: A possible early detection system for oxidative skin diseases.
PLoS ONE, 13, (3), ArticleNoe0193754-(2018)
   

RoxP

Ertürk Bergdahl G et al., In Vivo Detection and Absolute Quantification of a Secreted Bacterial Factor from Skin Using Molecularly Imprinted Polymers in a Surface Plasmon Resonance Biosensor for Improved Diagnostic Abilities.
ACS Sensors, 4, (3), 717-725, (2019)
   

RPG

Roushani M et al., Development of Electrochemical Sensor Based on Glassy Carbon Electrode Modified with a Molecularly Imprinted Copolymer and its Application for Detection of Repaglinide.
Electroanalysis, 30, (11), 2712-2718, (2018)
   

(-)-(5R)-5-phenyl- 2,4-diketo-tetrahydro-oxazole

Matsuishi T et al., Definitive evidence for enantioselective catalysis over molecular footprint catalytic cavities chirally imprinted on a silica(alumina) gel surface.
Chemistry Letters, 21, (10), 1921-1924, (1992)
   

(R)-(2)-2-phenylglycinol

Greene NT et al., Colorimetric molecularly imprinted polymer sensor array using dye displacement.
Journal of the American Chemical Society, 127, (15), 5695-5700, (2005)
   

(R)-phenylsuccinic acid

Ramström O et al., Recognition sites incorporating both pyridinyl and carboxy functionalities prepared by molecular imprinting.
Journal of Organic Chemistry, 58, (26), 7562-7564, (1993)
   

(R)-(+)-1,1prime-bi-2-naphthol

Meng AC et al., Multi-analyte imprinting capability of OMNiMIPs versus traditional molecularly imprinted polymers.
Journal of Molecular Recognition, 22, (2), 121-128, (2009)
   

(R)-(+)-1,1prime-bi-2-naphthol and BOC-L-tyrosine

Meng AC et al., Multi-analyte imprinting capability of OMNiMIPs versus traditional molecularly imprinted polymers.
Journal of Molecular Recognition, 22, (2), 121-128, (2009)
   

(R)-propranolol

Proceeding, Mizutani N et al, Fabrication and Application of Enantioselective TiO2 Nanoflims by Molecular Imprinting, 
1249-1252, (2006)
   

R-propranolol

Kantarovich K et al., Detection of template binding to molecularly imprinted polymers by Raman microspectroscopy.
Applied Physics Letters, 94, (19), 820-825, (2009)
   

R-propranolol

Yin JF et al., Molecularly imprinted nanotubes for enantioselective drug delivery and controlled release.
Chemical Communications, 46, (41), 7688-7690, (2010)
   

RR

Kyzas GZ et al., Selective separation of basic and reactive dyes by molecularly imprinted polymers (MIPs).
Chemical Engineering Journal, 149, (1-3), 263-272, (2009)
   

RR

Kyzas GZ et al., Optimization of chitosan and β-cyclodextrin molecularly imprinted polymer synthesis for dye adsorption.
Carbohydrate Polymers, 91, (1), 198-208, (2013)
   

(R,R)- cyclohexanediamine

Dobashi A et al., Chiral separation of enantiomeric 1,2-diamines using molecular imprinting method and selectivity enhancement by addition of achiral primary amines into eluents.
Analytical Sciences, 18, (1), 35-39, (2002)
   

(R,R)-1,2- cyclohexanediol

Dobashi A et al., Chiral separation of enantiomeric 1,2-diamines using molecular imprinting method and selectivity enhancement by addition of achiral primary amines into eluents.
Analytical Sciences, 18, (1), 35-39, (2002)
   

(1R,2R)-2-[(dimethylamino)methyl]-1-(3-methoxyphenyl)cyclohexanol

Afkhami A et al., Fabrication of a new electrochemical sensor based on a new nano-molecularly imprinted polymer for highly selective and sensitive determination of tramadol in human urine samples.
Biosensors and Bioelectronics, 44, 34-40, (2013)
   

