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The Journal of Neurophysiology Vol. 81 No. 6 June 1999, pp. 2893-2902
Copyright ©1999 by the American Physiological Society
1Department of Biomedical Engineering, McGill University, Montreal, Quebec H3A 2B4; and 2Division of Neuroscience, University of Alberta, Edmonton, Alberta T6G 2S2, Canada
Kearney, Robert E.,
Mireille Lortie, and
Richard B. Stein.
Modulation of Stretch Reflexes During Imposed Walking Movements
of the Human Ankle. J. Neurophysiol. 81: 2893-2902, 1999.
Modulation of stretch reflexes during imposed walking movements of the
human ankle. Our overall objectives were to examine the role of
peripheral afferents from the ankle in modulating stretch reflexes
during imposed walking movements and to assess the mechanical
consequences of this reflex activity. Specifically we sought to define
the changes in the electromyographic (EMG) and mechanical responses to
a stretch as a function of the phase of the step cycle. We recorded the
ankle position of a normal subject walking on a treadmill at 3 km/h and
used a hydraulic actuator to impose the same movements on supine
subjects generating a constant level of ankle torque. Small pulse
displacements, superimposed on the simulated walking movement, evoked
stretch reflexes at different phases of the cycle. Three major findings
resulted: 1) soleus reflex EMG responses were influenced
strongly by imposed walking movements. The response amplitude was
substantially smaller than that observed during steady-state conditions
and was modulated throughout the step cycle. This modulation was
qualitatively similar to that observed during active walking. Because
central factors were held constant during the imposed walking
experiments, we conclude that peripheral mechanisms were capable of
both reducing the amplitude of the reflex EMG and producing its
modulation throughout the movement. 2) Pulse disturbances
applied from early to midstance of the imposed walking cycle generated
large reflex torques, suggesting that the stretch reflex could help to
resist unexpected perturbations during this phase of walking. In
contrast, pulses applied during late stance and swing phase generated
little reflex torque. 3) Reflex EMG and reflex torque were
modulated differently throughout the imposed walking cycle. In fact, at
the time when the reflex EMG response was largest, the corresponding
reflex torque was negligible. Thus movement not only changes the reflex
EMG but greatly modifies the mechanical output that results.
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