Abstract
The development of technologies for the treatment of movement disorders, like stroke, is still of particular interest in brain-computer interface (BCI) research. In this context, source localization methods (SLMs), that reconstruct the cerebral origin of brain activity measured outside the head, e.g., via electroencephalography (EEG), can add a valuable insight into the current state and progress of the treatment. However, in BCIs SLMs were often solely considered as advanced signal processing methods that are compared against other methods based on the classification performance alone. Though, this approach does not guarantee physiological meaningful results. We present an empirical comparison of three established distributed SLMs with the aim to use one for single-trial movement prediction. The SLMs wMNE, sLORETA, and dSPM were applied on data acquired from eight subjects performing voluntary arm movements. Besides the classification performance as quality measure, a distance metric was used to asses the physiological plausibility of the methods. For the distance metric, which is usually measured to the source position of maximum activity, we further propose a variant based on clusters that is better suited for the single-trial case in which several sources are likely and the actual maximum is unknown. The two metrics showed different results. The classification performance revealed no significant differences across subjects, indicating that all three methods are equally well-suited for single-trial movement prediction. On the other hand, we obtained significant differences in the distance measure, favoring wMNE even after correcting the distance with the number of reconstructed clusters. Further, distance results were inconsistent with the traditional method using the maximum, indicating that for wMNE the point of maximum source activity often did not coincide with the nearest activation cluster. In summary, the presented comparison might help users to select an appropriate SLM and to understand the implications of the selection. The proposed methodology pays attention to the particular properties of distributed SLMs and can serve as a framework for further comparisons.
Highlights
Suffering a stroke nowadays often means lifelong impairments in daily living
While no significant differences between the source localization methods (SLMs) were obtained in terms of classification performance, our distance metric favored weighted Minimum Norm Estimate (wMNE)
We suggested to consider the classification performance, and a distance metric to compare SLMs, knowing well that both may lead to different results
Summary
Suffering a stroke nowadays often means lifelong impairments in daily living. Especially the upper limb recovery rate is not satisfactory, given that over 60% of the patients still have dysfunctions 6 month post-stroke (Kwakkel et al, 2003). Machine learning algorithms are applied to EEG singletrials to detect, e.g., movement preparation in advance of the intended movement onset. This knowledge can be integrated in technically assisted neuro-motor rehabilitation (Kirchner et al, 2013a). Penfield and colleagues proposed the first somatotopic map of the human primary motor cortex (Penfield and Boldrey, 1937; Penfield and Rasmussen, 1950) obtained from electrical stimulation Up to now, this mapping has extensively been studied, with noninvasive high resolution neuro-imaging methods, and a lot of evidence has accumulated that distinct brain regions for the body parts exist despite an overlap (e.g., Meier et al, 2008; Plow et al, 2010). Single-trial decoding to support neuromotor rehabilitation has time requirements, and can benefit in particular from an increased spatial resolution
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