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探索神经反馈训练对上肢BMI力量增强的作用:一项初步研究。

Exploring Neurofeedback Training for BMI Power Augmentation of Upper Limbs: A Pilot Study.

作者信息

Liang Hongbo, Maedono Shota, Yu Yingxin, Liu Chang, Ueda Naoya, Li Peirang, Zhu Chi

机构信息

Maebashi Institute of Technology, Center for Regional Collaboration, 460-1 Kamisadori, Maebashi, Gunma 371-0816, Japan.

Department of Systems Life Engineering, Graduate School of Engineering, Maebashi Institute of Technology, 460-1 Kamisadori, Maebashi, Gunma 371-0816, Japan.

出版信息

Entropy (Basel). 2021 Apr 9;23(4):443. doi: 10.3390/e23040443.

DOI:10.3390/e23040443
PMID:33918833
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8068929/
Abstract

Electroencephalography neurofeedback (EEG-NFB) training can induce changes in the power of targeted EEG bands. The objective of this study is to enhance and evaluate the specific changes of EEG power spectral density that the brain-machine interface (BMI) users can reliably generate for power augmentation through EEG-NFB training. First, we constructed an EEG-NFB training system for power augmentation. Then, three subjects were assigned to three NFB training stages, based on a 6-day consecutive training session as one stage. The subjects received real-time feedback from their EEG signals by a robotic arm while conducting flexion and extension movement with their elbow and shoulder joints, respectively. EEG signals were compared with each NFB training stage. The training results showed that EEG beta (12-40 Hz) power increased after the NFB training for both the elbow and the shoulder joints' movements. EEG beta power showed sustained improvements during the 3-stage training, which revealed that even the short-term training could improve EEG signals significantly. Moreover, the training effect of the shoulder joints was more obvious than that of the elbow joints. These results suggest that NFB training can improve EEG signals and clarify the specific EEG changes during the movement. Our results may even provide insights into how the neural effects of NFB can be better applied to the BMI power augmentation system and improve the performance of healthy individuals.

摘要

脑电图神经反馈(EEG-NFB)训练可诱发目标脑电频段功率的变化。本研究的目的是增强并评估脑机接口(BMI)用户通过EEG-NFB训练能够可靠地产生功率增强的脑电功率谱密度的特定变化。首先,我们构建了一个用于功率增强的EEG-NFB训练系统。然后,将三名受试者分配到三个NFB训练阶段,以连续6天的训练课程为一个阶段。受试者在分别用肘部和肩关节进行屈伸运动时,通过机械臂接收来自其脑电信号的实时反馈。将脑电信号与每个NFB训练阶段进行比较。训练结果表明,对于肘部和肩关节的运动,NFB训练后脑电β(12 - 40赫兹)功率均增加。在三阶段训练期间,脑电β功率持续改善,这表明即使是短期训练也能显著改善脑电信号。此外,肩关节的训练效果比肘关节更明显。这些结果表明,NFB训练可以改善脑电信号,并明确运动过程中脑电的具体变化。我们的结果甚至可能为如何将NFB的神经效应更好地应用于BMI功率增强系统以及提高健康个体的表现提供见解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e175/8068929/57f6a6632fa2/entropy-23-00443-g011.jpg
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The Cybathlon BCI race: Successful longitudinal mutual learning with two tetraplegic users.Cybathlon脑机接口竞赛:两位四肢瘫痪用户的成功纵向互学。
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Target Speaker Detection with Concealed EEG Around the Ear.
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