皮质电图运动-图像脑机接口中学习的神经关联。

IF 1.8 Q3 ENGINEERING, BIOMEDICAL
Tim M Blakely, Jared D Olson, Kai J Miller, Rajesh P N Rao, Jeffrey G Ojemann
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引用次数: 17

摘要

人类受试者可以学习通过调制初级运动(M1)高伽马活动(信号功率在75-200赫兹范围内)来控制一维皮质电图(ECoG)脑机接口(BCI)。然而,在新的脑机接口技能习得过程中,信号的稳定性和动态尚未得到研究。在本研究中,我们报告了脑机接口训练过程中高伽马控制信号演化的3个特征期:初始阶段,任务精度较低,伽马谱中相应的低功率调制;随后是任务精度提高的第二阶段,活动和休息之间的平均功率间隔增加;最后是任务精度高的阶段,功率间隔稳定(或减小),试验间方差减小。这些发现可能会对脑机接口控制算法的设计和实现产生影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Neural correlates of learning in an electrocorticographic motor-imagery brain-computer interface.

Neural correlates of learning in an electrocorticographic motor-imagery brain-computer interface.

Neural correlates of learning in an electrocorticographic motor-imagery brain-computer interface.

Neural correlates of learning in an electrocorticographic motor-imagery brain-computer interface.

Human subjects can learn to control a one-dimensional electrocorticographic (ECoG) brain-computer interface (BCI) using modulation of primary motor (M1) high-gamma activity (signal power in the 75-200 Hz range). However, the stability and dynamics of the signals over the course of new BCI skill acquisition have not been investigated. In this study, we report 3 characteristic periods in evolution of the high-gamma control signal during BCI training: initial, low task accuracy with corresponding low power modulation in the gamma spectrum, followed by a second period of improved task accuracy with increasing average power separation between activity and rest, and a final period of high task accuracy with stable (or decreasing) power separation and decreasing trial-to-trial variance. These findings may have implications in the design and implementation of BCI control algorithms.

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来源期刊
CiteScore
4.00
自引率
9.50%
发文量
14
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