Individuals with hemiparesis following a stroke are left with various degrees of impairment in function, especially affecting their walking ability. This BRP renewal application focuses on developing and testing novel rehabilitation solutions for gait retraining of stroke and other motor-impaired patients. Our rehab solutions consist of un-motorized and motorized exoskeletons, integrated with functional electric stimulation (FES), supplemented by biomechanical models. In the first five years of this project, we showed the feasibility of this approach through development of robotic exoskeletons with limited subject testing. The next five-year goal of this project is to integrate and expand on our current understanding of component science and technologies, i.e., un-motorized and motorized exoskeletons, FES, and biomechanics to fabricate and test novel rehabilitation solutions for gait training of patients with stroke.

Public Health Relevance

The goal of this renewal application is to integrate and expand on our current understanding of component science and technologies, i.e., un-motorized and motorized exoskeletons, FES, and biomechanics. We plan to test novel rehabilitation solutions for gait training of patients with stroke and compare these with currently accepted training methods, such as the body-weight supported treadmill training. The project aims are:
Aim 1 : Develop bilateral gait rehabilitation systems for treadmill training of hemiparetic stroke patients using un-motorized and motorized exoskeletons and FES. We will fabricate and test the following two rehabilitation systems: (i) Bilateral Gravity Balancing Orthosis (GBO) with FES/Motorized control of the ankle, (ii) Bilateral Active Limb Exoskeleton (ALEX) with FES/Motorized control of the ankle. Novel symbiotic control of the ankle will be implemented where the ankle motor will be used as a safety net for delivery of the FES training.
Aim 2 : Test the effectiveness of these two rehabilitation solutions in patients with stroke and compare their performances with body weight supported treadmill training (BWSTT), a paradigm used currently in the literature for gait training.
Aim 3 : Prediction of muscle coordination deficits off-line in individuals with hemiparesis using gait analysis, biomechanics, FES models, and sensors on the exoskeleton. The musculoskeletal models will be used before training, as a screening mechanism, and post-training to understand why a particular gait training strategy with the exoskeleton worked.

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Research Project (R01)
Project #
3R01HD038582-08S1
Application #
8112993
Study Section
Musculoskeletal Tissue Engineering Study Section (MTE)
Program Officer
Quatrano, Louis A
Project Start
2010-09-01
Project End
2011-08-31
Budget Start
2010-09-01
Budget End
2011-08-31
Support Year
8
Fiscal Year
2010
Total Cost
$100,000
Indirect Cost
Name
University of Delaware
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
059007500
City
Newark
State
DE
Country
United States
Zip Code
19716
Hsiao, HaoYuan; Gray, Vicki L; Creath, Robert A et al. (2017) Control of lateral weight transfer is associated with walking speed in individuals post-stroke. J Biomech 60:72-78
Stegall, Paul; Zanotto, Damiano; Agrawal, Sunil K (2017) Variable Damping Force Tunnel for Gait Training Using ALEX III. IEEE Robot Autom Lett 2:1495-1501
Hsiao, HaoYuan; Knarr, Brian A; Pohlig, Ryan T et al. (2016) Mechanisms used to increase peak propulsive force following 12-weeks of gait training in individuals poststroke. J Biomech 49:388-95
Srivastava, Shraddha; Kao, Pei-Chun; Reisman, Darcy S et al. (2016) Coordination of muscles to control the footpath during over-ground walking in neurologically intact individuals and stroke survivors. Exp Brain Res 234:1903-1914
Hsiao, HaoYuan; Zabielski Jr, Thomas M; Palmer, Jacqueline A et al. (2016) Evaluation of measurements of propulsion used to reflect changes in walking speed in individuals poststroke. J Biomech 49:4107-4112
Hsiao, HaoYuan; Higginson, Jill S; Binder-Macleod, Stuart A (2016) Baseline predictors of treatment gains in peak propulsive force in individuals poststroke. J Neuroeng Rehabil 13:2
Vashista, Vineet; Khan, Moiz; Agrawal, Sunil K (2016) A Novel Approach to Apply Gait Synchronized External Forces on the Pelvis using A-TPAD to Reduce Walking Effort. IEEE Robot Autom Lett 1:1118-1124
Srivastava, Shraddha; Kao, Pei Chun; Reisman, Darcy S et al. (2016) Robotic Assist-As-Needed as an Alternative to Therapist-Assisted Gait Rehabilitation. Int J Phys Med Rehabil 4:
Hsiao, HaoYuan; Awad, Louis N; Palmer, Jacqueline A et al. (2016) Contribution of Paretic and Nonparetic Limb Peak Propulsive Forces to Changes in Walking Speed in Individuals Poststroke. Neurorehabil Neural Repair 30:743-52
Srivastava, Shraddha; Kao, Pei-Chun; Kim, Seok Hun et al. (2015) Assist-as-Needed Robot-Aided Gait Training Improves Walking Function in Individuals Following Stroke. IEEE Trans Neural Syst Rehabil Eng 23:956-63

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