Abstract
BackgroundMotor imagery (MI) induced EEG patterns are widely used as control signals for brain-computer interfaces (BCIs). Kinetic and kinematic factors have been proved to be able to change EEG patterns during motor execution and motor imagery. However, to our knowledge, there is still no literature reporting an effective online MI-BCI using kinetic factor regulated EEG oscillations. This study proposed a novel MI-BCI paradigm in which users can online output multiple commands by imagining clenching their right hand with different force loads.MethodsEleven subjects participated in this study. During the experiment, they were asked to imagine clenching their right hands with two different force loads (30% maximum voluntary contraction (MVC) and 10% MVC). Multi-Common spatial patterns (Multi-CSPs) and support vector machines (SVMs) were used to build the classifier for recognizing three commands corresponding to high load MI, low load MI and relaxed status respectively. EMG were monitored to avoid voluntary muscle activities during the BCI operation. The event-related spectral perturbation (ERSP) method was used to analyse EEG variation during multiple load MI tasks.ResultsAll subjects were able to drive BCI systems using motor imagery of different force loads in online experiments. We achieved an average online accuracy of 70.9%, with the highest accuracy of 83.3%, which was much higher than the chance level (33%). The event-related desynchronization (ERD) phenomenon during high load tasks was significantly higher than it was during low load tasks both in terms of intensity at electrode positions C3 (p < 0.05) and spatial distribution.ConclusionsThis paper demonstrated the feasibility of the proposed MI-BCI paradigm based on multi-force loads on the same limb through online studies. This paradigm could not only enlarge the command set of MI-BCI, but also provide a promising approach to rehabilitate patients with motor disabilities.
Highlights
Motor imagery (MI) induced EEG patterns are widely used as control signals for brain-computer interfaces (BCIs)
We can observe that there are significant differences between ME tasks (p < 0.005, Paired T-test), while MI tasks show no significant differences (p > 0.05, Paired T-test). This result shows that the subjects who participated in our experiment successfully avoided muscle contractions during MI tasks
Considering commands in traditional Motor imagery based BCI (MI-BCI) always correspond to separate limbs, this study provides a means of extending MI-BCI commands
Summary
Motor imagery (MI) induced EEG patterns are widely used as control signals for brain-computer interfaces (BCIs). To our knowledge, there is still no literature reporting an effective online MI-BCI using kinetic factor regulated EEG oscillations. Several studies have confirmed that MI-BCI is an effective method for post stroke rehabilitation [5,6,7]. In these studies, a variety of functional devices, such as functional electrical stimulation (FES) [8], rehabilitation robots [9], etc., were used in combination with MI-BCI to construct a close loop neurofeedback from the sensorimotor cortex to paralyzed limbs [8,9,10,11]
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