Grip force when reaching with target uncertainty provides evidence for motor optimization over averaging

When presented with competing potential reach targets and required to launch a movement before knowing which one will be cued as the target, people initially reach in the average target direction. Although this spatial averaging could arise from executing a weighted average of motor plans for the potential targets, it could also arise from planning a single, optimal movement. To test between these alternatives we used a task in which participants were required to reach to either a single target or towards two potential targets while grasping an object. A robotic device applied a lateral elastic load to the object requiring large grip forces for reaches to targets either side of midline and a minimal grip force for midline movements. As expected, in trials with two targets located either side of midline, participants initially reached straight ahead. Critically, on these trials the initial grip force was minimal, appropriate for the midline movement, and not the average of the large grip forces required for movements to the individual targets. These results indicate that under conditions of target uncertainty, people do not execute an average of planned actions but rather a single movement that optimizes motor costs

Rapid visuomotor corrective responses during transport of hand-held objects incorporate novel object dynamics

Numerous studies have shown that people are adept at learning novel object dynamics, linking applied force and motion, when performing reaching movements with hand-held objects. Here we investigated whether the control of rapid corrective arm responses, elicited in response to visual perturbations, has access to such newly acquired knowledge of object dynamics. Participants first learned to make reaching movements while grasping an object subjected to complex load forces that depended on the distance and angle of the hand from the start position. During a subsequent test phase, we examined grip and load force coordination during corrective arm movements elicited (within ~150 ms) in response to viewed sudden lateral shifts (1.5 cm) in target or object position. We hypothesized that, if knowledge of object dynamics is incorporated in the control of the corrective responses, grip force changes would anticipate the unusual load force changes associated with the corrective arm movements so as to support grasp stability. Indeed, we found that the participants generated grip force adjustments tightly coupled, both spatially and temporally, to the load force changes associated with the arm movement corrections. We submit that recently learned novel object dynamics are effectively integrated into sensorimotor control policies that support rapid visually driven arm corrective actions during transport of hand held objects

Reflex circuits and their modulation in motor control: a historical perspective and current view

Sensorimotor reflexes have long been, and continue to be, an area of tremendous research in movement neuroscience. Here I aim to provide an account of some studies that have been crucial in advancing our understanding of the organization of reflex circuits, their function and their modulation during motor control. I review research ranging from early experiments in reduced animal preparations that investigated the basic building blocks of reflex circuits to more recent studies in humans that demonstrate remarkable tunability of reflexes in response to variety of contingencies related to the task, the body and the environment. By providing such an integrated account of the historical aspects and current view on reflex function, I attempt to bring out the stunning complexity of reflex machinery, as well as the incredible adaptability of this machinery despite its underlying complexity.by Pratik K. Muth