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TRACTs (DeconsTructing Post StRoke HemipAresis for PreCision NeurorehabiliTation) is a single timepoint study that aims to deconstruct post-stroke deficits of the upper extremity into distinct components and relate these components to brain anatomy and physiology.
The purpose of this study is to improve control of myoelectrically-controlled advanced orthotic devices (an exoskeleton device that use the body's muscle signals to drive movements of a robotic brace) by using advanced predictive decode algorithms, and the use of high count (\> 8) surface electromyographic (sEMG) electrodes.
This study aims to evaluate the feasibility and impact of transcutaneous electrical stimulation of the spinal cord (TESS) on the recovery of post-stroke individuals who have upper limb hemiparesis. It will compare outcomes measures between individuals who receive upper limb task specific training with TESS and individuals who receive task specific training of the upper limb with Sham, or fake, TESS.
The purpose of this research study is to evaluate and compare different robotic exoskeletons (RE) and identify which is most appropriate for gait training for each patient based off their specific needs. This will help guide clinicians in prescribing the appropriate RE for rehabilitation.
The subjects will be asked to attend minimum 15 separate sessions, 6 for testing changes in reflex behaviors, 3 for testing changes in the influence of descending motor tracts on spinal motor neurons, 3 for each testing functional movement in response to a trip event and cross-tilt walking adaptation pattern, as part of their participation in the research study. The estimated amount of time to enroll and collect the data for each of the subjects is four months' time. The data will be analyzed and ready for grant preparation (if successful) in approximately four months after the start of the study.
This study uses functional magnetic resonance imaging to map neural activity throughout the central nervous system during a shoulder abduction task to characterize what motor pathways are being used post-stroke.
This trial aims to investigate whether placebo in isolation (open and hidden) has a specific neural signature in stroke subjects thus providing a novel mechanism to explain placebo effects that can be used to ultimately enhance stroke rehabilitation therapies.
To determine whether treatment with transauricular vagus nerve stimulation (taVNS) during the training of an affected upper limb of a patient with chronic stroke on a robotic motor task alters the motor impairment.
The randomized study (in Phase II of the U44) compares the efficacy and durability of 9 weeks (18 sessions) of robot-assisted physical therapy (PTR) versus physical therapy (PT) alone on foot drop as assessed by gait biomechanics (ankle angle at initial contact, peak swing ankle angle, number of heel-first strikes - % total steps, gait velocity) and blinded clinician assessment (dorsiflexion active range of motion, ankle muscle strength, assistive device needs).
This study is designed to further develop and test the hardware and software components of the MyHand device based on user feedback and results from our pilot study. The goal is to refine the device so that is more effective and easier for stroke patients to use to increase their hand function.