Innovative Multi-Variable Biofeedback for Improving Gait Performance in Individuals With Diabetic Peripheral Neuropathy

Over 38 million adults in the United States (~1 in 7) are living with Diabetes Mellitus (DM), of which diabetic peripheral neuropathy (DPN) is the most common complication, affecting more than 50% of individuals with DM. DPN causes both sensory and motor impairments of the foot and ankle, leading to reduced functional mobility and increased ulceration and amputation risk. Propulsion and plantar pressure are two key interrelated gait parameters contributing to walking function and ulceration risk, respectively. Real-time biofeedback is a non-invasive rehabilitation strategy with significant promise for targeting gait impairments by providing the user with quantitative information regarding a targeted performance variable.

In this study, the team will evaluate multi-joint lower extremity biomechanical responses to univariate propulsion and plantar pressure biofeedback. Secondly, the team will use identified biomechanical compensations to propulsion and plantar pressure biofeedback to develop a multi-variable, implicit, individualized visual biofeedback program to improve gait function in individuals with DPN. Insights into the biomechanical mechanisms underlying plantar pressure and propulsion in people with DPN will allow us to design more informed and effective gait rehabilitation interventions aimed at preventing deleterious outcomes such as ulceration and amputation that can be tailored to individual patient characteristics.