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Adaptive control of movement deceleration during saccades

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  • Simon P Orozco
  • Scott T Albert
  • Reza Shadmehr

Abstract

As you read this text, your eyes make saccades that guide your fovea from one word to the next. Accuracy of these movements require the brain to monitor and learn from visual errors. A current model suggests that learning is supported by two different adaptive processes, one fast (high error sensitivity, low retention), and the other slow (low error sensitivity, high retention). Here, we searched for signatures of these hypothesized processes and found that following experience of a visual error, there was an adaptive change in the motor commands of the subsequent saccade. Surprisingly, this adaptation was not uniformly expressed throughout the movement. Rather, after experience of a single error, the adaptive response in the subsequent trial was limited to the deceleration period. After repeated exposure to the same error, the acceleration period commands also adapted, and exhibited resistance to forgetting during set-breaks. In contrast, the deceleration period commands adapted more rapidly, but suffered from poor retention during these same breaks. State-space models suggested that acceleration and deceleration periods were supported by a shared adaptive state which re-aimed the saccade, as well as two separate processes which resembled a two-state model: one that learned slowly and contributed primarily via acceleration period commands, and another that learned rapidly but contributed primarily via deceleration period commands.Author summary: A theoretical model posits that motor learning is supported by two independent processes, one that learns robustly from error but has poor retention, and another that learns more slowly but has strong retention. Here, we observed the potential signatures of these adaptive processes during control of saccades. The results suggest that distinct adaptive controllers may contribute to the acceleration and deceleration phases of a single movement.

Suggested Citation

  • Simon P Orozco & Scott T Albert & Reza Shadmehr, 2021. "Adaptive control of movement deceleration during saccades," PLOS Computational Biology, Public Library of Science, vol. 17(7), pages 1-30, July.
    • Handle: RePEc:plo:pcbi00:1009176
    DOI: 10.1371/journal.pcbi.1009176
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    References listed on IDEAS

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    3. Kurt A. Thoroughman & Reza Shadmehr, 2000. "Learning of action through adaptive combination of motor primitives," Nature, Nature, vol. 407(6805), pages 742-747, October.
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