Nanyang Institute of Technology in Health and Medicine, Interdisciplinary Graduate School, Nanyang Technological University, 50 Nanyang Avenue, Singapore 639798, Singapore.
J Neural Eng. 2017 Aug;14(4):046008. doi: 10.1088/1741-2552/aa6baf.
In electroencephalography (EEG)-based brain-computer interface (BCI) systems for motor control tasks the conventional practice is to decode motor intentions by using scalp EEG. However, scalp EEG only reveals certain limited information about the complex tasks of movement with a higher degree of freedom. Therefore, our objective is to investigate the effectiveness of source-space EEG in extracting relevant features that discriminate arm movement in multiple directions.
We have proposed a novel feature extraction algorithm based on supervised factor analysis that models the data from source-space EEG. To this end, we computed the features from the source dipoles confined to Brodmann areas of interest (BA4a, BA4p and BA6). Further, we embedded class-wise labels of multi-direction (multi-class) source-space EEG to an unsupervised factor analysis to make it into a supervised learning method.
Our approach provided an average decoding accuracy of 71% for the classification of hand movement in four orthogonal directions, that is significantly higher (>10%) than the classification accuracy obtained using state-of-the-art spatial pattern features in sensor space. Also, the group analysis on the spectral characteristics of source-space EEG indicates that the slow cortical potentials from a set of cortical source dipoles reveal discriminative information regarding the movement parameter, direction.
This study presents evidence that low-frequency components in the source space play an important role in movement kinematics, and thus it may lead to new strategies for BCI-based neurorehabilitation.
在基于脑电图(EEG)的运动控制任务脑机接口(BCI)系统中,传统的做法是使用头皮 EEG 解码运动意图。然而,头皮 EEG 只能揭示运动这一具有更高自由度的复杂任务的某些有限信息。因此,我们的目标是研究源空间 EEG 在提取区分多方向手臂运动的相关特征方面的有效性。
我们提出了一种基于监督因子分析的新特征提取算法,该算法对源空间 EEG 的数据进行建模。为此,我们从感兴趣的布罗德曼区域(BA4a、BA4p 和 BA6)的源偶极子中计算特征。此外,我们将多方向(多类)源空间 EEG 的类别标签嵌入到无监督因子分析中,使其成为一种监督学习方法。
我们的方法为四向正交手部运动的分类提供了 71%的平均解码精度,明显高于(>10%)在传感器空间中使用最先进的空间模式特征获得的分类精度。此外,对源空间 EEG 频谱特征的组分析表明,一组皮质源偶极子的慢皮质电位揭示了与运动参数、方向有关的判别信息。
这项研究表明,源空间中的低频成分在运动运动学中起着重要作用,因此它可能为基于 BCI 的神经康复提供新策略。
