中文
Earlier issues
Announcement
More
Progress in Chemistry 2008, Vol. 20 Issue (06): 969-974 Previous Articles   Next Articles

• Review •

Two-Dimensional Imprinting of Protein Molecules

Yan Changling1,2 Lu Yan1,2 **   

  1. (1. College of Chemistry and Chemical Engineering, Lanzhou University, Lanzhou 730000, China;
    2. College of Chemistry and Environmental Science, Henan Normal University, Xinxiang 453007, China)
  • Received: Revised: Online: Published:
  • Contact: Lu Yan
PDF ( 1242 ) Cited
Export

EndNote

Ris

BibTeX

This review focuses on two-dimensional imprinting of protein molecule. The basic conception of two-dimensional imprinting of protein molecule was simply introduced. The general principle of two-imensional approaches of protein imprinting are explained, including epitope imprinting, sol-gel approach, radio frequency glow-discharge plasma deposition, Langmuir lipid monolayer approach and so on. The physical forms of the materials of two-dimensional imprinting of protein molecule are maily thin film, lipid monolayer, core-shell microbeads and nanowires. The preparation, binding ability and selective recognition on the materials of two-imensional imprinting of protein molecule are recounted. The recognition mechanisms of the various materials are analyzed for template proteins. The advantages and shortcoming of these materials are pointed out.

Key words:

molecular imprinting, proteins, two-dimensional materials, preparative approaches

CLC Number: 

