AI Article Synopsis
- Motor commands for arm and hand movements usually come from the opposite side of the brain (contralateral motor cortex), but the same side (ipsilateral motor cortex) also shows some activity related to these movements, leading to confusion in previous research.
- This study used implanted microelectrodes to record neural activity from two subjects while they performed arm and hand movements in a virtual setting, aiming to understand the strength and independence of these motor signals.
- Results revealed that while ipsilateral arm movement is represented independently, it is weaker than contralateral movement; however, grasping movements were found to be similarly represented in both hands, raising new questions about how the motor cortex coordinates arm and hand functions differently.
Article Abstract
Motor commands for the arm and hand generally arise from the contralateral motor cortex, where most of the relevant corticospinal tract originates. However, the ipsilateral motor cortex shows activity related to arm movement despite the lack of direct connections. The extent to which the activity related to ipsilateral movement is independent from that related to contralateral movement is unclear based on conflicting conclusions in prior work. Here we investigate bilateral arm and hand movement tasks completed by two human subjects with intracortical microelectrode arrays implanted in the left hand and arm area of the motor cortex. Neural activity was recorded while they attempted to perform arm and hand movements in a virtual environment. This enabled us to quantify the strength and independence of motor cortical activity related to continuous movements of each arm. We also investigated the subjects' ability to control both arms through a brain-computer interface. Through a number of experiments, we found that ipsilateral arm movement was represented independently of, but more weakly than, contralateral arm movement. However, the representation of grasping was correlated between the two hands. This difference between hand and arm representation was unexpected and poses new questions about the different ways the motor cortex controls the hands and arms.
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| http://dx.doi.org/10.1093/cercor/bhaa120 | DOI Listing |
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