Enhancing motor rehabilitation using a hybrid BCI paradigm: integrating high-frequency SSVEP with action observation and motor imagery

IF 3.4 4区医学 Q2 CLINICAL NEUROLOGY

Journal of Neurorestoratology Pub Date : 2025-07-18 DOI:10.1016/j.jnrt.2025.100238

Zhaohui Li , Meng Li , Xiaorong Gao , Hongyan Cui , Xiaogang Chen

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引用次数: 0

Abstract

Background

Both action observation (AO) and motor imagery (MI) can elicit activity in mirror neurons and the motor cortex. Therefore, brain–computer interface (BCI) systems based on AO and MI hold broad application prospects in the field of motor rehabilitation. An increasing number of studies have incorporated steady-state visual evoked potentials (SSVEP) into AO or MI paradigms to construct hybrid BCI systems and enhance robustness of the systems.

Methods

In this study, AO, MI, and AO combined with MI experiments were designed, based on a SSVEP paradigm. In the AO experiment, subjects were required to observe alternating and flickering fisted- and extended-hand pictures. In the MI task, subjects were required to perform MI tasks while focusing on flickering extended-hand pictures. In the AO combined with MI experiment, subjects were required to execute the same task for the AO experiment while simultaneously perform the MI task. Task-discriminant component analysis and Tikhonov regularizing common spatio-spectral pattern algorithms were used to separately process inputs from the two modalities, with the system ultimately outputting a fusion result.

Results

The results found that AO combined with MI and MI alone more effectively activated the motor cortex compared with AO alone. The fusion classification accuracy of the proposed hybrid paradigm reached 86.42% ± 8.42%, 88.54% ± 10.31%, and 88.91% ± 9.61% for AO, MI, and AO combined with MI, respectively.

Conclusion

This study provided an alternative for the construction of a more robust and comfortable rehabilitation system.

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使用混合脑机接口模式增强运动康复：将高频SSVEP与动作观察和运动想象相结合

动作观察（AO）和运动想象（MI）都可以引起镜像神经元和运动皮层的活动。因此，基于AO和MI的脑机接口系统在运动康复领域具有广阔的应用前景。越来越多的研究将稳态视觉诱发电位（SSVEP）引入到AO或MI范式中，以构建混合脑机接口系统并增强系统的鲁棒性。方法本研究基于SSVEP范式，设计了AO、MI和AO联合MI实验。在AO实验中，受试者被要求观察交替闪烁的拳头和伸出的手的图片。在MI任务中，受试者被要求在专注于闪烁的伸出的手的图片时执行MI任务。在AO与MI联合实验中，受试者被要求在执行MI任务的同时执行AO实验的相同任务。使用任务判别成分分析和Tikhonov正则化公共空间光谱模式算法分别处理两种模式的输入，最终输出融合结果。结果AO联合心肌梗死和单独心肌梗死对运动皮层的激活作用均优于AO。AO、MI和AO合并MI的融合分类准确率分别为86.42%±8.42%、88.54%±10.31%和88.91%±9.61%。结论本研究为构建更加稳健舒适的康复系统提供了一种选择。

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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