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Separation & Purification Reviews Volume 36, 2007 - Issue 4
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Original Articles

Recent Advances in the Study of Protein Imprinting

Xue Zhou Key Laboratory of Functional Polymer Materials, Chemistry Department, Ministry of Education of China, Nankai University, Tianjin, P. R. China
,
Wenyou Li Key Laboratory of Functional Polymer Materials, Chemistry Department, Ministry of Education of China, Nankai University, Tianjin, P. R. China
,
Xiwen He Key Laboratory of Functional Polymer Materials, Chemistry Department, Ministry of Education of China, Nankai University, Tianjin, P. R. ChinaCorrespondence[email protected]
,
Langxing Chen Key Laboratory of Functional Polymer Materials, Chemistry Department, Ministry of Education of China, Nankai University, Tianjin, P. R. China
&
Yukui Zhang Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian, P. R. China
Pages 257-283 | Received 25 Sep 2007, Accepted 31 Oct 2007, Published online: 27 Dec 2007

References

  • Mahony , J. O. , Nolan , K. , Smyth , M. R. and Mizaikoff , B. 2005 . Molecularly imprinted polymers—potential and challenges in analytical chemistry . Anal. Chim. Acta , 534 ( 1 ) : 31
  • Turiel , E. and Martin‐Esteban , A. 2004 . Molecularly imprinted polymers: towards highly selective stationary phase in liquid chromatography and capillary electrophoresis . Anal. Bioanal. Chem. , 378 ( 8 ) : 1876
  • Haginaka , J. 2004 . Molecularly imprinted polymers for solid‐phase extraction . Anal. Bioanal. Chem. , 379 ( 3 ) : 332
  • Sellergren , B. 1994 . Direct drug determination by selective sample enrichment on an imprinted polymer . Anal. Chem. , 66 ( 9 ) : 1578
  • Wulff , G. 2002 . Enzyme‐like catalysis by molecularly imprinted polymers . Chem. Rev. , 102 ( 1 ) : 1
  • Alvarez‐Lorenzo , C. and Concheiro , A. 2004 . Molecularly imprinted polymers for drug delivery . J. Chromatogr. B , 804 ( 1 ) : 231
  • Haupt , K. and Mosbach , K. 2000 . Molecularly imprinted polymers and their use in biomimetic sensors . Chem. Rev. , 100 ( 7 ) : 2495
  • Surugiu , L. , Danielsson , B. , Ye , L. , Mosbach , K. and Haupt , K. 2001 . Chemiluminescence imaging ELISA using an imprinted polymers as the recognition element instead of an antibody . Anal. Chem. , 73 ( 3 ) : 487
  • Yan , M. and Ramström , O. 2005 . Molecularly Imprinted Materials Science and Technology Vol. 1 , 25 – 87 . New York : Marcel Dekker .
  • McElhiney , J. and Lawton , L. A. 2005 . Detection of the cyanobacterial hepatotoxins microcystins . Toxicol. Appl. Phamacol. , 203 ( 3 ) : 219
  • Parmpi , P. and Kofinas , P. 2004 . Biomimetic glucose recognition using molecularly imprinted polymer hydrogels . Biomaterials , 25 ( 10 ) : 1969
  • Rap , T. and Horvai , G. 2004 . Characterization of the selectivity of a phenytoin imprinted polymer . J. Chromatogr. A , 1034 ( 1–2 ) : 99
  • Spivak , D. A. , Simon , R. and Campbell , J. 2004 . Evidence of shape selectivity in non‐covalently imprinted polymers . Anal. Chim. Acta , 504 ( 1 ) : 23
  • Hjertén , S. , Liao , J. L. , Nakazato , K. , Wang , Y. , Zamaratskaia , G. and Zhang , H. X. 1997 . Gels mimicking antibodies in their selective recognition of proteins . Chromatographia , 44 ( 5–6 ) : 227
  • Liao , J. L. , Wang , Y. and Hjertén , S. 1996 . A novel support with artificially created recognition for the selective removal of proteins and for affinity chromatography . Chromatographia , 42 ( 5 ) : 259
  • Hjertén , S. and Mosbach , R. 1962 . “Molecular‐sieve” chromatography of proteins on columns of cross‐linked polyacrylamide . Anal. Biochem. , 3 ( 2 ) : 109
  • Pang , X. S. , Cheng , G. X. , Li , R. S. , Lu , S. L. and Zhang , Y. H. 2005 . Bovine serum albumin‐imprinted polyacrylamide gel beads prepared via inverse‐phase seed suspension polymerization . Anal. Chim. Acta , 550 ( 1–2 ) : 13
  • Burow , M. and Minoura , N. 1996 . Molecular imprinting: synthesis of polymer particles with antibody‐like binding characteristics for glucose oxidase . Biochem. Biophys. Res. Commun. , 227 ( 2 ) : 419
