Historical perspectives, challenges, and future directions of implantable brain-computer interfaces for sensorimotor applications.

Bioelectronic medicine Pub Date : 2021-09-22 DOI:10.1186/s42234-021-00076-6

Santosh Chandrasekaran, Matthew Fifer, Stephan Bickel, Luke Osborn, Jose Herrero, Breanne Christie, Junqian Xu, Rory K J Murphy, Sandeep Singh, Matthew F Glasser, Jennifer L Collinger, Robert Gaunt, Ashesh D Mehta, Andrew Schwartz, Chad E Bouton

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Abstract

Almost 100 years ago experiments involving electrically stimulating and recording from the brain and the body launched new discoveries and debates on how electricity, movement, and thoughts are related. Decades later the development of brain-computer interface technology began, which now targets a wide range of applications. Potential uses include augmentative communication for locked-in patients and restoring sensorimotor function in those who are battling disease or have suffered traumatic injury. Technical and surgical challenges still surround the development of brain-computer technology, however, before it can be widely deployed. In this review we explore these challenges, historical perspectives, and the remarkable achievements of clinical study participants who have bravely forged new paths for future beneficiaries.

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用于感应运动应用的植入式脑机接口的历史视角、挑战和未来方向。

近 100 年前，通过对大脑和人体进行电刺激和记录的实验，人们对电、运动和思维之间的关系有了新的发现和讨论。几十年后，脑-计算机接口技术开始发展，目前应用范围广泛。其潜在用途包括为被锁定的病人提供辅助交流，以及恢复那些与疾病作斗争或遭受创伤的人的感觉运动功能。然而，在广泛应用脑机技术之前，其发展仍面临着技术和手术方面的挑战。在这篇综述中，我们将探讨这些挑战、历史视角以及临床研究参与者的卓越成就，他们勇敢地为未来的受益者开辟了新的道路。

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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