Influence of Instruction, Prediction and Afferent Sensory Information on
the Postural Organization of Step Initiation.
Burleigh, A. and F. Horak.
R.S. Dow Neurological Sciences Institute, Portland, Oregon, 97209.
APStracts 2:0304N, 1995.
SUMMARY AND CONCLUSIONS
1. Our previous study showed that when subjects were instructed to step in
response to a backward surface translation, rather than maintain stance, two
distinct postural modifications occurred: 1) the automatic postural responses
to the surface perturbation were reduced in magnitude; 2) the anticipatory
postural adjustments promoting foot-off were shortened in duration. This study
investigates the extent to which task instruction, prediction of perturbation
velocity and afferent sensory information related to perturbation velocity are
responsible for these postural modifications. 2. Eleven human subjects were
instructed, in advance, to either maintain stance or step forward in response
to a backward surface translation. Four different velocities of translation
were used to perturb equilibrium. To assess the influence of predicted versus
actual velocity information, the surface translations were presented in both a
blocked order of increasing perturbation velocity (predictable) and a random
order (unpredictable). Lower extremity electromyographs (EMGs), ground
reaction forces and movement kinematics were quantified for both the automatic
postural responses to perturbation and the anticipatory postural adjustments
for step initiation. 3. The instruction to step was not solely responsible for
the suppression of the automatic postural response. Prediction of perturbation
velocity was required for significant suppression of the early automatic
postural response when subjects stepped in response to the perturbation. When
compared to the stance condition, the magnitude of the inital 50 ms of the
automatic response in bilateral soleus and the left limb gastrocnemius
(initial stance limb) was significantly reduced only when the perturbation
velocities were presented in a blocked order. The magnitude of the automatic
response was not reduced in the gastrocnemius of the right limb, which was
always the initial swing limb and recruited for heel-off in the step
conditions. This asymmetrical reduction of the gastrocnemius suggests that
modification of the response was specific to the instruction, rather than a
general decrease in the extensor muscle excitability. 4. The suppression of
the early automatic postural response involved a change in the bias of the
response. Despite the reduced magnitude during the predictable velocity step
condition, the slope (i.e. gain) of the response with increasing velocities
was not different from that of the stance condition. Thus, the excitability of
the automatic response was reduced by a relatively constant amount for each
velocity when the perturbation velocity was predictable. 5. In contrast to the
importance of velocity prediction for modification of the automatic postural
response, actual velocity information was used for modification of the
anticipatory postural adjustments when step was initiated in response to the
surface perturbation. Regardless of whether the perturbation velocities were
presented in a blocked or random order, the anticipatory postural adjustments
were rapidly initiated and the duration of the postural adjustments for step
initiation was shortened as the velocity of perturbation increased. 6. We
conclude that the CNS uses prediction of perturbation velocity to modify the
excitability of early automatic postural responses when the postural goal
changes. In contrast, actual afferent velocity information can be used to
modify the duration of the anticipatory postural adjustments for a voluntary
step in response to perturbation. Thus, the CNS utilizes feed-forward
prediction to modify peripherally-triggered postural responses, and utilizes
immediate afferent information to modify the centrally-initiated postural
adjustments associated with voluntary movement.
Received 30 June 1995; accepted in final form 23 October 1995.
APS Manuscript Number J419-5.
Article publication pending J. Neurophysiol.
ISSN 1080-4757 Copyright 1995 The American Physiological Society.
Published in APStracts on 6 November 95