  • Hirayama , K. , Burow , M. , Morikawa , Y. and Minoura , N. 1998 . Synthesis of polymer‐coated silica particles with specific recognition sites for glucose oxidase by the molecular imprinting technique . Chem. Lett. , 28 ( 8 ) : 731
  • Hirayama , K. , Sakai , Y. and Kameoka , K. 2001 . Synthesis of polymer particles with specific lysozyme recognition sites by a molecular imprinting technique . J. Appl. Polym. Sci. , 81 ( 14 ) : 3378
  • Ou , S. H. , Wu , M. C. , Chou , T. C. and Liu , C. C. 2004 . Polyacylamide gels with electrostatic functional groups for the molecular imprinting of lysozyme . Anal. Chim. Acta , 504 ( 1 ) : 163
  • Vaidya , A. A. , Lele , B. S. , Kulkarni , M. G. and Mashelkar , R. A. 2001 . Creating a macromolecular receptor by affinity imprinting . J. Appl. Polym. Sci. , 81 ( 5 ) : 1075
  • Huang , J. T. , Zhang , J. , Zhang , J. Q. and Zheng , S. H. 2005 . Template imprinting amphoteric polymer for the recognition of proteins . J. Appl. Polym. Sci. , 95 ( 2 ) : 358
  • Pang , X. S. , Cheng , G. X. , Lu , S. L. and Tang , E. J. 2006 . Synthesis of polyacrylamide gel beads with electrostatic functional groups for the molecular imprinting of bovine serum albumin . Anal. Bioanal. Chem. , 384 ( 1 ) : 225
  • Hawkins , D. M. , Stevenson , D. and Reddy , S. M. 2005 . Investigation of protein imprinting in hydrogel‐based molecularly imprinted polymers (HydroMIPs) . Anal. Chim. Acta , 542 ( 1 ) : 61
  • Guo , T. Y. , Xia , Y. Q. , Hao , G. J. , Song , M. D. and Zhang , B. H. 2004 . Adsorptive separation of hemoglobin by molecularly imprinted chitosan beads . Biomaterials , 25 ( 4 ) : 5905
  • Muzzarelli , R. , Baldassarre , V. , Conto , F. , Ferrara , P. , Biagini , G. , Gazzanelli , G. and Vasi , V. 1988 . Biological activity of chitosan: ultrastructual study . Biomaterials , 9 ( 3 ) : 247
  • Guo , T. Y. , Xia , Y. Q. , Wang , J. , Song , M. D. and Zhang , B. H. 2005 . Chitosan beads as molecularly imprinted polymer matrix for selective separation of proteins . Biomaterials , 26 ( 28 ) : 5737
  • Turner , N. W. , Jeans , C. W. , Brain , K. R. , Allender , C. J. , Hlady , V. and Britt , D. W. 2006 . From 3D to 2D: a review of the molecular imprinting of proteins . Biotechnol. Prog. , 22 ( 6 ) : 1474
  • Glad , M. , Norrlöw , O. , Sellergren , B. , Siegbahn , N. and Mosbach , K. 1985 . Use of silane monomers for molecular imprinting and enzyme entrapment in polysiloxane‐coated porous silica . J. Chromatogr. , 347 ( 1 ) : 11
  • Venton , D. L. and Gudipati , E. 1995a . Influence of protein on polysiloxane polymer formation: evidence for induction of complementary protein‐polymer interactions . Biochim. Biophys. Acta , 1250 ( 2 ) : 126
  • Venton , D. L. and Gudipati , E. 1995b . Entrapment of enzymes using organo‐functionalized polysiloxane copolymers . Biochim. Biophys. Acta , 1250 ( 2 ) : 117
  • Shiomi , T. , Matsui , M. , Mizukami , F. and Sakaguchi , K. 2005 . A method for the molecular imprinting of hemoglobin on silica surfaces using silanes . Biomaterials , 26 ( 27 ) : 5564
  • Mallik , S. , Plunkett , S. D. , Dhal , P. K. , Johnson , R. D. , Pack , D. , Shnek , D. and Arnold , F. H. 1994 . Towards materials for the specific recognition and separation of proteins . New J. Chem. , 18 ( 3 ) : 299
  • Kempe , M. , Glad , M. and Mosbach , M. 1995 . An approach towards surface imprinting using the enzyme ribonuclease A . J. Mol. Recognit. , 8 ( 1–2 ) : 35
  • Piletsky , S. A. , Piletska , E. V. , Chen , B. , Karim , K. , Weston , D. , Barrett , G. , Lowe , P. and Turner , A. P.F. 2000 . Chemical grafting of molecularly imprinted homopolymers to the surface of microplates. Application of artificial adrenergic receptor in enzyme‐linked assay for β‐agonists determination . Anal. Chem. , 72 ( 18 ) : 4381
  • Piletsky , S. A. , Piletska , E. V. , Bossi , A. , Karim , K. , Lowe , P. and Turner , A. P.F. 2001 . Substitution of antibodies and receptors with molecularly imprinted polymers in enzyme‐linked and fluorescent assays . Biosens. Bioelectron. , 16 ( 9–12 ) : 701
  • Bossi , A. , Piletsky , S. A. , Piletska , E. V. , Righetti , P. G. and Turner , A. P.F. 2001 . Surface‐grafted molecularly imprinted polymers for protein recognition . Anal. Chem. , 73 ( 21 ) : 5281
