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We expect that a smart, wearable airbag system that can accurately predict falls and quickly inflate will reduce hip fractures in people with Parkinson's.

This project studies precision neurotrauma medicine with patient-derived iPSC-neurons to determine patient specific factors affecting clinical outcomes

This research project is working on improving the interactions between robots and humans by learning from human paired physical interaction to apply to human like robotics.

We combine sensors with fun, interactive computer games in order to strengthen arm muscles after stroke or SCI! Free program offered by the Perez Lab.

The purpose of the study was to examine the contribution of passive muscle stiffness and active spinal reflex mechanisms to clinical outcomes of spasticity after SCI.

This study investigates the intracortical inhibition in humans with cervical spinal cord injury. We particularly aim to understand the inhibitory mechanism for the control of upper arm muscles to further promote rehabilitation protocol.

This study will evaluate use of wearable sensors to gather information on COVID-19 like signs and symptoms.

Dawn Ehde, PhD, presented on her research on chronic pain in individuals with physical disabilities and the use of telehealth to deliver cognitive-behavioral interventions to support health and independence.

On Oct. 29th, 2019, Shirley Ryan ÐÇ¿Õ´«Ã½ÊÓƵ's Center for Rehabilitation Outcomes ÐÇ¿Õ´«Ã½ÊÓƵ (CROR) invited job seekers with disabilities and employers to attend an all-day, interactive workshop on job accommodations.

The Slutzky Neuroprosthetics Lab Team is evaluating a new rehab therapy using wearable devices and a video game interface to improve arm movement after stroke.

BMIs have been able to restore basic communication by allowing patients to slowly spell out individual letters by decoding particular signals, most commonly evoked potentials in response to some stimulus.

The ultimate goal of this project is to restore hand and arm function to people with paralysis from neurological disorders. Brain machine interfaces - BMIs, which decode electrical signals recorded from the brain, offer one way to bypass the area causing paralysis and intuitively reanimate paralyzed muscles via electrical stimulation.