电化学在行动-工程神经元对电微刺激的反应

IF 1.7 Q4 ELECTROCHEMISTRY
M. Orazem, K. Otto, Christopher L. Alexander
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引用次数: 0

摘要

脑神经调控彻底改变了神经疾病和损伤的医学治疗;然而,现有的治疗方法在临床应用范围上是有限的。大多数现有的治疗方法都是通过植入的大电极来提供的,这些大电极要么位于大脑顶部,要么直接位于大脑内部。对这些设备传播的有效电场的估计通常涵盖数千到数百万个神经元。不幸的是,一些神经系统疾病和损伤需要更高精度的刺激场。已开发出具有数百个紧密间隔通道的下一代微神经调节装置(~102-103μm2表面积)。这些设备可能能够以双相、电荷平衡的小振幅方波的形式提供电微刺激,向人类受试者提供显著的行为相关信息。然而,缺乏将其纳入安全性和临床使用的知识。神经调控是一个科学、医学和生物工程领域,包括植入式和非植入式技术,电或化学技术,作用于神经界面,改善人类生活。我们的研究小组合作研究通过电微刺激进行的神经调控。我们的主要发展目标是大脑神经调控。本文着重介绍了电化学在神经调控领域的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Electrochemistry in Action-Engineering the Neuronal Response to Electrical Microstimulation
Brain neuromodulation has revolutionized the medical treatment of neurological diseases and injuries; however, existing therapies are limited in their clinical scope of application. Most existing therapies are delivered through implanted macroelectrodes that reside either on top of or directly inside the brain. Estimates of the effective electric field spread from these devices generally span from thousands to millions of individual neurons. Unfortunately, some neurological diseases and injuries require stimulation fields of higher precision. Next-generation microneuromodulation devices (˜102 – 103 μm2 surface area) have been developed with hundreds of closely spaced channels. These devices may be able to provide electrical microstimulation in the form of biphasic, charge-balanced small amplitude square waves that provide salient, behaviorally relevant information to human subjects. However, there is a lack of knowledge incorporated into their safety and clinical use. Neuromodulation is a field of science, medicine, and bioengineering that encompasses implantable and non-implantable technologies, electrical or chemical, that act upon neural interfaces to improve life for humanity. Our research groups collaboratively investigate neuromodulation performed via electrical microstimulation. Our primary development target is brain neuromodulation. In this article we highlight the application of electrochemistry to the field of neuromodulation.
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来源期刊
CiteScore
2.10
自引率
5.60%
发文量
62
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