Spatiotemporal Dissociation of FMRI Activity in the Caudate Nucleus Underlies Human De Novo Motor Skill Learning

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2020 Sep 9

PMID 32900934

Citations 19

Authors

Yera Choi

Emily Yunha Shin

Sungshin Kim

Affiliations

Soon will be listed here.

Abstract

Motor skill learning involves a complex process of generating novel movement patterns guided by evaluative feedback, such as a reward. Previous literature has suggested anteroposteriorly separated circuits in the striatum to be implicated in early goal-directed and later automatic stages of motor skill learning, respectively. However, the involvement of these circuits has not been well elucidated in human de novo motor skill learning, which requires learning arbitrary action-outcome associations and value-based action selection. To investigate this issue, we conducted a human functional MRI (fMRI) experiment in which participants learned to control a computer cursor by manipulating their right fingers. We discovered a double dissociation of fMRI activity in the anterior and posterior caudate nucleus, which was associated with performance in the early and late learning stages. Moreover, cognitive and sensorimotor cortico-caudate interactions predicted individual learning performance. Our results suggest parallel cortico-caudate networks operating in different stages of human de novo motor skill learning.

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