Reach adaptation and proprioceptive recalibration following exposure to misaligned sensory input.

Motor adaptation in response to a visuomotor distortion arises when the usual motor command no longer results in the predicted sensory output. In this study, we examined if exposure to a sensory discrepancy was sufficient on its own to produce changes in reaches and recalibrate the sense of felt hand position in the absence of any voluntary movements. Subjects pushed their hand out along a robot-generated fixed linear path (active exposure group) or were passively moved along the same path (passive exposure group). This fixed path was gradually rotated counterclockwise around the home position with respect to the path of the cursor. On all trials, subjects saw the cursor head directly to the remembered target position while their hand moved outwards. We found that after exposure to the visually distorted hand motion, subjects in both groups adapted their reaches such that they aimed ∼6° to the left of the intended target. The magnitude of reach adaptation was similar to the extent that subjects recalibrated their sense of felt hand position. Specifically the position at which subjects perceived their unseen hand to be aligned with a reference marker was the same as that to which they reached when allowed to move freely. Given the similarity in magnitude of these adaptive responses we propose that reach adaptation arose due to changes in subjects' sense of felt hand position. Moreover, results indicate that motor adaptation can arise following exposure to a sensory mismatch in the absence of movement related error signals.

[1]  Robert L. Sainburg,et al.  The symmetry of interlimb transfer depends on workspace locations , 2006, Experimental Brain Research.

[2]  Daniel M. Wolpert,et al.  Forward Models for Physiological Motor Control , 1996, Neural Networks.

[3]  B. Treutwein Adaptive psychophysical procedures , 1995, Vision Research.

[4]  R. Held,et al.  Adaptation of Disarranged Hand-Eye Coordination Contingent upon Re-Afferent Stimulation , 1958 .

[5]  D. Henriques,et al.  Sensory recalibration of hand position following visuomotor adaptation. , 2009, Journal of neurophysiology.

[6]  R. Sainburg,et al.  Interlimb transfer of visuomotor rotations: independence of direction and final position information , 2002, Experimental Brain Research.

[7]  J. Flanagan,et al.  Learning and recall of incremental kinematic and dynamic sensorimotor transformations , 2005, Experimental Brain Research.

[8]  Mitsuo Kawato,et al.  Internal models for motor control and trajectory planning , 1999, Current Opinion in Neurobiology.

[9]  J. F. Soechting,et al.  Bias and sensitivity in the haptic perception of geometry , 2003, Experimental Brain Research.

[10]  Sethu Vijayakumar,et al.  Unifying the Sensory and Motor Components of Sensorimotor Adaptation , 2008, NIPS.

[11]  Philip N. Sabes,et al.  Visual-shift adaptation is composed of separable sensory and task-dependent effects. , 2007, Journal of neurophysiology.

[12]  Robert L. Sainburg,et al.  Limitations in interlimb transfer of visuomotor rotations , 2004, Experimental Brain Research.

[13]  D. Wolpert,et al.  When Feeling Is More Important Than Seeing in Sensorimotor Adaptation , 2002, Current Biology.

[14]  J. Flanagan,et al.  Task-specific internal models for kinematic transformations. , 2003, Journal of neurophysiology.

[15]  Tamar Flash,et al.  Computational approaches to motor control , 2001, Current Opinion in Neurobiology.

[16]  Jinsung Wang,et al.  Adaptation to Visuomotor Rotations Remaps Movement Vectors, Not Final Positions , 2005, The Journal of Neuroscience.

[17]  B. Craske Adaptation to prisms: change in internally registered eye-position. , 1967, British journal of psychology.

[18]  D. Henriques,et al.  Visuomotor adaptation does not recalibrate kinesthetic sense of felt hand path. , 2009, Journal of neurophysiology.

[19]  R. Held,et al.  PLASTICITY IN HUMAN SENSORIMOTOR CONTROL. , 1963, Science.

[20]  P. Viviani,et al.  Pointing errors reflect biases in the perception of the initial hand position. , 1998, Journal of neurophysiology.

[21]  Erin K. Cressman,et al.  Proprioceptive localization of the left and right hands , 2010, Experimental Brain Research.

[22]  B Moulden,et al.  Adaptation to Displaced Vision: Reafference is a Special Case of the Cue-Discrepancy Hypothesis , 1971, The Quarterly journal of experimental psychology.

[23]  Michael I. Jordan,et al.  Generalization to Local Remappings of the Visuomotor Coordinate Transformation , 1996, The Journal of Neuroscience.

[24]  Adaptation to visual rearrangement elicited by tonic vibration reflexes , 1975, Experimental Brain Research.

[25]  R H Day,et al.  Spatial adaptation and aftereffect with optically transformed vision: effects of active and passive responding and the relationship between test and exposure responses. , 1966, Journal of experimental psychology.

[26]  I P HOWARD,et al.  VISUOMOTOR ADAPTATION TO DISCORDANT EXAFFERENT STIMULATION. , 1965, Journal of experimental psychology.

[27]  J R Lackner,et al.  Adaptation to Visual Rearrangement: Role of Sensory Discordance , 1977, The Quarterly journal of experimental psychology.

[28]  Michael I. Jordan,et al.  An internal model for sensorimotor integration. , 1995, Science.

[29]  H. Wallach,et al.  A PASSIVE CONDITION FOR RAPID ADAPTATION TO DISPLACED VISUAL DIRECTION. , 1963, The American journal of psychology.

[30]  R. Held,et al.  Neonatal deprivation and adult rearrangement: complementary techniques for analyzing plastic sensory-motor coordinations. , 1961, Journal of comparative and physiological psychology.

[31]  C Ghez,et al.  Learning of Visuomotor Transformations for Vectorial Planning of Reaching Trajectories , 2000, The Journal of Neuroscience.

[32]  Olivier White,et al.  Use-Dependent and Error-Based Learning of Motor Behaviors , 2010, The Journal of Neuroscience.

[33]  H. Kesten Accelerated Stochastic Approximation , 1958 .

[34]  Robert L. Sainburg,et al.  Mechanisms underlying interlimb transfer of visuomotor rotations , 2003, Experimental Brain Research.

[35]  John W. Krakauer,et al.  Independent learning of internal models for kinematic and dynamic control of reaching , 1999, Nature Neuroscience.