Jeong Hojun, Song Minsu, Jang Sung-Ho, Kim Jonghyun
School of Mechanical Engineering, Sungkyunkwan University, Suwon, Gyeonggi-do, 16419, Republic of Korea.
Department of Psychology, University of British Columbia, Vancouver, V6T 1Z4, Canada.
J Neuroeng Rehabil. 2025 Mar 18;22(1):61. doi: 10.1186/s12984-025-01597-w.
Motor imagery-based brain-computer interface (MI-BCI) is a promising solution for neurorehabilitation. Many studies proposed that reducing false positive (FP) feedback is crucial for inducing neural plasticity by BCI technology. However, the effect of FP feedback on cortical plasticity induction during MI-BCI training is yet to be investigated.
This study aims to validate the hypothesis that FP feedback affects the cortical plasticity of the user's MI during MI-BCI training by first comparing two different asynchronous MI-BCI paradigms (with and without FP feedback), and then comparing its effectiveness with that of conventional motor learning methods (passive and active training).
Twelve healthy volunteers and four patients with stroke participated in the study. We implemented two electroencephalogram-driven asynchronous MI-BCI systems with different feedback conditions. The feedback was provided by a hand exoskeleton robot performing hand open/close task. We assessed the hemodynamic responses in two different feedback conditions and compared them with two conventional motor learning methods using functional near-infrared spectroscopy with an event-related design. The cortical effects of FP feedback were analyzed in different paradigms, as well as in the same paradigm via statistical analysis.
The MI-BCI without FP feedback paradigm induced higher cortical activation in MI, focusing on the contralateral motor area, compared to the paradigm with FP feedback. Additionally, within the same paradigm providing FP feedback, the task period immediately following FP feedback elicited a lower hemodynamic response in the channel located over the contralateral motor area compared to the MI-BCI paradigm without FP feedback (p = 0.021 for healthy people; p = 0.079 for people with stroke). In contrast, task trials where there was no FP feedback just before showed a higher hemodynamic response, similar to the MI-BCI paradigm without FP feedback (p = 0.099 for healthy people, p = 0.084 for people with stroke).
FP feedback reduced cortical activation for the users during MI-BCI training, suggesting a potential negative effect on cortical plasticity. Therefore, minimizing FP feedback may enhance the effectiveness of rehabilitative MI-BCI training by promoting stronger cortical activation and plasticity, particularly in the contralateral motor area.
基于运动想象的脑机接口(MI-BCI)是神经康复领域一种很有前景的解决方案。许多研究表明,减少误报(FP)反馈对于通过脑机接口技术诱导神经可塑性至关重要。然而,FP反馈在MI-BCI训练过程中对皮质可塑性诱导的影响尚未得到研究。
本研究旨在验证以下假设:通过首先比较两种不同的异步MI-BCI范式(有无FP反馈),然后将其有效性与传统运动学习方法(被动和主动训练)进行比较,FP反馈会影响MI-BCI训练期间用户运动想象的皮质可塑性。
12名健康志愿者和4名中风患者参与了该研究。我们实施了两个具有不同反馈条件的脑电图驱动的异步MI-BCI系统。反馈由执行手张开/闭合任务的手部外骨骼机器人提供。我们评估了两种不同反馈条件下的血液动力学反应,并使用功能近红外光谱和事件相关设计将它们与两种传统运动学习方法进行比较。通过统计分析,在不同范式以及同一范式中分析了FP反馈的皮质效应。
与有FP反馈的范式相比,无FP反馈的MI-BCI范式在运动想象中诱导了更高的皮质激活,主要集中在对侧运动区。此外,在提供FP反馈的同一范式中,与无FP反馈的MI-BCI范式相比,FP反馈后紧接着的任务期在对侧运动区上方的通道中引起了较低的血液动力学反应(健康人为p = 0.021;中风患者为p = 0.079)。相比之下,之前没有FP反馈的任务试验显示出较高的血液动力学反应,类似于无FP反馈的MI-BCI范式(健康人为p = 0.099,中风患者为p = 0.084)。
FP反馈在MI-BCI训练期间降低了用户的皮质激活,表明对皮质可塑性可能有负面影响。因此,尽量减少FP反馈可能通过促进更强的皮质激活和可塑性来提高康复性MI-BCI训练的有效性,特别是在对侧运动区。
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