High-dose gait training with robotic exoskeleton may improve function after acute stroke
Kessler research team reports advances in inpatient rehabilitation for acute stroke; findings indicate early intervention using the robotic exoskeleton for high-dose gait training may improve function
East Hanover, NJ. August X 2021. Preliminary findings by Kessler researchers show that the use of a robotic exoskeleton during inpatient rehabilitation for acute stroke may improve function. Gait training in the robotic exoskeleton can provide high-dose therapy soon after stroke, when it is likely to have its maximal effect on functional ambulation. The article, "Effect of robotic exoskeleton gait training during acute stroke on functional ambulation" (doi: 10.3233/NRE-210010 ), was published June 16, 2021 in NeuroRehabilitation and is available open access at: https://content.iospress.com/articles/neurorehabilitation/nre210010
The authors are Kiran K. Karunakaran, PhD, Sharon Gute, Gregory R. Ames, Kathleen Chervin, and Karen J. Nolan, PhD, of the Center for Mobility and Rehabilitation Engineering Research at Kessler Foundation, and Christina M. Dandola, PT, of Kessler Institute for Rehabilitation. Kessler scientists and clinicians have faculty appointments at Rutgers New Jersey Medical School.
Stroke-related disability is one of the major problems in the U.S., with half of stroke survivors experiencing residual deficits in walking, balance, and coordination even after one year. Functional ambulation deficits limit their ability to perform activities of daily living, participate in the community, and live independently. One promising approach is to use robotic devices to provide therapy early after stroke when neuroplasticity allows for maximal gains. For this study, the Kessler team analyzed the ability of the robotic device (Ekso GT by Ekso Bionics, Inc.) to provide gait training to restore functional gait in individuals with stroke.
Participants included 14 individuals (mean age 61.24 years ± 1.98) who received inpatient rehabilitation at Kessler Institute for Rehabilitation for moderate to severe hemiplegia caused by stroke. Their physical therapy sessions (45-90 min) included conventional standard of care (SOC) and overground gait training in the robotic exoskeleton (RE). All participants received both therapies and the same overall amount of therapy time. At baseline and follow up, functional ambulation was assessed by 10-Meter Walk Test, (10MWT), Timed Up and Go (TUG), and 6-Minute Walk Test (6MWT). Data collected during SOC and RE sessions included distance walked and number of steps taken.
Results showed that total distance walked was higher during RE sessions compared with SOC sessions. The number of steps walked during RE sessions correlated to walking distance during physical therapy. Participants also increased their walking distance during physical therapy with increased use of RE. At follow up, there were improvements in speed, balance, and endurance compared with baseline. There were no complications or falls related to RE gait training.
“These improvements in functional ambulation have important implications for recovery following stroke,” said Dr. Nolan, assistant director of the Center for Mobility and Rehabilitation Engineering Research at Kessler Foundation. “Regaining functional ambulation means spending more time in the community, which correlates with better quality of life for individuals recovering from stroke,” she noted. “We anticipate that the increased dosing provided by training in the robotic exoskeleton may contribute to improvements in balance and quality of gait, as well as improved functional ambulation.”
The study also has implications for the timing of gait training after stroke. Previous research shows that early intervention with higher dose may confer long-lasting effects. Dr. Karunakaran foresees improvement in long-term outcomes: “We have seen that individuals treated soon after their stroke have better function at six months than their counterparts with delayed rehabilitation. Administered early, higher dose gait training can make a significant difference in the lives of individuals recovering from stroke.”
Recent articles from the Kessler robotics research team:
Robotic exoskeleton training expands options for stroke rehabilitation | EurekAlert! Science News
Robotic exoskeleton training improves walking in adolescents with acquired brain injury | EurekAlert! Science News
Funding sources: National Institute on Disability, Independent Living, and Rehabilitation Research (RERC on Wearable Robots) (90RE5021)
Learn about the Foundation’s ongoing studies in stroke rehabilitation research: https://kesslerfoundation.org/research/studies/stroke
For further information, contact our recruitment specialist at: ResearchStudies@KesslerFoundation.org
About Kessler Foundation
Kessler Foundation, a major nonprofit organization in the field of disability, is a global leader in rehabilitation research that seeks to improve cognition, mobility and long-term outcomes, including employment, for people with neurological disabilities caused by diseases and injuries of the brain and spinal cord. Kessler Foundation leads the nation in funding innovative programs that expand opportunities for employment for people with disabilities. For more information, visit KesslerFoundation.org.
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