(1R,3R,4R)-3-benzoyl-1,7,7-trimethylbicyclo[2.2.1]heptan-2-one

Hedin-Dahlström J et al., A class II aldolase mimic.
Journal of Organic Chemistry, 71, (13), 4845-4853, (2006)
   

RS

Zhang WL et al., Novel surface molecularly imprinted polymers as solid-phase extraction sorbents for selective extraction of dihydroxybenzenes from environmental water samples.
Fresenius Environmental Bulletin, 22, (8), 2324-2333, (2013)
   

(R,S)-(±)-2-amino-1-phenylethanol

Sobiech M et al., Separation of octopamine racemate on (R,S)-2-amino-1-phenylethanol imprinted polymer - Experimental and computational studies.
Talanta, 146, 556-567, (2016)
   

(2RS)-2-[[2-[[[(1E)-5-methoxy-1-[4(trifluoromethyl)phenyl]pentylidene]amino]oxy]ethyl]amino]butanedioic acid

Hashemi-Moghaddam H et al., Removal of potentioally genotoxic impurity from fluroxamine maleate crude drug by molecularly imprinted polymer.
Korean Journal of Chemical Engineering, 31, (10), 1898-1902, (2014)
   

1R,2S(-)ephedrine

Brisbane C et al., Molecularly imprinted films of acrylonitrile/methyl methacrylate/acrylic acid terpolymers: influence of methyl methacrylate in the binding performance of l-ephedrine imprinted films.
Organic & Biomolecular Chemistry, 11, (17), 2872-2884, (2013)
   

R,S 3-(4-Fluorophenyl) -2, 2-Dimethylcyclopane Carboxamide

Proceeding, Xu CM et al, Chiral Separation of R,S 3-(4-Fluorophenyl) -2,2-Dimethylcyclopane Carboxamide with Monolithic Molecularly Imprinted Polymers, 
In: Advanced Materials Research, Chen R, Sung WP, Kao JCM (Eds.), 40-43, (2013)
   

(1R,2S)-norephedrine

Amano S et al., Solid-State Hosts by the Template Polymerization of Columnar Liquid Crystals: Locked Supramolecular Architectures around Chiral 2-Amino Alcohols.
Chemistry - A European Journal, 13, (18), 5186-5196, (2007)
   

(R,S)-octopamine

Sobiech M et al., Separation of octopamine racemate on (R,S)-2-amino-1-phenylethanol imprinted polymer - Experimental and computational studies.
Talanta, 146, 556-567, (2016)
   

(RS)-1-p-chlorophenyl-4,4-dimethyl-3-(1H-1,2,4-triazol-1-ylmethyl) pentan-3-ol

Popov SA et al., The sorption properties of polymers with molecular imprints of chlorine-containing pesticides.
Russian Journal of Physical Chemistry A, Focus on Chemistry, 83, (4), 552-557, (2009)
   

R. sphaeroides

Lee MH et al., Recognition of Rhodobacter sphaeroides by microcontact-imprinted poly(ethylene-co-vinyl alcohol).
Colloids and Surfaces B: Biointerfaces, 135, 394-399, (2015)
   

RSV

Luo JP et al., Determination of active ingredients in Chinese medicine Danning Tablets using dispersion solid-phase extraction by molecular imprinting nanomaterials coupled with HPLC-DAD.
Analytical Methods, 9, (17), 2585-2589, (2017)
   

RT

Yang LT et al., Facile preparation of molecularly imprinted polypyrrole-graphene-multiwalled carbon nanotubes composite film modified electrode for rutin sensing.
Talanta, 161, 413-418, (2016)
   

RT

Yang SR et al., A Novel Rutin Electrochemical Sensor Using Reduced Graphene Oxide/Magnetite/Silver Nanoparticle-Molecularly Imprinted Polymer Composite Modified Electrode.
International Journal of Electrochemical Science, 13, 2483-2497, (2018)
   

RT

Song HJ et al., Novel bayberry-and-honeycomb-like magnetic surface molecularly imprinted polymers for the selective enrichment of rutin from Sophora japonica.
Food Chemistry, 356, Article129722-(2021)
   

