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Human Somatosensory Cortex Is Modulated during Motor Planning

Daniel J. Gale, J. Randall Flanagan, Jason P. Gallivan

2021Journal of Neuroscience88 citationsDOIOpen Access PDF

Abstract

Recent data and motor control theory argues that movement planning involves preparing the neural state of primary motor cortex (M1) for forthcoming action execution. Theories related to internal models, feedback control, and predictive coding also emphasize the importance of sensory prediction (and processing) before (and during) the movement itself, explaining why motor-related deficits can arise from damage to primary somatosensory cortex (S1). Motivated by this work, here we examined whether motor planning, in addition to changing the neural state of M1, changes the neural state of S1, preparing it for the sensory feedback that arises during action. We tested this idea in two human functional MRI studies (N = 31, 16 females) involving delayed object manipulation tasks, focusing our analysis on premovement activity patterns in M1 and S1. We found that the motor effector to be used in the upcoming action could be decoded, well before movement, from neural activity in M1 in both studies. Critically, we found that this effector information was also present, well before movement, in S1. In particular, we found that the encoding of effector information in area 3b (S1 proper) was linked to the contralateral hand, similarly to that found in M1, whereas in areas 1 and 2 this encoding was present in both the contralateral and ipsilateral hemispheres. Together, these findings suggest that motor planning not only prepares the motor system for movement but also changes the neural state of the somatosensory system, presumably allowing it to anticipate the sensory information received during movement.

Topics & Concepts

Somatosensory systemSensory systemNeuroscienceMotor systemPrimary motor cortexMotor controlPsychologyMotor cortexSupplementary motor areaPosterior parietal cortexNeural correlates of consciousnessFunctional magnetic resonance imagingCognitionStimulationEEG and Brain-Computer InterfacesMotor Control and AdaptationNeural dynamics and brain function