Management of scoliosis with special seating for the non-ambulant spastic cerebral palsy population - a biomechanical study

K.J. Holmes, S.M. Michael, S.L. Thorpe, S.E. Solomonidis

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    32 Citations (Scopus)

    Abstract

    Study aimed to investigate the effects of special seating on lateral spinal curvature in the non-ambulant spastic cerebral palsy population with scoliosis. The shape of the spine was measured with subjects sitting in an assessment chair with a clear backrest. The measurement recorded was the "spinous process angle", an approximation to the Cobb angle. The forces exerted on the subject by the chair were measured by electrical resistance strain gauged transducers attached to the lateral support pads and seat base. Measurements were taken with three alternative arrangements of lateral support pads: upper body unsupported in configuration 1; two lateral pads at the same height in configuration 2; body supported by a 3-point force system in configuration 3. Configuration 3 gave a mean correction of +35% in the spinous process angle compared to configuration 1 (P=0.000) and the forces applied through the two lateral thoracic pads were, on average, of similar magnitude (mean values of 51 and 47 N). In comparison, for configuration 2 the mean correction was only +18.7% (P=0.004) and on average the pad on the concave side of the scoliosis applied a much larger force to the chest wall than the pad on the convex side (mean values of 36 and 17 N respectively). Significant static correction of the scoliotic spine can be achieved with an arrangement of lateral pads on a seating system that applies a 3-point force system to the sides of the body.
    Original languageEnglish
    Pages (from-to)480-487
    Number of pages7
    JournalClinical Biomechanics
    Volume18
    Issue number6
    DOIs
    Publication statusPublished - 2003

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    Keywords

    • scoliosis
    • spastic
    • cerebral palsy
    • wheelchairs
    • posture
    • 3-point force
    • bioengineering

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