Cerebellar Output Shapes Cortical Preparatory Activity During Motor Adaptation

Overview

Journal Nat Commun

Specialty Biology

Date 2025 Mar 16

PMID 40089504

Authors

Sharon Israely

Hugo Ninou

Ori Rajchert

Lee Elmaleh

Ran Harel

Firas Mawase

Jonathan Kadmon

Yifat Prut

Affiliations

Soon will be listed here.

Abstract

The cerebellum plays a key role in motor adaptation by driving trial-to-trial recalibration of movements based on previous errors. In primates, cortical correlates of adaptation are encoded already in the pre-movement motor plan, but these early cortical signals could be driven by a cerebellar-to-cortical information flow or evolve independently through intracortical mechanisms. To address this question, we trained female macaque monkeys to reach against a viscous force field (FF) while blocking cerebellar outflow. The cerebellar block led to impaired FF adaptation and a compensatory, re-aiming-like shift in motor cortical preparatory activity. In the null-field conditions, the cerebellar block altered neural preparatory activity by increasing task-representation dimensionality and impeding generalization. A computational model indicated that low-dimensional (cerebellar-like) feedback is sufficient to replicate these findings. We conclude that cerebellar signals carry task structure information that constrains the dimensionality of the cortical preparatory manifold and promotes generalization. In the absence of these signals, cortical mechanisms are harnessed to partially restore adaptation.

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