Combined user-driven treadmill control and functional electrical stimulation increases walking speeds poststroke

The variety of poststroke impairments and compensatory mechanisms necessitate adaptive and subject-specific approaches to locomotor rehabilitation. To implement subject-specific, adaptive training to treadmill-based gait training, we developed a user-driven treadmill (UDTM) control algorithm that ad...

Full description

Saved in:
Bibliographic Details
Published in:Journal of biomechanics 2021-07, Vol.124, p.110480-110480, Article 110480
Main Authors: Ray, Nicole T., Reisman, Darcy S., Higginson, Jill S.
Format: Article
Language:English
Subjects:
Algorithms
Ankle
Anterior ground reaction force
Biomechanical Phenomena
Control algorithms
Control theory
Electric Stimulation
Electrical stimuli
Exercise Test
Fitness equipment
Gait
Humans
Motion capture
Rehabilitation
Self-paced treadmill control
Software
Speed
Speed control
Stimulation
Stroke
Stroke - therapy
Stroke Rehabilitation
Trailing limb angle
Training
Treadmills
User-driven treadmill control
Walking
Walking Speed
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The variety of poststroke impairments and compensatory mechanisms necessitate adaptive and subject-specific approaches to locomotor rehabilitation. To implement subject-specific, adaptive training to treadmill-based gait training, we developed a user-driven treadmill (UDTM) control algorithm that adjusts the user’s speed in real-time. This study examines the response of individuals poststroke to the combination of UDTM control and electrical stimulation of the paretic ankle musculature to augment forward propulsion during walking. Sixteen individuals poststroke performed a randomized series of walking tasks on an instrumented split-belt treadmill at their self-selected speeds 1) with fixed speed treadmill (FSTM) control only, 2) FSTM control and paretic limb functional electrical stimulation (FES), 3) UDTM control only, and 4) UDTM control and FES. With UDTM control and FES, participants selected speeds that were 0.13 m/s faster than their speeds with fixed speed control only. This instantaneous increase is comparable to the gains in SS speed seen after 12 weeks of training with FES and fast walking with fixed speed treadmill control by Kesar and colleagues (Δ = 0.18 m/s). However, we saw no significant differences in the corresponding push-off forces or trailing limb position. Since individuals can use a variety of strategies to change their walking speeds, it is likely that the differences among individual responses obscured trends in the group average changes in mechanics. Ultimately, the combination of UDTM control and functional electrical stimulation (FES) allows individuals to increase speeds after a short exposure and may be a beneficial addition to poststroke gait training programs.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2021.110480