RTA

Komarova E et al., Design of molecularly imprinted conducting polymer protein-sensing films via substrate-dopant binding.
Analyst, 140, (4), 1099-1106, (2015)
   

(R)-thalidomide

Suksuwan A et al., Tracking the chemical surface properties of racemic thalidomide and its enantiomers using a biomimetic functional surface on a quartz crystal microbalance.
Journal of Applied Polymer Science, 132, (30), ArticleNo42309-(2015)
   

(R)-thalidomide

Suksuwan A et al., The composite nanomaterials containing (R)-thalidomide-molecularly imprinted polymers as a recognition system for enantioselective-controlled release and targeted drug delivery.
Journal of Applied Polymer Science, 132, (18), Article No 41930-(2015)
   

Ru-AcTSn

Zambrzycka E et al., Studies of ion-imprinted polymers for solid-phase extraction of ruthenium from environmental samples before its determination by electrothermal atomic absorption spectrometry.
Spectrochimica Acta Part B-Atomic Spectroscopy, 66, (7), 508-516, (2011)
   

rubber elongation factor

Sontimuang C et al., Development of a rubber elongation factor, surface-imprinted polymer-quartz crystal microbalance sensor, for quantitative determination of Hev b1 rubber latex allergens present in natural rubber latex products.
Analytica Chimica Acta, 687, (2), 184-192, (2011)
   

rubidium ion

Hashemi B et al., Synthesis of novel ion-imprinted polymeric nanoparticles based on dibenzo-21-crown-7 for the selective pre-concentration and recognition of rubidium ions.
Journal of Separation Science, 38, (24), 4248-4254, (2015)
   

rubidium ion

Wang YY et al., Calix[4]arenes functionalized dual-imprinted mesoporous film for the simultaneous selective recovery of lithium and rubidium.
Applied Organometallic Chemistry, 32, (10), ArticleNoe4511-(2018)
   

rubidium ion

Xu XC et al., A facile strategy toward ion-imprinted hierarchical mesoporous material via dual-template method for simultaneous selective extraction of lithium and rubidium.
Journal of Cleaner Production, 171, 264-274, (2018)
   

rubidium ion

Liu XW et al., Extraction of Rb(I) Ions from Aqueous Solution Using Novel Imprinting Materials.
Industrial & Engineering Chemistry Research, 58, (13), 5269-5279, (2019)
   

rubidium ion

Xu JC et al., Simultaneous adsorption of Li(I) and Rb(I) by dual crown ethers modified magnetic ion imprinting polymers.
Applied Organometallic Chemistry, 33, (3), Article_e4778-(2019)
   

rubidium ion

Zheng XD et al., Dual-Functional Mesoporous Films Templated by Cellulose Nanocrystals for the Selective Adsorption of Lithium and Rubidium.
Journal of Chemical & Engineering Data, 64, (3), 926-933, (2019)
   

rubidium ion

Zhou ZY et al., Facile preparation of a rubidium ion-imprinted polymer by bulk polymerization for highly efficient separation of rubidium ions from aqueous solution.
New Journal of Chemistry, 45, (21), 9582-9590, (2021)
   

Ru-complex catalysts

Weng ZH et al., Preparation of surface molecularly imprinted Ru-complex catalysts for asymmetric transfer hydrogenation in water media.
Dalton Transactions, 40, (10), 2338-2347, (2011)
   

Ru(III)

Zambrzycka E et al., Studies of ion-imprinted polymers for solid-phase extraction of ruthenium from environmental samples before its determination by electrothermal atomic absorption spectrometry.
Spectrochimica Acta Part B-Atomic Spectroscopy, 66, (7), 508-516, (2011)
   

Ru(III)

Godlewska-Zylkiewicz B et al., Separation of ruthenium from environmental samples on polymeric sorbent based on imprinted Ru(III)-allyl acetoacetate complex.
Talanta, 89, (1), 352-359, (2012)
   

Ru(III)

