Role of the Unperturbed Limb and Arms in the Reactive Recovery Response to an Unexpected Slip During Locomotion

doi:10.1152/jn.00683.2002

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Role of the Unperturbed Limb and Arms in the Reactive Recovery Response to an Unexpected Slip During Locomotion

Daniel S. Marigold, Allison J. Bethune, and Aftab E. Patla

Gait and Posture Lab, Department of Kinesiology, University of Waterloo, Waterloo, Ontario N2L 3G1, Canada

Marigold, Daniel S., Allison J. Bethune, and Aftab E. Patla. Role of the Unperturbed Limb and Arms in the Reactive Recovery Response to an Unexpected Slip During Locomotion. J. Neurophysiol. 89: 1727-1737, 2003. Understanding reactive recovery responses to slipping is fundamental in falls research and prevention. The primary purposeof this study was to investigate the role of the unperturbed limband arms in the reactive recovery response to an unexpected slip.Ten healthy, young adults participated in this experiment in whichan unexpected slip was induced by a set of steel free-wheelingrollers. Surface electromyography (EMG) data were collected fromthe unperturbed limb (i.e., the swing limb) rectus femoris, bicepsfemoris, tibialis anterior, and the medial head of gastrocnemius,and bilateral gluteus medius, erector spinae, and deltoids. Kinematicdata were also collected by an optical imaging system to monitorlimb trajectories. The first slip response was significantly differentfrom the subsequent recovery responses to the unexpected slips,with an identifiable reactive recovery response and no proactivechanges in EMG patterns. The muscles of the unperturbed limb,upper body, and arms were recruited at the same latency as thosepreviously found for the perturbed limb. The arm elevation strategiesassisted in shifting the center of mass forward after it was posteriorlydisplaced with the slip, while the unperturbed limb musculaturedemonstrated an extensor strategy supporting the observed loweringof the limb to briefly touch the ground to widen the base of supportand to increase stability. Evidently a dynamic multilimb coordinatedstrategy is employed by the CNS to control and coordinate theupper and lower limbs in reactive recovery responses to unexpectedslips duringlocomotion.

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