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用于实时监测异质多巴胺释放的微制造 FSCV 兼容微电极阵列。

Microfabricated FSCV-compatible microelectrode array for real-time monitoring of heterogeneous dopamine release.

机构信息

Joint Department of Biomedical Engineering, University of North Carolina at Chapel Hill, Chapel Hill, NC, USA.

出版信息

Analyst. 2010 Jul;135(7):1556-63. doi: 10.1039/c0an00114g. Epub 2010 May 13.

DOI:10.1039/c0an00114g
PMID:20464031
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2975426/
Abstract

Fast scan cyclic voltammetry (FSCV) has been used previously to detect neurotransmitter release and reuptake in vivo. An advantage that FSCV has over other electrochemical techniques is its ability to distinguish neurotransmitters of interest (i.e. monoamines) from their metabolites using their respective characteristic cyclic voltammograms. While much has been learned with this technique, it has generally only been used in a single working electrode arrangement. Additionally, traditional electrode fabrication techniques tend to be difficult and somewhat irreproducible. Described in this report is a fabrication method for a FSCV compatible microelectrode array (FSCV-MEA) that is capable of functioning in vivo. The microfabrication techniques employed here allow for better reproducibility than traditional fabrication methods of carbon fiber microelectrodes, and enable batch fabrication of electrode arrays. The reproducibility and electrochemical qualities of the probes were assessed along with crosstalk in vitro. Heterogeneous release of electrically evoked dopamine was observed in real-time in the striatum of an anesthetized rat using the FSCV-MEA. The heterogeneous effects of pharmacology on the striatum were also observed and shown to be consistent across multiple animals.

摘要

快速扫描循环伏安法(FSCV)以前曾被用于检测体内神经递质的释放和重摄取。FSCV 相对于其他电化学技术的一个优势是,它能够使用各自的特征循环伏安图区分感兴趣的神经递质(即单胺类)与其代谢物。尽管这项技术已经取得了很大的进展,但它通常只在单个工作电极排列中使用。此外,传统的电极制造技术往往比较困难,而且有些不可重复。本报告介绍了一种可用于体内的 FSCV 兼容微电极阵列(FSCV-MEA)的制造方法。这里采用的微制造技术比传统的碳纤维微电极制造方法具有更好的可重复性,并能够批量制造电极阵列。还评估了探针的重现性和电化学质量以及体外串扰。使用 FSCV-MEA 在麻醉大鼠的纹状体中实时观察到电刺激诱发的多巴胺的不均匀释放。还观察到药理学对纹状体的不均匀影响,并在多个动物中表现出一致性。

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