Zambrzycka E et al., A novel ion imprinted polymer as a highly selective sorbent for separation of ruthenium ions from environmental samples.
Analytical Methods, 5, (12), 3096-3105, (2013)
   

Ru(III)

Zambrzycka E et al., A new ion imprinted polymer based on Ru(III)-thiobarbituric acid complex for solid phase extraction of ruthenium(III) prior to its determination by ETAAS.
Microchimica Acta, 181, (9-10), 1019-1027, (2014)
   

Ru(III)

Zeng JX et al., Fabrication and characterization of an ion-imprinted membrane via blending poly(methyl methacrylate-co-2-hydroxyethyl methacrylate) with polyvinylidene fluoride for selective adsorption of Ru(III).
Reactive and Functional Polymers, 115, 1-9, (2017)
   

Ru(III)

Monier M et al., Preparation of ruthenium (III) ion-imprinted beads based on 2-pyridylthiourea modified chitosan.
Journal of Colloid and Interface Science, 513, 266-278, (2018)
   

Ru(III)

Zeng JX et al., Ion-imprinted poly(methyl methacrylate-vinyl pyrrolidone)/poly(vinylidene fluoride) blending membranes for selective removal of ruthenium(III) from acidic water solutions.
Polymers for Advanced Technologies, 30, (7), 1865-1877, (2019)
   

Ru(III) 2-thiobarbituric acid complex

Zambrzycka E et al., A new ion imprinted polymer based on Ru(III)-thiobarbituric acid complex for solid phase extraction of ruthenium(III) prior to its determination by ETAAS.
Microchimica Acta, 181, (9-10), 1019-1027, (2014)
   

RUT

Masumoto S et al., Molecularly imprinted polymers for arbutin and rutin by modified precipitation polymerization and their application for selective extraction of rutin in nutritional supplements.
Journal of Pharmaceutical and Biomedical Analysis, 205, Article114294-(2021)
   

rutaecarpine

Fan JP et al., A molecular imprinted polymer on the surface of superparamagnetic Fe3O4-graphene oxide (MIP@Fe3O4@GO) for simultaneous recognition and enrichment of evodiamine and rutaecarpine in Evodiae fructus.
Journal of Applied Polymer Science, 134, (7), ArticleNo44465-(2017)
   

ruthenium(III) acetaldehyde thiosemicarbazone complex

Zambrzycka E et al., Studies of ion-imprinted polymers for solid-phase extraction of ruthenium from environmental samples before its determination by electrothermal atomic absorption spectrometry.
Spectrochimica Acta Part B-Atomic Spectroscopy, 66, (7), 508-516, (2011)
   

ruthenium(III) thiosemicarbazide complex

Zambrzycka E et al., Studies of ion-imprinted polymers for solid-phase extraction of ruthenium from environmental samples before its determination by electrothermal atomic absorption spectrometry.
Spectrochimica Acta Part B-Atomic Spectroscopy, 66, (7), 508-516, (2011)
   

ruthenium ion

Zambrzycka E et al., Studies of ion-imprinted polymers for solid-phase extraction of ruthenium from environmental samples before its determination by electrothermal atomic absorption spectrometry.
Spectrochimica Acta Part B-Atomic Spectroscopy, 66, (7), 508-516, (2011)
   

ruthenium ion

Godlewska-Zylkiewicz B et al., Separation of ruthenium from environmental samples on polymeric sorbent based on imprinted Ru(III)-allyl acetoacetate complex.
Talanta, 89, (1), 352-359, (2012)
   

ruthenium ion

Zambrzycka E et al., A novel ion imprinted polymer as a highly selective sorbent for separation of ruthenium ions from environmental samples.
Analytical Methods, 5, (12), 3096-3105, (2013)
   

ruthenium ion

Zambrzycka E et al., A new ion imprinted polymer based on Ru(III)-thiobarbituric acid complex for solid phase extraction of ruthenium(III) prior to its determination by ETAAS.
Microchimica Acta, 181, (9-10), 1019-1027, (2014)
   

