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The Journal of Neurophysiology Vol. 87 No. 2 February 2002, pp. 859-875
Copyright ©2002 by the American Physiological Society
Aerospace Medical Research Unit, Department of Physiology, McGill University, Montreal, Quebec H3G 1Y6, Canada
Dubrovsky, Alexander S. and
Kathleen E. Cullen.
Gaze-, Eye-, and Head-Movement Dynamics During Closed- and
Open-Loop Gaze Pursuit. J. Neurophysiol. 87: 859-875, 2002. Horizontal step-ramp stimuli were used to examine
gaze-, eye-, and head-movement dynamics during head-unrestrained
pursuit in two rhesus monkeys. In a first series of experiments, we
characterized and compared head-restrained (HR) and -unrestrained (HU)
pursuit responses to unpredictable, nonperiodic, constant velocity
(20-80°/s) stimuli. When the head was free to move, both monkeys
used a combination of eye and head motion to initially fixate and then
pursue the target. The pursuit responses (i.e., gaze responses) were
highly stereotyped and nearly identical among the HR and HU conditions for a given step-ramp stimulus. In the HU condition, initial eye and
initial head acceleration tended to increase as a function of target
velocity but did not vary systematically with initial target
eccentricity. In a second series of experiments, step-ramp stimuli
(40°/s) were presented, and, ~125 ms after pursuit onset, a
constant retinal velocity error (RVE) was imposed for a duration of 300 ms. In each monkey, HR and HU gaze velocity was similarly affected by
stabilizing the target with respect to the monkey's fovea (i.e.,
RVE = 0°/s) and by moving the target with constant retinal
velocity errors (i.e., RVE = ±10°/s). In the HU condition, changes in both eye and head velocity trajectories contributed to the
observed gaze velocity responses to imposed RVEs. We conclude that eye
and head movements are not independently controlled during HU pursuit
but rather are controlled, at least in part, by a shared upstream
controller within the pursuit pathways.
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