Searching for author GuerreiroA in mipdatabase.com main collection

1. Gómez-Caballero A et al., Solid-phase synthesis of imprinted nanoparticles as artificial antibodies against the C-terminus of the cannabinoid CB1 receptor: exploring a viable alternative for bioanalysis.
   Microchimica Acta, 188, (11), Article368-(2021)
      
2. Guha A et al., Direct detection of small molecules using a nano-molecular imprinted polymer receptor and a quartz crystal resonator driven at a fixed frequency and amplitude.
   Biosensors and Bioelectronics, 158, Article112176-(2020)
      
3. Di Masi S et al., Sensor based on electrosynthesised imprinted polymeric film for rapid and trace detection of copper(II) ions.
   Sensors and Actuators B: Chemical, 307, Article127648-(2020)
      
4. Di Masi S et al., Corrigendum to "Sensor based on electrosynthesised imprinted polymeric film for rapid and trace detection of copper(II) ions" [Sens. Actuators, B 307 (2020) 127648].
   Sensors and Actuators B: Chemical, 311, Article127910-(2020)
      
5. Moczko E et al., Epitope approach in molecular imprinting of antibodies.
   Journal of Chromatography B, 1124, 1-6, (2019)
      
6. Smolinska-Kempisty K et al., Negative selection of MIPs to create high specificity ligands for glycated haemoglobin.
   Sensors and Actuators B: Chemical, 301, Article126967-(2019)
      
7. Canfarotta F et al., Specific Drug Delivery to Cancer Cells with Double-Imprinted Nanoparticles against Epidermal Growth Factor Receptor.
   Nano Letters, 18, (8), 4641-4646, (2018)
      
8. Canfarotta F et al., A novel capacitive sensor based on molecularly imprinted nanoparticles as recognition elements.
   Biosensors and Bioelectronics, 120, 108-114, (2018)
      
9. Altintas Z et al., Corrigendum to "NanoMIP based optical sensor for pharmaceuticals monitoring" [Sens. Actuators B: Chem. 213 (2015) 305-313].
   Sensors and Actuators B: Chemical, 277, 679-(2018)
      
10. Piletsky SS et al., Development of molecularly imprinted polymers specific for blood antigens for application in antibody-free blood typing.
    Chemical Communications, 53, (11), 1793-1796, (2017)
       
11. Bates F et al., Computational design of molecularly imprinted polymer for direct detection of melamine in milk.
    Separation Science and Technology, 52, (8), 1441-1453, (2017)
       
12. Karim K et al., A Protocol for the Computational Design of High Affinity Molecularly Imprinted Polymer Synthetic Receptors.
    Global Journal of Biotechnology and Biomaterial Science, 3, (1), 001-007, (2017)
       
13. Smolinska-Kempisty K et al., New potentiometric sensor based on molecularly imprinted nanoparticles for cocaine detection.
    Biosensors and Bioelectronics, 96, 49-54, (2017)
       
14. Tang SP et al., A pseudo-ELISA based on molecularly imprinted nanoparticles for detection of gentamicin in real samples.
    Analytical Methods, 9, (19), 2853-2858, (2017)
       
15. Gutierrez-Climente R et al., Molecularly imprinted nanoparticles grafted to porous silica as chiral selectors in liquid chromatography.
    Journal of Chromatography A, 1508, 53-64, (2017)
       
16. Piletska E et al., Biomimetic Silica Nanoparticles Prepared by a Combination of Solid-Phase Imprinting and Ostwald Ripening.
    Scientific Reports, 7, (1), ArticleNo11537-(2017)
       
17. Motib A et al., Modulation of Quorum Sensing in a Gram-Positive Pathogen by Linear Molecularly Imprinted Polymers with Anti-infective Properties.
    Angewandte Chemie International Edition, 56, (52), 16555-16558, (2017)
       
