Motor-Cognitive Virtual Reality Training to Improve Gait and Balance in Young Adults with TBI.

Traumatic Brain Injury (TBI) is one of the leading causes of motor and cognitive deficits in adults, and often results in motor control and balance impairments. Motor deficits include gait dysfunction and decreased postural control & coordination; leading to compromised functional ambulation and reduced quality of life. Research has shown that cognitive (attention and executive) function contributes to motor deficits and recovery. Hence, targeting the motor and the cognitive domains simultaneously by increasing cognitive and motor effort to perform the task may lead to improved ambulation recovery. The objective of this investigation was to evaluate the efficacy of simultaneous motor & cognitive training (MCT) using virtual reality to improve ambulation; assessed using biomechanical, cognitive, and functional outcomes. Preliminary data is presented for three participants with chronic TBI who received MCT. The results show improved cognition, speed, endurance, step length, gait cycle time, static & reactive balance, dual-task performance, and progression towards healthy ambulation. These preliminary results suggest that integrated cognitive motor training has the potential to induce functional recovery in young adults with TBI.Clinical Relevance - Preliminary data provides initial evidence for MCT as a therapeutic intervention for gait and balance rehabilitation in young adults with TBI.

Lower extremity robotic exoskeleton devices for overground ambulation recovery in acquired brain injury-A review.

Acquired brain injury (ABI) is a leading cause of ambulation deficits in the United States every year. ABI (stroke, traumatic brain injury and cerebral palsy) results in ambulation deficits with residual gait and balance deviations persisting even after 1 year. Current research is focused on evaluating the effect of robotic exoskeleton devices (RD) for overground gait and balance training. In order to understand the device effectiveness on neuroplasticity, it is important to understand RD effectiveness in the context of both downstream (functional, biomechanical and physiological) and upstream (cortical) metrics. The review identifies gaps in research areas and suggests recommendations for future research. We carefully delineate between the preliminary studies and randomized clinical trials in the interpretation of existing evidence. We present a comprehensive review of the clinical and pre-clinical research that evaluated therapeutic effects of RDs using various domains, diagnosis and stage of recovery.

Changes in Center of Pressure after Robotic Exoskeleton Gait Training in Adults with Acquired Brain Injury.

Acquired brain injury (ABI) resulting in hemiplegia, is one of the leading causes of gait and balance deficits in adults. Gait and balance deficits include reduced momentum for forward progression, reduced step length, increased spatial and temporal asymmetry, and decreased speed; resulting in reduced functional ambulation, activities of daily living, and quality of life. Wearable lower extremity robotic exoskeletons (REs) are becoming an effective method for gait neurorehabilitation in individuals with ABI. REs can provide high dose, consistent, goal-directed repetition of movements as well as balance & stability for individuals with ABI. The objective of this study is to understand the effect of RE gait training using center of pressure (COP) displacement, temporal & spatial parameters, and functional outcomes for individuals with ABI. The results from this investigation show improved anterior-posterior COP displacement & rate of progression, spatial symmetry, step length, walking speed, and decreased time during the gait cycle. These preliminary results suggest that high dose, repetitive gait training using robotic exoskeletons has the potential to induce recovery of function in adults diagnosed with ABI.