Continuous Force Decoding from Deep Brain Local Field Potentials for Brain Computer Interfacing.

International IEEE/EMBS Conference on Neural Engineering : [proceedings]. International IEEE EMBS Conference on Neural Engineering Pub Date : 2017-01-01 DOI:10.1109/NER.2017.8008367

Syed A Shah, Huiling Tan, Peter Brown

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引用次数: 11

Abstract

Current Brain Computer Interface (BCI) systems are limited by relying on neuronal spikes and decoding limited to kinematics only. For a BCI system to be practically useful, it should be able to decode brain information on a continuous basis with low latency. This study investigates if force can be decoded from local field potentials (LFP) recorded with deep brain electrodes located at the Subthalamic nucleus (STN) using data from 5 patients with Parkinson's disease, on a continuous basis with low latency. A Wiener-Cascade (WC) model based decoder was proposed using both time-domain and frequency-domain features. The results suggest that high gamma band (300-500Hz) activity, in addition to the beta (13-30Hz) and gamma band (55-90Hz) activity is the most informative for force prediction but combining all features led to better decoding performance. Furthermore, LFP signals preceding the force output by up to 1256 milliseconds were found to be predictive of the force output.

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脑深部局部场电位连续力解码的脑机接口。

目前的脑机接口(BCI)系统受限于依赖神经元峰值和解码仅局限于运动学。为了使BCI系统在实际应用中发挥作用，它应该能够以低延迟的方式连续解码大脑信息。本研究利用5例帕金森病患者的低潜伏期连续数据，研究是否可以从位于丘脑下核(STN)的脑深部电极记录的局部场电位(LFP)中解码力。提出了一种基于维纳级联(Wiener-Cascade, WC)模型的时域和频域解码器。结果表明，除了beta (13-30Hz)和gamma波段(55-90Hz)活动外，高gamma波段(300-500Hz)活动对力预测的信息量最大，但将所有特征结合起来会导致更好的解码性能。此外，LFP信号在力输出之前的1256毫秒被发现是力输出的预测。

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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International IEEE/EMBS Conference on Neural Engineering : [proceedings]. International IEEE EMBS Conference on Neural Engineering

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