Your search keyword '"Jeffrey Weiler"' showing total 3 results

1. Response suppression delays the planning of subsequent stimulus-driven saccades.

Author

Jeffrey Weiler, Trina Mitchell, and Matthew Heath

Subjects

Medicine, Science

Abstract

The completion of an antisaccade selectively increases the reaction tiME (RT) of a subsequent prosaccade: a result that has been interpreted to reflect the residual inhibition of stimulus-driven saccade networks [1], [2]. In the present investigation we sought to determine whether the increase in prosaccade RT is contingent on the constituent antisaccade planning processes of response suppression and vector inversion or is limited to response suppression. To that end, in one block participants alternated between pro- and antisaccades after every second trial (task-switching block), and in another block participants completed a series of prosaccades that were randomly (and infrequently) interspersed with no-go catch-trials (go/no-go block). Notably, such a design provides a framework for disentangling whether response suppression and/or vector inversion delays the planning of subsequent prosaccades. As expected, results for the task-switching block showed that antisaccades selectively increased the RTs of subsequent prosaccades. In turn, results for the go/no-go block showed that prosaccade RTs were increased when preceded by a no-go catch-trial. Moreover, the magnitude of the RT 'cost' was equivalent across the task-switching and go/no-go blocks. That prosaccades preceded by an antisaccade or a no-go catch-trial produced equivalent RT costs indicates that the conjoint processes of response suppression and vector inversion do not drive the inhibition of saccade planning mechanisms. Rather, the present findings indicate that a general consequence of response suppression is a residual inhibition of stimulus-driven saccade networks.

Published

2014

2. Rapid feedback responses are flexibly coordinated across arm muscles to support goal-directed reaching

Author

Jeffrey Weiler, Paul L. Gribble, and J. Andrew Pruszynski

Subjects

0301 basic medicine, musculoskeletal diseases, Male, medicine.medical_specialty, Physiology, Computer science, Movement, Elbow, Exoskeleton robot, Thumb, Wrist, behavioral disciplines and activities, Motion (physics), Feedback, 03 medical and health sciences, Young Adult, 0302 clinical medicine, EMG, Physical medicine and rehabilitation, Orientation (mental), Goal-dependent, Reflex, medicine, Humans, Muscle activity, Elbow flexion, Muscle, Skeletal, Feedback, Physiological, Communication, Hand Strength, business.industry, General Neuroscience, Flexor muscles, Long latency, Evoked Potentials, Motor, Biomechanical Phenomena, body regions, 030104 developmental biology, medicine.anatomical_structure, Coordination, Arm, Female, business, Goals, 030217 neurology & neurosurgery, Psychomotor Performance, Research Article

Abstract

A transcortical pathway helps support goal-directed reaching by processing somatosensory information to produce rapid feedback responses across multiple joints and muscles. Here we tested whether such feedback responses can account for changes in arm configuration and for arbitrary visuomotor transformations – two manipulations that alter how muscles at the elbow and wrist need to be coordinated to achieve task success. Participants used a planar three degree-of-freedom exoskeleton robot to move a cursor to a target following a mechanical perturbation that flexed the elbow. In our first experiment, the cursor was mapped to the veridical position of the robot handle, but participants grasped the handle with two different hand orientations (thumb pointing upward or thumb point downward). We found that large rapid feedback responses were evoked in wrist extensor muscles when wrist extension helped move the cursor to the target (i.e., thumb upward), and in wrist flexor muscles when wrist flexion helped move the cursor to the target (i.e., thumb downward). In our second experiment, participants grasped the robot handle with their thumb pointing upward, but the cursor’s movement was either veridical, or was mirrored such that flexing the wrist moved the cursor as if the participant extended their wrist, and vice versa. After extensive practice, we found that rapid feedback responses were appropriately tuned to the wrist muscles that supported moving the cursor to the target when the cursor was mapped to the mirrored movement of the wrist, but were not tuned to the appropriate wrist muscles when the cursor was remapped to the wrist’s veridical movement.New and NoteworthyWe show that rapid feedback responses were evoked in different wrist muscles depending on the arm’s orientation, and this muscle activity was appropriate to generate the wrist motion that supported a reaching action. Notably, we also show that these rapid feedback responses can be evoked in wrist muscles that are detrimental to a reaching action if a non-veridical mapping between wrist and hand motion is extensively learned.

Published

2017

3. Coordinating long-latency stretch responses across the shoulder, elbow, and wrist during goal-directed reaching

Author

James Saravanamuttu, Jeffrey Weiler, Paul L. Gribble, and J. Andrew Pruszynski

Subjects

0301 basic medicine, musculoskeletal diseases, Male, Reflex, Stretch, medicine.medical_specialty, Shoulder, Flexibility (anatomy), Time Factors, Physiology, Computer science, Movement, Elbow, Wrist, Feedback, 03 medical and health sciences, Young Adult, EMG, 0302 clinical medicine, Physical medicine and rehabilitation, Reflex, medicine, Reaction Time, Humans, Upper limb, Muscle, Skeletal, Intersegmental dynamics, Electromyography, General Neuroscience, Goal-dependent activity, Exoskeleton Device, Long latency, Long-latency stretch response, body regions, 030104 developmental biology, medicine.anatomical_structure, Coordination, Female, Control of Movement, Goals, 030217 neurology & neurosurgery

Abstract

The long-latency stretch response (muscle activity 50–100 ms after a mechanical perturbation) can be coordinated across multiple joints to support goal-directed actions. Here we assessed the flexibility of such coordination and whether it serves to counteract intersegmental dynamics and exploit kinematic redundancy. In three experiments, participants made planar reaches to visual targets after elbow perturbations and we assessed the coordination of long-latency stretch responses across shoulder, elbow, and wrist muscles. Importantly, targets were placed such that elbow and wrist (but not shoulder) rotations could help transport the hand to the target—a simple form of kinematic redundancy. In experiment 1 we applied perturbations of different magnitudes to the elbow and found that long-latency stretch responses in shoulder, elbow, and wrist muscles scaled with perturbation magnitude. In experiment 2 we examined the trial-by-trial relationship between long-latency stretch responses at adjacent joints and found that the magnitudes of the responses in shoulder and elbow muscles, as well as elbow and wrist muscles, were positively correlated. In experiment 3 we explicitly instructed participants how to use their wrist to move their hand to the target after the perturbation. We found that long-latency stretch responses in wrist muscles were not sensitive to our instructions, despite the fact that participants incorporated these instructions into their voluntary behavior. Taken together, our results indicate that, during reaching, the coordination of long-latency stretch responses across multiple joints counteracts intersegmental dynamics but may not be able to exploit kinematic redundancy.

Published

2016