• Title of article

    Distributed moment histogram: A neurophysiology based method of agonist and antagonist trunk muscle activity prediction

  • Author/Authors

    Ulrich Raschke، نويسنده , , Bernard J. Martin، نويسنده , , Don B. Chaffin، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 1996
  • Pages
    10
  • From page
    1587
  • To page
    1596
  • Abstract
    A neurocortical-based technique of muscle recruitment is presented to solve the muscle indeterminacy problem for lumbar torso modeling. Cortical recordings from behaving primates have established motor cortex cells that respond to a wide range of task directions, but are tuned to a preferred direction. A characteristic activity pattern of these neurons seems to be associated with effort direction. It was hypothesized that a model which recruits muscles based on a similar distribution would predict antagonistic muscle activity with greater realism than a widely referenced optimization formulation. The predictions of the Distributed Moment Histogram (DMH) method were evaluated under common speed (<30os−1) sagittal plane lifting conditions using five subjects. The predicted forces showed high correspondence with agonist and antagonist myoelectric patterns. The mean coefficient of determination for the erector spinae was r2=0.91, and 0.41 for the latissimus. For the antagonistic muscles, the rectus abdominus was found to be electrically silent (<3% MVC) and no activity was predicted by the method. The external oblique muscle was observed to be minimally active (<16% MVC), and the DMH method predicted its mostly constant activity with a mean standard error of 1.6% MVC. The realistic antagonistic predictions supported the hypothesis and justify this cortical based technique as an alternative for muscle tension estimation in biomechanical torso modeling. A primary advantage of this method is its computational simplicity and direct physiologic analogy
  • Keywords
    Dynamic analysis , Electromyography , Trunk muscle recruitment , Trunk biomechanical modeling , Neurophysiology.
  • Journal title
    Journal of Biomechanics
  • Serial Year
    1996
  • Journal title
    Journal of Biomechanics
  • Record number

    450434