ruthenium ion

Zeng JX et al., Fabrication and characterization of an ion-imprinted membrane via blending poly(methyl methacrylate-co-2-hydroxyethyl methacrylate) with polyvinylidene fluoride for selective adsorption of Ru(III).
Reactive and Functional Polymers, 115, 1-9, (2017)
   

ruthenium ion

Monier M et al., Preparation of ruthenium (III) ion-imprinted beads based on 2-pyridylthiourea modified chitosan.
Journal of Colloid and Interface Science, 513, 266-278, (2018)
   

ruthenium ion

Zeng JX et al., Ion-imprinted poly(methyl methacrylate-vinyl pyrrolidone)/poly(vinylidene fluoride) blending membranes for selective removal of ruthenium(III) from acidic water solutions.
Polymers for Advanced Technologies, 30, (7), 1865-1877, (2019)
   

rutin

Theodoridis G et al., Molecular imprinting of natural flavonoid antioxidants: Application in solid-phase extraction for the sample pretreatment of natural products prior to HPLC analysis.
Journal of Separation Science, 29, (15), 2310-2321, (2006)
   

rutin

Zhang YQ et al., Synthesis of silica adsorbent and its selective separation for flavone.
Journal of Tianjin University Science and Technology, 40, (4), 411-415, (2007)
   

rutin

Zhang YQ et al., Synthesis of silica adsorbent and its selective separation for flavone (Translated from: Journal of Tianjin University, 2007, 40(4): 411-415).
Frontiers of Chemistry in China, 3, (3), 320-324, (2008)
   

rutin

Peng L et al., Molecularly imprinted polymer for solid-phase extraction of rutin in complicated traditional Chinese medicines.
Analyst, 136, (4), 756-763, (2011)
   

rutin

Rezaei B et al., Molecularly imprinted-multiwall carbon nanotube paste electrode as a biosensor for voltammetric detection of rutin.
Analytical Methods, 3, (11), 2510-2516, (2011)
   

rutin

Fu Y et al., Preparation and adsorption selectivity of rutin molecularly imprinted polymers.
Journal of Applied Polymer Science, 123, (2), 903-912, (2012)
   

rutin

Yang YS et al., Study on preparation and performance of rutin molecularly imprinted polymers.
Science and Technology of Food Industry, 33, (2), 119-121, 125, (2012)
   

rutin

Zeng H et al., Preparation of magnetic molecularly imprinted polymers for separating rutin from Chinese medicinal plants.
Analyst, 137, (10), 2503-2512, (2012)
   

rutin

Zeng H et al., Preparation of molecular imprinted polymers using bi-functional monomer and bi-crosslinker for solid-phase extraction of rutin.
Talanta, 93, (1), 172-181, (2012)
   

rutin

Liu R et al., Study on graphene-nanogold modified molecular imprinting electrochemical sensor for determining the content of rutin in black tea.
Chinese Journal of Analysis Laboratory, 34, (11), 1272-1275, (2015)
   

rutin

Tang T et al., Preparation of Surface Molecularly Imprinted Polymer Based on CNTs/SiO2 and Its Application in Electrochemical Detecting Rutin.
Journal of Instrumental Analysis, 34, (11), 1253-1258, (2015)
   

rutin

Li GZ et al., Hybrid molecularly imprinted polymers modified by deep eutectic solvents and ionic liquids with three templates for the rapid simultaneous purification of rutin, scoparone, and quercetin from Herba Artemisiae Scopariae.
Journal of Separation Science, 39, (23), 4465-4473, (2016)
   

rutin

Wang CL et al., Boronic acid based imprinted electrochemical sensor for rutin recognition and detection.
Analyst, 141, (20), 5792-5798, (2016)
   

rutin

Yang LT et al., Facile preparation of molecularly imprinted polypyrrole-graphene-multiwalled carbon nanotubes composite film modified electrode for rutin sensing.
Talanta, 161, 413-418, (2016)
   

