Experimental Brain Research

, Volume 164, Issue 2, pp 250–259

Learning and recall of incremental kinematic and dynamic sensorimotor transformations

  • Jessica Klassen
  • Christine Tong
  • J. Randall Flanagan
Research Article

DOI: 10.1007/s00221-005-2247-4

Cite this article as:
Klassen, J., Tong, C. & Flanagan, J.R. Exp Brain Res (2005) 164: 250. doi:10.1007/s00221-005-2247-4

Abstract

Numerous studies have shown that when people encounter a sudden and novel sensorimotor transformation that alters perceived or actual movement, they gradually adapt and can later recall what they have learned if they encounter the transformation again. In this study, we tested whether retention and recall of learning is also observed when kinematic and dynamic transformations are introduced incrementally such that participants never experience large movement errors. Participants adapted their reaching movements to either a visuomotor rotation of hand position (kinematic transformation) or a rotary viscous force-field applied to the hand (dynamic transformation). These perturbations were introduced either incrementally or instantaneously. Thus, four groups of participants were tested with an incremental and an instantaneous group for both the kinematic and dynamic perturbations. To evaluate retention of learning, participants from all four groups were tested a day later on the same kinematic or dynamic perturbation presented instantaneously (at full strength). As expected, we found that subjects in the instantaneous group retained learning across days. We also found that, for both kinematic and dynamic perturbations, retention was equally good or better when the transformation was introduced incrementally. Because large and clearly detectable movement errors were not observed during adaptation to incremental perturbations, we conclude that such errors are not required for the learning and retention of internal models of kinematic and dynamic sensorimotor transformations.

Keywords

Motor learningInternal modelsArm movementVisuomotor rotationForce-field

Copyright information

© Springer-Verlag 2005

Authors and Affiliations

  • Jessica Klassen
    • 1
  • Christine Tong
    • 1
  • J. Randall Flanagan
    • 1
  1. 1.Department of Psychology and Centre for Neuroscience StudiesQueen’s UniversityKingstonCanada