18. Cáceres C et al., Does size matter? Study of performance of pseudo-ELISAs based on molecularly imprinted polymer nanoparticles prepared for analytes of different sizes.
    Analyst, 141, (4), 1405-1412, (2016)
       
19. Mazzotta E et al., Solid-phase synthesis of electroactive nanoparticles of molecularly imprinted polymers. A novel platform for indirect electrochemical sensing applications.
    Sensors and Actuators B: Chemical, 229, 174-180, (2016)
       
20. Canfarotta F et al., Solid-phase synthesis of molecularly imprinted nanoparticles.
    Nature Protocols, 11, (3), 443-455, (2016)
       
21. Czulak J et al., Formation of target-specific binding sites in enzymes: solid-phase molecular imprinting of HRP.
    Nanoscale, 8, (21), 11060-11066, (2016)
       
22. Garcia-Mutio D et al., Solid-phase synthesis of imprinted nanoparticles grafted on gold substrates for voltammetric sensing of 4-ethylphenol.
    Sensors and Actuators B: Chemical, 236, 839-848, (2016)
       
23. Canfarotta F et al., Biocompatibility and internalization of molecularly imprinted nanoparticles.
    Nano Research, 9, (11), 3463-3477, (2016)
       
24. Smolinska-Kempisty K et al., A comparison of the performance of molecularly imprinted polymer nanoparticles for small molecule targets and antibodies in the ELISA format.
    Scientific Reports, 6, ArticleNo37638-(2016)
       
25. Altintas Z et al., NanoMIP based optical sensor for pharmaceuticals monitoring.
    Sensors and Actuators B: Chemical, 213, 305-313, (2015)
       
26. Altintas Z et al., Detection of Waterborne Viruses Using High Affinity Molecularly Imprinted Polymers.
    Analytical Chemistry, 87, (13), 6801-6807, (2015)
       
27. Garcia D et al., Molecularly imprinted polymers as a tool for the study of the 4-ethylphenol metabolic pathway in red wines.
    Journal of Chromatography A, 1410, 164-172, (2015)
       
28. Garcia-Mutio D et al., Molecularly Imprinted High Affinity Nanoparticles for 4-Ethylphenol Sensing.
    Procedia Engineering, 120, 1132-1136, (2015)
       
29. Mistry J et al., Analysis of cooperative interactions in molecularly imprinted polymer nanoparticles.
    Molecular Imprinting, 3, (1), 55-64, (2015)
       
30. Basozabal I et al., Direct potentiometric quantification of histamine using solid-phase imprinted nanoparticles as recognition elements.
    Biosensors and Bioelectronics, 58, 138-144, (2014)
       
31. Shutov RV et al., Introducing MINA - The Molecularly Imprinted Nanoparticle Assay.
    Small, 10, (6), 1086-1089, (2014)
       
32. Korposh S et al., Selective vancomycin detection using optical fibre long period gratings functionalised with molecularly imprinted polymer nanoparticles.
    Analyst, 139, (9), 2229-2236, (2014)
       
33. Muzyka K et al., Optimisation of the synthesis of vancomycin-selective molecularly imprinted polymer nanoparticles using automatic photoreactor.
    Nanoscale Research Letters, 9, Article No 154-(2014)
       
34. Guerreiro A et al., Influence of Surface-Imprinted Nanoparticles on Trypsin Activity.
    Advanced Healthcare Materials, 3, (9), 1426-1429, (2014)
       
35. Warwick C et al., Conductance based sensing and analysis of soluble phosphates in wastewater.
    Biosensors and Bioelectronics, 52, 173-179, (2014)
       
36. Poma A et al., Automatic reactor for solid-phase synthesis of molecularly imprinted polymeric nanoparticles (MIP NPs) in water.
    RSC Advances, 4, (8), 4203-4206, (2014)
       
37. Warwick C et al., A molecular imprinted polymer based sensor for measuring phosphate in wastewater samples.
    Water Science & Technology, 69, (1), 48-54, (2014)
       