rutin

Hu Y et al., Boronate-modified hollow molecularly imprinted polymers for selective enrichment of glycosides.
Microchimica Acta, 185, (1), ArticleNo46-(2018)
   

rutin

Yang SR et al., A Novel Rutin Electrochemical Sensor Using Reduced Graphene Oxide/Magnetite/Silver Nanoparticle-Molecularly Imprinted Polymer Composite Modified Electrode.
International Journal of Electrochemical Science, 13, 2483-2497, (2018)
   

rutin

Zhao QY et al., Selective recognition and fast enrichment of anthocyanins by dummy molecularly imprinted magnetic nanoparticles.
Journal of Chromatography A, 1572, 9-19, (2018)
   

rutin

Li DJ et al., Boronate affinity-based surface-imprinted quantum dots as novel fluorescent nanosensors for the rapid and efficient detection of rutin.
Analytical Methods, 11, (25), 3212-3220, (2019)
   

rutin

El Jaouhari A et al., Enhanced molecular imprinted electrochemical sensor based on zeolitic imidazolate framework/reduced graphene oxide for highly recognition of rutin.
Analytica Chimica Acta, 1106, 103-114, (2020)
   

rutin

Guo QJ et al., In-situ and controllable synthesis of graphene-gold nanoparticles/molecularly imprinted polymers composite modified electrode for sensitive and selective rutin detection.
Microchemical Journal, 158, Article105254-(2020)
   

rutin

Lu YX et al., Electrochemical determination of rutin based on molecularly imprinted poly (ionic liquid) with ionic liquid-graphene as a sensitive element.
Sensors and Actuators B: Chemical, 311, Article127911-(2020)
   

rutin

Xi JJ et al., Novel molecularly imprinted photoelectrochemical sensor for rutin based on Bi2S3/ZnIn2S4 heterojunction.
Sensors and Actuators B: Chemical, 320, Article128409-(2020)
   

rutin

Masumoto S et al., Molecularly imprinted polymers for arbutin and rutin by modified precipitation polymerization and their application for selective extraction of rutin in nutritional supplements.
Journal of Pharmaceutical and Biomedical Analysis, 205, Article114294-(2021)
   

rutin

Song HJ et al., Novel bayberry-and-honeycomb-like magnetic surface molecularly imprinted polymers for the selective enrichment of rutin from Sophora japonica.
Food Chemistry, 356, Article129722-(2021)
   

rutin

Wang Y et al., Fabrication and application of a rutin electrochemical sensor based on rose-like AuNPs-MoS2-GN composite and molecularly imprinted chitosan.
Microchemical Journal, 168, Article106505-(2021)
   

rutoside

Guo HJ et al., Facile construction of reduced graphene oxide-carbon dot complex embedded molecularly imprinted polymers for dual-amplification and selective electrochemical sensing of rutoside.
New Journal of Chemistry, 41, (18), 9977-9983, (2017)
   

Ru-TSd

Zambrzycka E et al., Studies of ion-imprinted polymers for solid-phase extraction of ruthenium from environmental samples before its determination by electrothermal atomic absorption spectrometry.
Spectrochimica Acta Part B-Atomic Spectroscopy, 66, (7), 508-516, (2011)
   

RUX

Çorman ME et al., A porous molecularly imprinted nanofilm for selective and sensitive sensing of an anticancer drug ruxolitinib.
Analytica Chimica Acta, 1187, Article339143-(2021)
   

ruxolitinib

Çorman ME et al., A porous molecularly imprinted nanofilm for selective and sensitive sensing of an anticancer drug ruxolitinib.
Analytica Chimica Acta, 1187, Article339143-(2021)
   

R-VX

Liu F et al., Detection of organophosphorus compounds using a molecularly imprinted photonic crystal.
Biosensors and Bioelectronics, 32, (1), 273-277, (2012)
   

RYDMLNISSLRQDG

Tai DF et al., Epitope-Cavities Generated by Molecularly Imprinted Films Measure the Coincident Response to Anthrax Protective Antigen and Its Segments.
Analytical Chemistry, 82, (6), 2290-2293, (2010)
   

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