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引用本文:   馮濤濤, 張帥, 張麗, 張美寧. 活體微電極抗蛋白質吸附的研究進展. 分析化學, 2019, 47(10): 1612-1621. doi:  10.19756/j.issn.0253-3820.191455 [復制]

Citation:   FENG Tao-Tao , ZHANG Shuai , ZHANG Li , ZHANG Mei-Ning . Recent Advances on Antifouling of Microelectrode for in Vivo Electrochemistry. Chinese Journal of Analytical Chemistry, 2019, 47(10): 1612-1621. doi: 10.19756/j.issn.0253-3820.191455 [復制]

活體微電極抗蛋白質吸附的研究進展

通訊作者:  張美寧, [email protected]

收稿日期: 2019-07-28

基金項目: 本文系國家自然科學基金項目(No.21874152)資助

Recent Advances on Antifouling of Microelectrode for in Vivo Electrochemistry

Corresponding author:  ZHANG Mei-Ning , [email protected]

Received Date:  2019-07-28

Fund Project:  This work was supported by the National Natural Science Foundation of China (No. 21874152).

活體電化學分析方法是利用微電極植入特定腦區原位監測腦內神經化學物質動態變化的方法之一,具有高時空分辨率、高靈敏度、對腦組織損傷小等優點。然而,微電極的植入會引發機體產生一系列的排異反應,這將對微電極的電分析性能產生不利影響。一方面,蛋白質的非特異性吸附會導致微電極的靈敏度和選擇性下降;另一方面,蛋白質介導的細胞粘附,其代謝過程會導致電極周圍的微化學環境改變,從而影響微電極對神經化學物質檢測的準確性。最終,電極表面上形成的纖維囊會阻礙電子(電荷)的轉移,導致微電極無法正常工作。本文首先簡要介紹了蛋白質非特異性吸附對電極電化學性能的影響,以及近年來發展的電極抗蛋白質吸附的方法和策略,對活體原位電化學分析中抗蛋白質吸附的研究進展做評綜述,并對活體微電極抗蛋白質吸附存在的問題及未來的發展進行了總結和展望。

關鍵詞:   活體分析, 微電極, 蛋白質吸附, 抗蛋白質吸附, 評述
Key words:   In vivo electrochemistry, Microelectrode, Protein nonspecific adsorption, Antifouling, Review
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目錄

活體微電極抗蛋白質吸附的研究進展

馮濤濤, 張帥, 張麗, 張美寧

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