The interplay between cerebellum and basal ganglia in motor adaptation: A modeling study.

Dmitrii I Todorov,Yaroslav I Molkov,Sergey N Markin,Taegyo Kim,William H Barnett,Elizaveta M Latash,Robert A Capps,Khaldoun C Hamade,Ilya A Rybak,Genela Morris

doi:10.1371/journal.pone.0214926

Dmitrii I Todorov, Yaroslav I Molkov + Show 8 more

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https://doi.org/10.1371/journal.pone.0214926

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Journal: PloS one	Publication Date: Apr 12, 2019
Citations: 11	License type: CC BY 4.0

Affiliation: Georgia State University, Drexel University

Abstract

Motor adaptation to perturbations is provided by learning mechanisms operating in the cerebellum and basal ganglia. The cerebellum normally performs motor adaptation through supervised learning using information about movement error provided by visual feedback. However, if visual feedback is critically distorted, the system may disengage cerebellar error-based learning and switch to reinforcement learning mechanisms mediated by basal ganglia. Yet, the exact conditions and mechanisms of cerebellum and basal ganglia involvement in motor adaptation remain unknown. We use mathematical modeling to simulate control of planar reaching movements that relies on both error-based and non-error-based learning mechanisms. We show that for learning to be efficient only one of these mechanisms should be active at a time. We suggest that switching between the mechanisms is provided by a special circuit that effectively suppresses the learning process in one structure and enables it in the other. To do so, this circuit modulates learning rate in the cerebellum and dopamine release in basal ganglia depending on error-based learning efficiency. We use the model to explain and interpret experimental data on error- and non-error-based motor adaptation under different conditions.

Highlights

Motor learning is a process of acquiring skills to perform an appropriate motor task in response to a sensory cue, e.g. precise reaching with a mouse pointer to a target spot shown on the screen
We modeled the neuromechanical control of reaching movements in humans and used this model to reproduce and explain the results of previous experimental studies demonstrating motor adaptation during reaching [7, 10]
We have shown above that when the vector movement error is distorted by a strong visual rotation or a reflection of the visual field, the error-based mechanisms lead to divergence of the movement endpoint from the target instead of adaptation to the target

Summary

Introduction

Motor learning is a process of acquiring skills to perform an appropriate motor task in response to a sensory cue, e.g. precise reaching with a mouse pointer to a target spot shown on the screen. Motor adaptation is a form of motor learning to overcome movement perturbations caused by novel environment or altered sensory feedback. Future movements are corrected using error information acquired on previous trials [1]. Representation of the movement error depends on available sensory components. During reaching movements under unexpected perturbation, visual feedback can provide a vector displacement of the movement endpoint relative to the target position.

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