We previously demonstrated that predictive motor timing (i.e., timing requiring visuomotor coordination in anticipation of a future event, such as catching or batting a ball) is impaired in patients with spinocerebellar ataxia (SCA) types 6 and 8 relative to healthy controls. Specifically, SCA patients had difficulties postponing their motor response while estimating the target kinematics. This behavioral difference relied on the activation of both cerebellum and striatum in healthy controls, but not in cerebellar patients, despite both groups activating certain parts of cerebellum during the task. However, the role of these two key structures in the dynamic adaptation of themotor timing to target kinematic properties remained unexplored. In the current paper, we analyzed these data with the aim of characterizing the trial-bytrial changes in brain activation. We found that in healthy controls alone, and in comparison with SCA patients, the activation in bilateral striatum was exclusively associated with past successes and that in the left putamen, withmaintaining a successful performance across successive trials. In healthy controls, relative to SCA patients, a larger network was involved in maintaining a successful trial-by-trial strategy; this included cerebellum and fronto-parietotemporo- occipital regions that are typically part of attentional network and actionmonitoring. Cerebellumwas also part of a network of regions activated when healthy participants postponed their motor response from one trial to the next; SCA patients showed reduced activation relative to healthy controls in both cerebellum and striatum in the same contrast. These findings support the idea that cerebellum and striatum play complementary roles in the trial-by-trial adaptation in predictive motor timing. In addition to expanding our knowledge of brain structures involved in time processing, our results have implications for the understanding of BG disorders, such as Parkinson’s, where feedback processing or reward learning is affected.
Bibliographical noteFunding Information:
This work was supported by NIH Grant NS40106, MH065598, the Department of Veterans Affairs, the Brain Sciences Chair, a Proshek-Fulbright grant, the Academia Medica Pragensis Foundation, and a ?CEITEC-Central European Institute of Technology? project (CZ.1.05/1.1.00/02.0068) from the European Regional Development Fund.
© 2012, Massachusetts Institute of Technology.
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