Subject inefficiency phenomenon of motor imagery brain-computer interface: Influence factors and potential solutions

Brain Science Advances Pub Date : 2020-09-01 DOI:10.26599/BSA.2020.9050021

Rui Zhang, Fali Li, Tao Zhang, D. Yao, Peng Xu

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引用次数: 23

Abstract

Motor imagery brain–computer interfaces (MI‐BCIs) have great potential value in prosthetics control, neurorehabilitation, and gaming; however, currently, most such systems only operate in controlled laboratory environments. One of the most important obstacles is the MI‐BCI inefficiency phenomenon. The accuracy of MI‐BCI control varies significantly (from chance level to 100% accuracy) across subjects due to the not easily induced and unstable MI‐related EEG features. An MI‐BCI inefficient subject is defined as a subject who cannot achieve greater than 70% accuracy after sufficient training time, and multiple survey results indicate that inefficient subjects account for 10%–50% of the experimental population. The widespread use of MI‐BCI has been seriously limited due to these large percentages of inefficient subjects. In this review, we summarize recent findings of the cause of MI‐BCI inefficiency from resting‐state brain function, task‐related brain activity, brain structure, and psychological perspectives. These factors help understand the reasons for inter‐subject MI‐BCI control performance variability, and it can be concluded that the lower resting‐state sensorimotor rhythm (SMR) is the key factor in MI‐BCI inefficiency, which has been confirmed by multiple independent laboratories. We then propose to divide MI‐BCI inefficient subjects into three categories according to the resting‐state SMR and offline/online accuracy to apply more accurate approaches to solve the inefficiency problem. The potential solutions include developing transfer learning algorithms, new experimental paradigms, mindfulness meditation practice, novel training strategies, and identifying new motor imagery‐related EEG features. To date, few studies have focused on improving the control accuracy of MI‐BCI inefficient subjects; thus, we appeal to the BCI community to focus more on this research area. Only by reducing the percentage of inefficient subjects can we create the opportunity to expand the value and influence of MI‐BCI.

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运动意象脑机接口的主体低效率现象:影响因素及可能的解决方法

运动图像脑机接口在假肢控制、神经康复和游戏方面具有巨大的潜在价值；然而，目前，大多数这样的系统只在受控的实验室环境中运行。最重要的障碍之一是MI‐BCI的低效现象。由于不易诱发和不稳定的MI相关脑电图特征，受试者的MI-BCI控制准确性差异很大（从偶然水平到100%准确性）。MI‐BCI低效受试者被定义为在足够的训练时间后不能达到70%以上准确率的受试者，多项调查结果表明，低效受试人占实验人群的10%-50%。由于大量低效受试者，MI‐BCI的广泛使用受到严重限制。在这篇综述中，我们从静息状态大脑功能、任务相关大脑活动、大脑结构和心理角度总结了MI-BCI低效的最新发现。这些因素有助于理解受试者间心肌梗死-脑机接口控制性能变异的原因，可以得出结论，较低的静息状态感觉运动节律（SMR）是心肌梗死-机接口低效的关键因素，这一点已得到多个独立实验室的证实。然后，我们建议根据静息状态SMR和离线/在线准确性将MI-BCI低效受试者分为三类，以应用更准确的方法来解决低效问题。潜在的解决方案包括开发迁移学习算法、新的实验范式、正念冥想练习、新的训练策略，以及识别新的运动图像相关的脑电图特征。到目前为止，很少有研究关注提高MI‐BCI低效受试者的控制准确性；因此，我们呼吁脑机接口社区更多地关注这一研究领域。只有降低低效受试者的百分比，我们才能创造机会扩大MI‐BCI的价值和影响力。

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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Brain Science Advances

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10 weeks