  • Rick , J. and Chou , T. C. 2005 . Imprinting unique motifs formed from protein‐protein associations . Anal. Chim. Acta , 542 ( 1 ) : 26
  • Chou , P. C. , Rick , J. and Chou , T. C. 2005 . C‐reactive protein thin‐film molecularly imprinted polymers formed using a micro‐contact approach . Anal. Chim. Acta , 542 ( 1 ) : 20
  • Zen , Q. , Zhong , W. and Mortensen , R. F. 1997 . Binding site on human C‐reactive Protein (CRP) recognized by the Leukocyte CRP‐receptor . J. Cell. Biochem. , 64 ( 1 ) : 140
  • Hsu , C. Y. , Lin , H. Y. , Thomas , J. L. and Chou , T. C. 2006 . Synthesis of and recognition by ribonuclease A imprinted polymers . Nanotechnology , 17 ( 4 ) : S77
  • Chronakis , I. S. , Milosevic , B. , Frenot , A. and Ye , L. 2006 . Generation of molecular recognition sites in electrospun polymer nanofibers via molecular imprinting . Macromolecules , 39 ( 1 ) : 357
  • Yang , H. H. , Zhang , S. Q. , Tan , F. , Zhuang , Z. X. and Wang , X. R. 2005 . Surface molecularly imprinted nanowires for biorecognition . J. Am. Chem. Soc. , 127 ( 5 ) : 1378
  • Shi , H. Q. , Tsai , W. B. , Garrison , M. D. , Ferrari , S. and Ratner , B. D. 1999 . Template‐imprinted nanostructured surfaces for protein recognition . Nature , 398 ( 4 ) : 593
  • Shi , H. Q. and Ratner , B. D. 2000 . Template recognition of protein‐imprinted polymer surfaces . J. Biomed. Mater. Res. , 49 ( 1 ) : 1
  • Li , Y. , Yang , H. H. , You , Q. H. , Zhuang , Z. X. and Wang , X. R. 2006 . Protein recognition via surface molecularly imprinted polymer nanowires . Anal. Chem. , 78 ( 1 ) : 317
  • Xie , C. G. , Zhang , Z. P. , Wang , D. P. , Guan , G. J. , Gao , D. M. and Liu , J. H. 2006 . Surface molecular self‐assembly strategy for TNT imprinting of polymer nanowire/nanotube arrays . Anal. Chem. , 78 ( 24 ) : 8339
  • Rachkov , A. and Minoura , N. 2000 . Recognition of oxytocin and oxytocin‐related peptides in aqueous media using a molecularly imprinted polymer synthesized by the epitope approach . J. Chromatogr. A , 889 ( 1–2 ) : 111
  • Rachkov , A. and Minoura , N. 2001 . Towards molecularly imprinted polymers selective to peptides and proteins. The epitope approach . Biochim. Biophys. Acta , 1544 ( 1–2 ) : 255
  • Rachkov , A. , Hu , M. J. and Bulgarevich , E. 2004 . Molecularly imprinted polymers prepared in aqueous solution selective for [Sar1, Ala8]angiotensin II . Anal. Chim. Acta , 504 ( 1 ) : 191
  • Nishino , H. , Huang , C. S. and Shea , K. J. 2006 . Selective protein capture by epitope imprinting . Angew. Chem. Int. Ed. , 45 ( 15 ) : 2392
  • Tong , D. , Hetényi , C. , Bikádi , Z. , Gao , J. P. and Hjertén , S. 2001 . Some studies of the chromatographic properties of gels (‘artificial antibodies/receptors’) for selective adsorption of proteins . Chromatographia , 54 ( 1–2 ) : 7
  • Mares‐Guia , M. and Shaw , E. 1965 . Studies on the active center of trypsin. The binding of amidines and guanidines as models of the substrate side chain . J. Biol. Chem. , 240 ( 4 ) : 1579
  • Luong , J. H.T. , Male , K. B. and Nguyen , A. L. 1988 . Synthesis and characterization of a water‐soluble affinity polymer for trypsin purification . Biotech. Bioeng. , 31 ( 5 ) : 439
  • Thompson , D. , Pepys , M. B. and Wood , S. P. 1999 . The physiological structure of human C‐reactive protein and its complex with phosphocholine . Structure , 7 ( 2 ) : 169
  • Caide , X. , Liu , Z. , Gao , Q. F. , Zhou , Q. Z. and Sui , S. F. 1996 . Specific interaction of rabbit C‐reactive protein with phospholipid membranes . Thin Solid Films , 284–285 ( 15 ) : 793
  • Piletska , E. , Pilestsky , S. , Karim , K. , Terpetschnig , E. and Turner , A. 2004 . Biotin‐specific synthetic receptors prepared using molecular imprinting . Anal. Chim. Acta , 504 ( 1 ) : 179
  • Hirayama , K. and Kameoka , K. 2000 . Synthesis of polymer particles with specific binding sites for lysozyme by a molecular imprinting technique and its application to a quartz crystal microbalance sensor . Bunseki Kagaku , 49 ( 1 ) : 29

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