Abstract
BackgroundMotor imagery (MI) with real-time neurofeedback could be a viable approach, e.g., in rehabilitation of cerebral stroke. Magnetoencephalography (MEG) noninvasively measures electric brain activity at high temporal resolution and is well-suited for recording oscillatory brain signals. MI is known to modulate 10- and 20-Hz oscillations in the somatomotor system. In order to provide accurate feedback to the subject, the most relevant MI-related features should be extracted from MEG data. In this study, we evaluated several MEG signal features for discriminating between left- and right-hand MI and between MI and rest.MethodsMEG was measured from nine healthy participants imagining either left- or right-hand finger tapping according to visual cues. Data preprocessing, feature extraction and classification were performed offline. The evaluated MI-related features were power spectral density (PSD), Morlet wavelets, short-time Fourier transform (STFT), common spatial patterns (CSP), filter-bank common spatial patterns (FBCSP), spatio—spectral decomposition (SSD), and combined SSD+CSP, CSP+PSD, CSP+Morlet, and CSP+STFT. We also compared four classifiers applied to single trials using 5-fold cross-validation for evaluating the classification accuracy and its possible dependence on the classification algorithm. In addition, we estimated the inter-session left-vs-right accuracy for each subject.ResultsThe SSD+CSP combination yielded the best accuracy in both left-vs-right (mean 73.7%) and MI-vs-rest (mean 81.3%) classification. CSP+Morlet yielded the best mean accuracy in inter-session left-vs-right classification (mean 69.1%). There were large inter-subject differences in classification accuracy, and the level of the 20-Hz suppression correlated significantly with the subjective MI-vs-rest accuracy. Selection of the classification algorithm had only a minor effect on the results.ConclusionsWe obtained good accuracy in sensor-level decoding of MI from single-trial MEG data. Feature extraction methods utilizing both the spatial and spectral profile of MI-related signals provided the best classification results, suggesting good performance of these methods in an online MEG neurofeedback system.
Highlights
Motor imagery (MI) augmented with real-time feedback of the modulated brain activity could be an effective method for rehabilitation of motor function in patients who are unable to perform overt limb movements [1,2,3]
The 0.5-s delay in the beginning of MI is due to the reaction time
It has been reported that some subjects are brain—computer interfaces (BCI) illiterate, i.e. not able to operate an MI-BCI despite excessive training [51,52], and our results suggest that insufficient mu rhythm suppression can partially explain this finding
Summary
Motor imagery (MI) augmented with real-time feedback of the modulated brain activity could be an effective method for rehabilitation of motor function in patients who are unable to perform overt limb movements [1,2,3]. MI, as well as overt motor acts and somatosensory stimulation, is associated with a suppression of 10- and 20-Hz oscillations over the sensorimotor cortex and a rebound of these after the end of MI, motor activity or stimulation [4]. These oscillations are often referred to as the mu rhythm, or more generally as sensorimotor rhythms (SMR). ERD and ERS during overt hand movements were detected in magnetoencephalography (MEG) by Salmelin and Hari [5]. We evaluated several MEG signal features for discriminating between left- and right-hand MI and between MI and rest
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