电信号分子在电化学功能核酸生物传感器中的研究进展

doi:10.13560/j.cnki.biotech.bull.1985.2018-0600

摘要/Abstract

摘要： 电信号分子是应用于功能核酸电化学生物传感器中起着信号转换作用的具有电化学活性且能够和核酸相互作用或是可以标记在核酸链上的一类分子的统称。电信号分子对于功能核酸电化学生物传感器是必不可少的一部分,它对于电化学生物传感器检测的灵敏度和应用的普及性都至关重要。简要介绍了5大类电信号分子,即染料类电信号分子、金属有机配合物类电信号分子、纳米材料类电信号分子、类过氧化氢酶类电信号分子、有机小分子类电信号分子,详细阐述了这些电信号在功能核酸电化学生物传感器中的应用,主要从产生电信号的方式、实际应用以及每种电信号的使用优缺点进行分析,并对新的电信号分子的发现或设计进行了展望,以期对后续有关电信号的研究有借鉴作用。

关键词: 电信号分子, 功能核酸电化学生物传感器, 信号转换

Abstract: Electrical signal molecules refer to a class of molecules that have an electrochemical activity as signal-switching role in functional nucleic acids electrochemical biosensors,and can interact with nucleic acids or can be Labeled on nucleic acid strands. Electrical signal molecules are essential part of functional nucleic acids electrochemical biosensors,and crucial for the detection sensitivity and application popularity of functional nucleic acids electrochemical biosensors. In this article we briefly introduced 5 major categories of electrical signal molecules,i.e.,dye class,organometallic complexes,nanomaterials,catalase-like,and organic small molecule. Then we demonstrated their applications in functional nucleic acids electrochemical biosensors,mainly from 3 aspects：the methods of generating electrical signals,practical applications,and the advantages and disadvantages of each electrical signal. In the end,we Look on the future discovery or design of new electrical signal molecules. It’s expected to be useful for the subsequent study of electrical signals.

Key words: electrical signal molecule, functional nucleic acids electrochemical biosensors, signal transition

谢银侠, 王蔚然, 程楠, 许文涛. 电信号分子在电化学功能核酸生物传感器中的研究进展[J]. 生物技术通报, 2019, 35(5): 157-169.

XIE Yin-xia, WANG Wei-ran, CHENG Nan, XU Wen-tao. Research Progress on Electrical Signal Molecules in Electrochemical Functional Nucleic Acids Biosensors[J]. Biotechnology Bulletin, 2019, 35(5): 157-169.

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