Goal-directed reaching movements are guided by visual feedback from both target and hand. The classical view is that the brain extracts information about target and hand positions from a visual scene, calculates a difference vector between them, and uses this estimate to control the movement. Here we show that during fast feedback control, this computation is not immediate, but evolves dynamically over time. Immediately after a change in the visual scene, the motor system generates independent responses to the errors in hand and target location. Only about 200 ms later, the changes in target and hand positions are combined appropriately in the response, slowly converging to the true difference vector. Therefore, our results provide evidence...
The visuomotor system recalibrates when visual and motor maps are in conflict, bringing the maps bac...
The goal of this study was to examine the reorganization of hand movements during adaptation to dela...
To accurately guide one's actions online, the brain predicts sensory action feedback ahead of time b...
Goal-directed reaching movements are guided by visual feedback from both target and hand. The classi...
Goal-directed reaching movements are guided by visual feedback from both target and hand. The classi...
Closed loop visual feedback control of the hand is essential for accurate reaching movements. Withou...
The human motor system is remarkably proficient in the online control of visually guided movements, ...
Adaptation to novel dynamics requires learning a motor memory, or a new pattern of predictive feedfo...
Vision of the hand during reaching provides dynamic feedback that can be used to control movement. W...
To accurately guide one's actions online, the brain predicts sensory action feedback ahead of time b...
SummaryThe human motor system is remarkably proficient in the online control of visually guided move...
In the presence of vision, finalized motor acts can trigger spatial remapping, i.e., reference frame...
Contains fulltext : 64567.pdf (publisher's version ) (Closed access)Eye–hand coord...
AbstractTo accurately guide one's actions online, the brain predicts sensory action feedback ahead o...
Information pertaining to visual motion is used in the brain not only for conscious perception but a...
The visuomotor system recalibrates when visual and motor maps are in conflict, bringing the maps bac...
The goal of this study was to examine the reorganization of hand movements during adaptation to dela...
To accurately guide one's actions online, the brain predicts sensory action feedback ahead of time b...
Goal-directed reaching movements are guided by visual feedback from both target and hand. The classi...
Goal-directed reaching movements are guided by visual feedback from both target and hand. The classi...
Closed loop visual feedback control of the hand is essential for accurate reaching movements. Withou...
The human motor system is remarkably proficient in the online control of visually guided movements, ...
Adaptation to novel dynamics requires learning a motor memory, or a new pattern of predictive feedfo...
Vision of the hand during reaching provides dynamic feedback that can be used to control movement. W...
To accurately guide one's actions online, the brain predicts sensory action feedback ahead of time b...
SummaryThe human motor system is remarkably proficient in the online control of visually guided move...
In the presence of vision, finalized motor acts can trigger spatial remapping, i.e., reference frame...
Contains fulltext : 64567.pdf (publisher's version ) (Closed access)Eye–hand coord...
AbstractTo accurately guide one's actions online, the brain predicts sensory action feedback ahead o...
Information pertaining to visual motion is used in the brain not only for conscious perception but a...
The visuomotor system recalibrates when visual and motor maps are in conflict, bringing the maps bac...
The goal of this study was to examine the reorganization of hand movements during adaptation to dela...
To accurately guide one's actions online, the brain predicts sensory action feedback ahead of time b...