[ 1 ] Mallik S , Plunkett S D , Dhal P K, et al . NewJ . Chem. , 1994 ,18 : 299 —304
[ 2 ] Dhal P K, Kulkarni M G, Mashelkar R A. Bio2Imprinting :Polymeric Receptors with and for Biological Macromolecules ( ed.Sellergren B) . New York : Elsevier , 2001. 23
[ 3 ] Wulff G. Angew. Chem. Int . Ed. Engl . , 1995 , 34 : 1812 —1832
[ 4 ] 郭天瑛(Guo T Y) , 夏永清(Xia YQ) , 郝广杰(Hao GJ ) 等.化工进展(Chemical Industry Engineering Progress) , 2003 , 22(7) : 713 —716
[ 5 ] Ramstrêm O , Ansell R J . Chirality , 1998 , 10 : 195 —209
[ 6 ] Nicholls I A , Rosengren J P. Bioseparation , 2002 , 10 : 301 —305
[ 7 ] 董文国(Dong W G) , 张敏莲(Zhang M L) , 刘铮(Liu Z) . 化工进展(Chemical Industry Engineering Progress) , 2003 , 22(7) :683 —688
[ 8 ] 史瑞雪(Shi R X) , 郭成海(Guo C H) , 邹小红(Zhou X H) 等.化工进展(Chemical Industry Engineering Progress) , 2002 , 14(3) : 182 —191
[ 9 ] 谭淑珍(Tan S Z) , 李革新(Li G X) , 李再全(Li Z Q) . 应用化工(Applied Chemical Industry) , 2004 , 33(4) : 4 —6
[10] 王锦(Wang J) , 雷孝(Lei X) , 何文礼(He WL) 等. 化学与生物工程(Chemistry and Bioengineering) , 2006 , 23 (4) : 4 —6
[11] 陈长宝(Chen C B) , 周杰(Zhou J) , 吴春辉(Wu C H) . 化学研究与应用(Chemical Research and Application) , 2006 , 18(8) : 896 —902
[12] 刘志航(Liu Z H) , 浣石(Huan S) , 蒋国平(Jiang G P) 等. 科技导报(Science and Technology Review) , 2006 , 24(1) : 51 —54
[13] Rachkov A , Minoura N. Biochim. Biophys. Acta-Protein Struct .M. , 2001 , 1544 : 255 —266
[14] Shiomi T , Matsui M, Mizukami F , et al . Biomaterials , 2005 ,26 : 5564 —5571
[15] Li Y, Yang H H , You Q H , et al . Anal . Chem. , 2006 , 78 :317 —320
[16] Glad M, Norrlow O , Sellergren B , et al . J . Chromatogr. A ,1985 , 347 : 11 —23
[17] Burow M, Minoura N. Biochem. Biophy. Res. , 1996 , 227 :419 —422
[18] Hirayama K, Sakal Y, Kameoka K. J . Appl . Polym. Sci . ,2001 , 81 : 3378 —3387
[19] Shi H Q , Tsai W B , Garrison M D , et al . Nature , 1999 , 398 :593 —597
[20] Shi H Q , Ratner B D. J . Biomed. Mater. Res. , 2000 , 49 : 1 —11
[21] Ratner B D. J . Mol . Recognit . , 1996 , 9 : 617 —625
[22] Ratner B D , Shi H Q. Curr. Opin. Solid State Mater. Sci . ,1999 , 4 : 395 —402
[23] Britt D W, Mêbius D , Hlady V. Phys. Chem. Chem. Phys. ,2000 , 20 : 4594 —4599
[24] Du X, Hlady V , Britt D W. Biosens. Bioelectron. , 2005 , 20 :2053 —2060
[25] Dhruv H , Pepalla R , Taveras M, et al . Biotechnol . Prog. ,2006 , 22 : 150 —155
[26] Turner N W, Wright B E , Hlady V , et al . J . Colloid Interface Sci . , 2007 , 308 : 71 —80
[27] Kempe M, Glad M, Mosbach K. J . Mol . Recognit . , 1995 , 8 :35 —39
[28] Chou P C , Rick J , Chou T C. Anal . Chim. Acta , 2005 , 542 :20 —25
[29] Ramanaviciene A , Ramanavicius A. Biosens. Bioelectron. ,2004 , 20 : 1076 —1082
[30] Piletsky S A , Piletska E V , Chen B , et al . Anal . Chem. , 2000 ,72 : 4381 —4385
[31] Bossi A , Piletsky S A , Piletska E V , et al . Anal . Chem. , 2001 ,73 : 5281 —5286
[32] Rick J , Chou T C. Chim. Acta , 2005 , 542 : 26 —31
[33] Rick J , Chou T C. Biosens. Bioelectron. , 2005 , 20 : 1878 —1883
[34] Yan C L , Lu Y, Gan S Y. J . Polym. Sci . Part A: Polym.Chem. , 2007 , 45 : 1911 —1919
[35] Tai D F , Lin C Y, Wu T Z , et al . Anal . Chem. , 2005 , 77 :5140 —5143
[36] Guo T Y, Xia YQ , Hao GJ , et al . Chin. Chem. Lett . , 2004 ,15 : 1339 —1341
[37] Litvin A L , Samuelson L A , Charych D H , et al . J . Phys.Chem. , 1995 , 100 : 17708 —17708
[38] Gidalevitz D , Weissbuch I , Kjaer K, et al . J . Am. Chem.Soc. , 1994 , 116 : 3271 —3278
[39] Pack D , Arnold F H. Chem. Phys. Lipids , 1997 , 86 : 135 —152
[1] Yiming Chen, Huiying Li, Peng Ni, Yan Fang, Haiqing Liu, Yunxiang Weng. Catechol Hydrogel as Wet Tissue Adhesive [J]. Progress in Chemistry, 2023, 35(4): 560-576.
[2] Xuan Li, Jiongpeng Huang, Yifan Zhang, Lei Shi. 1D Nanoribbons of 2D Materials [J]. Progress in Chemistry, 2023, 35(1): 88-104.
[3] Yanyan Wang, Limin Chen, Siyang Li, Luhua Lai. How Intrinsically Disordered Proteins Modulate Biomolecular Condensates [J]. Progress in Chemistry, 2022, 34(7): 1610-1618.
[4] Jin Zhou, Pengpeng Chen. Modification of 2D Nanomaterials and Their Applications in Environment Pollution Treatment [J]. Progress in Chemistry, 2022, 34(6): 1414-1430.
[5] Yanan Han, Jiahui Hong, Anrui Zhang, Ruoxuan Guo, Kexin Lin, Yuejie Ai. A Review on MXene and Its Applications in Environmental Remediation [J]. Progress in Chemistry, 2022, 34(5): 1229-1244.
[6] Weijia Zhang, Xueguang Shao, Wensheng Cai. Molecular Simulation of the Antifreeze Mechanism of Antifreeze Proteins [J]. Progress in Chemistry, 2021, 33(10): 1797-1811.
[7] Bin Qiao, Hongfei Chen, Hui Zhang, Chenxin Cai. Analysis and Detection of Tumor Exosomes [J]. Progress in Chemistry, 2019, 31(6): 847-857.
[8] Cheng Chen, Zhiqiang Dong, Haowen Chen, Yang Chen, Zhigang Zhu, Weiheng Shih. Two-Dimensional Photonic Crystals [J]. Progress in Chemistry, 2018, 30(6): 775-784.
[9] Honglei Wang, Wenzhen Lv, Xingxing Tang, Lingfeng Chen, Runfeng Chen, Wei Huang. Two-Dimensional Perovskites and Their Applications on Optoelectronic Devices [J]. Progress in Chemistry, 2017, 29(8): 859-869.
[10] Wenjie Zhu, Guoan Tai, Xufeng Wang, Qilin Gu, Zenghui Wu, Kongjun Zhu. Fabrication and Strain Sensing Properties of Two-Dimensional Atomic Crystal Materials [J]. Progress in Chemistry, 2017, 29(11): 1285-1296.
[11] Ding Peng, Chen Xian, Li Xiuling, Qing Guangyan, Sun Taolei, Liang Xinmiao. The Separation and Enrichment of Glycoproteins or Glycopeptides Based on Nanoparticles [J]. Progress in Chemistry, 2015, 27(11): 1628-1639.
[12] Cao Ya, Zhu Xiaoli, Zhao Jing, Li Hao, Li Genxi. Electrochemical Analysis of Tumor Marker Proteins [J]. Progress in Chemistry, 2015, 27(1): 1-10.
[13] Lin Yingwu. Dimerization, Oligomerization and Polymerization of Heme Proteins [J]. Progress in Chemistry, 2014, 26(06): 987-995.
[14] Zhong Dagen, Liu Zonghua, Zuo Qinhua, Xue Wei. Interaction of Polymeric Nanomaterials with Plasma Proteins [J]. Progress in Chemistry, 2014, 26(04): 638-646.
[15] Chen Xuwei, Mao Quanxing, Wang Jianhua*. Ionic Liquids in Extraction/Separation of Proteins [J]. Progress in Chemistry, 2013, 25(05): 661-668.