38. Warwick C et al., Sensing and analysis of soluble phosphates in environmental samples: A review.
    Biosensors and Bioelectronics, 41, 1-11, (2013)
       
39. Subrahmanyam S et al., Optimization of experimental conditions for synthesis of high affinity MIP nanoparticles.
    European Polymer Journal, 49, 100-105, (2013)
       
40. Moczko E et al., Surface-modified multifunctional MIP nanoparticles.
    Nanoscale, 5, (9), 3733-3741, (2013)
       
41. Poma A et al., Solid-Phase Synthesis of Molecularly Imprinted Polymer Nanoparticles with a Reusable Template-"Plastic Antibodies".
    Advanced Functional Materials, 23, (22), 2821-2827, (2013)
       
42. Unceta N et al., Enantioselective extraction of (+)-(S)-citalopram and its main metabolites using a tailor-made stir bar chiral imprinted polymer for their LC-ESI-MS/MS quantitation in urine samples.
    Talanta, 116, 448-453, (2013)
       
43. Moczko E et al., PEG-Stabilized Core-Shell Surface-Imprinted Nanoparticles.
    Langmuir, 29, (31), 9891-9896, (2013)
       
44. Basozabal I et al., Rational design and chromatographic evaluation of histamine imprinted polymers optimised for solid-phase extraction of wine samples.
    Journal of Chromatography A, 1308, 45-51, (2013)
       
45. Chianella I et al., Direct Replacement of Antibodies with Molecularly Imprinted Polymer Nanoparticles in ELISA - Development of a Novel Assay for Vancomycin.
    Analytical Chemistry, 85, (17), 8462-8468, (2013)
       
46. Piletska E et al., Extraction of salbutamol using co-sintered molecularly imprinted polymers as a new format of solid-phase extraction.
    Analytical Methods, 5, (24), 6954-6959, (2013)
       
47. Ivanova-Mitseva PK et al., Cubic Molecularly Imprinted Polymer Nanoparticles with a Fluorescent Core.
    Angewandte Chemie International Edition, 51, (21), 5196-5199, (2012)
       
48. Gomez-Caballero A et al., Chiral imprinted polymers as enantiospecific coatings of stir bar sorptive extraction devices.
    Biosensors and Bioelectronics, 28, (1), 25-32, (2011)
       
49. Garcinuño RM et al., The stabilisation of receptor structure in low cross-linked MIPs by an immobilised template.
    Soft Matter, 5, (2), 313-317, (2009)
       
50. Guerreiro A et al., Preliminary evaluation of new polymer matrix for solid-phase extraction of nonylphenol from water samples.
    Analytica Chimica Acta, 612, (1), 99-104, (2008)
       
51. Breton F et al., Virtual imprinting as a tool to design efficient MIPs for photosynthesis-inhibiting herbicides.
    Biosensors and Bioelectronics, 22, (9-10), 1948-1954, (2007)
       
52. Mijangos I et al., Influence of initiator and different polymerisation conditions on performance of molecularly imprinted polymers.
    Biosensors and Bioelectronics, 22, (3), 381-387, (2006)
       
53. Piletsky SA et al., Polymer cookery: Influence of polymerization time and different initiation conditions on performance of molecularly imprinted polymers.
    Macromolecules, 38, (4), 1410-1414, (2005)
       
54. Schneider F et al., Comparison of thin-layer and bulk MlPs synthesized by photoinitiated in situ crosslinking polymerization from the same reaction mixtures.
    Journal of Applied Polymer Science, 98, (1), 362-372, (2005)
       
55. Karim K et al., How to find effective functional monomers for effective molecularly imprinted polymers?
    Advanced Drug Delivery Reviews, 57, (12), 1795-1808, (2005)
       
56. Piletsky SA et al., Polymer cookery. 2. Influence of polymerization pressure and polymer swelling on the performance of molecularly imprinted polymers.
    Macromolecules, 37, (13), 5018-5022, (2004)
       



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