Glass nano/micron pipette-based ion current rectification sensing technology for single cell/in vivo analysis

IF 3.6 3区 化学 Q2 CHEMISTRY, ANALYTICAL
Analyst Pub Date : 2024-09-12 DOI:10.1039/D4AN00899E
Wei Yi, Junxiong Xiao, Zhenyu Shi, Changbo Zhang, Lanhua Yi, Yebo Lu and Xingzhu Wang
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Abstract

Glass nano/micron pipettes, owing to their easy preparation, unique confined space at the tip, and modifiable inner surface of the tip, can capture the ion current signal caused by a single entity, making them widely used in the construction of highly sensitive and highly selective electrochemical sensors for single entity analysis. Compared with other solid-state nanopores, their conical nano-tip causes less damage to cells when inserted into them, thereby becoming a powerful tool for the in situ analysis of important substances in cells. However, glass nanopipettes have some shortcomings, such as poor mechanical properties, difficulty in precise preparation (aperture less than 50 nm), and easy blockage during complex real sample detection, limiting their practicability. Therefore, in recent years, researchers have conducted a series of studies on glass micropipettes. Ionic current rectification technology is a novel electrochemical analysis technique. Compared with traditional electrochemical analysis methods, it does not generate redox products during the detection process; therefore, it can not only be used for the determination of non-electrochemically active substances, but also causes less damage to the cell/living body in situ analysis, becoming a powerful analysis technology for the in situ analysis of cells/in vivo in recent years. In this review, we summarize the preparation and functionalization of glass nano/micron pipettes and introduce the sensing mechanisms of two electrochemical sensing platforms constructed using glass nano/micron pipette-based ion current rectification sensing technology as well as their applications in single cell/in vivo analysis, existing problems, and future prospects.

Abstract Image

基于玻璃纳米/微米移液管的离子电流整流传感技术,用于单细胞/活体分析
玻璃纳米/微米移液器因其易于制备、独特的顶端密闭空间和可修饰的顶端内表面,具有捕捉单体引起的离子电流信号的能力,使其广泛应用于构建高灵敏度和高选择性的单体分析电化学传感器。与其他固态纳米孔相比,其锥形纳米尖端在插入细胞时对细胞的损伤较小,因此已成为细胞内重要物质原位分析的有力工具。然而,玻璃纳米吸头也存在一些缺点,如机械性能差、难以精确制备(孔径小于 50 nm)、在复杂的实际样品检测过程中容易堵塞等,限制了其实用性。因此,近年来研究人员对玻璃微量移液器进行了一系列研究。离子电流整流技术是一种新型的电化学分析技术。与传统的电化学分析方法相比,它在检测过程中不产生氧化还原产物,不仅可用于非电化学活性物质的测定,而且对原位分析的细胞/活体损伤较小,成为近年来细胞和活体原位分析的有力分析技术。在这篇综述中,我们总结了玻璃纳米/微米移液器的制备和功能化,介绍了基于玻璃纳米/微米移液器离子电流整流传感技术构建的两种电化学传感平台的传感机理,以及它们在单细胞/体内分析中的应用、存在的问题和未来展望。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Analyst
Analyst 化学-分析化学
CiteScore
7.80
自引率
4.80%
发文量
636
审稿时长
1.9 months
期刊介绍: The home of premier fundamental discoveries, inventions and applications in the analytical and bioanalytical sciences
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