Jessica Zistatsis1, Keshia M Peters1, Daniel Ballesteros2, Heather A Feldner1,3, Kristie Bjornson3,4, Katherine M Steele1. 1. Department of Mechanical Engineering, University of Washington, Seattle, WA, USA. 2. Department of Bioengineering, University of Washington, Seattle, WA, USA. 3. Department of Rehabilitation Medicine, University of Washington, Seattle, WA, USA. 4. Department of Pediatrics, University of Washington, Seattle Children's Research Institute, Seattle, WA, USA.
Abstract
BACKGROUND: Children with hemiparesis are commonly prescribed ankle foot orthoses to help improve gait; however, these orthoses often result in only small and variable changes in gait. Research with adult stroke survivors has suggested that orthoses that extend beyond the ankle using long, passive tendon-like structures (i.e. exotendons) can improve walking. OBJECTIVES: The aim of this study was to quantify the impact of an exotendon-based exoskeleton on pediatric gait. STUDY DESIGN: Repeated-measures study. METHODS: Two typically-developing children and two children with hemiparesis completed a gait analysis, walking without and with the exoskeleton. The exotendon was tested at three stiffness levels. RESULTS: All children were able to walk comfortably with the exoskeleton, with minimal changes in step width. Walking speed increased and lower limb joint symmetry improved for the children with hemiparesis with the exoskeleton. Each participant had changes in muscle activity while walking with the exoskeleton, although the impact on specific muscles and response to exotendon stiffness varied. CONCLUSION: Exotendon-based exoskeletons may provide an alternative solution for optimizing gait in therapy and in the community for children with hemiparesis. Determining the optimal stiffness and configuration for each child is an important area of future research.
BACKGROUND: Children with hemiparesis are commonly prescribed ankle foot orthoses to help improve gait; however, these orthoses often result in only small and variable changes in gait. Research with adult stroke survivors has suggested that orthoses that extend beyond the ankle using long, passive tendon-like structures (i.e. exotendons) can improve walking. OBJECTIVES: The aim of this study was to quantify the impact of an exotendon-based exoskeleton on pediatric gait. STUDY DESIGN: Repeated-measures study. METHODS: Two typically-developing children and two children with hemiparesis completed a gait analysis, walking without and with the exoskeleton. The exotendon was tested at three stiffness levels. RESULTS: All children were able to walk comfortably with the exoskeleton, with minimal changes in step width. Walking speed increased and lower limb joint symmetry improved for the children with hemiparesis with the exoskeleton. Each participant had changes in muscle activity while walking with the exoskeleton, although the impact on specific muscles and response to exotendon stiffness varied. CONCLUSION: Exotendon-based exoskeletons may provide an alternative solution for optimizing gait in therapy and in the community for children with hemiparesis. Determining the optimal stiffness and configuration for each child is an important area of future research.
Authors: Jan F Veneman; Jasper Menger; Edwin H F van Asseldonk; Frans C T van der Helm; Herman van der Kooij Journal: Gait Posture Date: 2008-01-22 Impact factor: 2.840
Authors: Robert J Kuczmarski; Cynthia L Ogden; Shumei S Guo; Laurence M Grummer-Strawn; Katherine M Flegal; Zuguo Mei; Rong Wei; Lester R Curtin; Alex F Roche; Clifford L Johnson Journal: Vital Health Stat 11 Date: 2002-05
Authors: R N Boyd; F Dobson; J Parrott; S Love; J Oates; A Larson; G Burchall; P Chondros; J Carlin; G Nattrass; H K Graham Journal: Eur J Neurol Date: 2001-11 Impact factor: 6.089