BrainGate: An Intracortical Brain-Computer Interface for the Restoration of Communication and Functional Independence for People with Paralysis

2023 11th International Winter Conference on Brain-Computer Interface (BCI) Pub Date : 2023-02-20 DOI:10.1109/BCI57258.2023.10078547

Daniel B. Rubin, L. Hochberg

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Abstract

Intracortical brain computer interfaces (iBCIs) have the potential to restore and maintain communication, mobility, and functional independence for people living with paralysis due to neurologic disease or injury. The BrainGate Neural Interface System utilizes one to four microelectrode arrays chronically implanted in motor cortex to acquire the neural signals associated with intended movement. A real-time decoding system processes these signals, allowing the user to control a computer or other assistive device by attempting to or thinking about moving. Participants in the ongoing BrainGate2 clinical trial have been able to control a personal computer, robotic limb, and even their own paralyzed extremity through pairing with functional electrical stimulation. The BrainGate system has enabled increasingly facile communication through highly accurate decoding of point and click cursor control and intended handwriting. Ongoing research is focused on improving communication rates by decoding intended speech and optimizing mobility through the control of wearable robotic technology.

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脑门:用于瘫痪患者恢复沟通和功能独立的皮质内脑机接口

皮质内脑机接口(ibci)具有恢复和维持因神经系统疾病或损伤而瘫痪的人的沟通、活动和功能独立性的潜力。BrainGate神经接口系统利用一到四个长期植入运动皮层的微电极阵列来获取与预期运动相关的神经信号。实时解码系统处理这些信号，允许用户通过尝试或思考移动来控制计算机或其他辅助设备。正在进行的BrainGate2临床试验的参与者已经能够通过配对功能性电刺激来控制个人电脑、机械肢体，甚至他们自己瘫痪的肢体。BrainGate系统通过对点、点击光标控制和手写的高度精确解码，使通信变得越来越方便。正在进行的研究重点是通过解码预期语音来提高通信速率，并通过可穿戴机器人技术的控制来优化移动性。

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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2023 11th International Winter Conference on Brain-Computer Interface (BCI)

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