Comparison of the Discharge Characteristics of Brainstem Omnipause Neurons
and Superior Colliculus Fixation Neurons in Monkey: Implications for Control
of Fixation and Saccade Behavior.
Stefan Everling, Martin Par‚, Michael C. Dorris, and Douglas P. Munoz.
Medical Research Council Group in Sensory-Motor Neuroscience, Department of
Physiology, Queen's University, Kingston, Ontario K7L 3N6, Canada.
APStracts 4:294N, 1997.
ABSTRACT
Fixation neurons (SCFNs) in the rostral pole of the superior colliculus (SC)
and omnipause neurons (OPNs) in the nucleus raphe interpositus (rip) in the
pons share similar discharge properties. Both types of neurons discharge
tonically during periods of visual fixation and pause for saccadic eye
movements, and their activation by electrical stimulation suppresses saccade
generation. Based on these similarities and the projection from the rostral SC
to the rip, it was hypothesized that SCFNs provide a major excitatory input to
OPNs. We investigated the role and relationship of SCFNs and OPNs with respect
to both fixation behavior and saccade generation by comparing their activity
recorded in the same monkeys performing a gap saccade task. In this task, the
central fixation point was extinguished 200 ms before the presentation of an
eccentric saccadic target, and the discharges of OPNs and SCFNs were
contrasted during visual fixation, non-visual (gap) fixation, and saccade
generation. During visual fixation, the mean discharge rate of OPNs was higher
and more regular than that of SCFNs. During the gap period, SCFNs decreased
their discharge rate before target appearance, whereas no change in discharge
rate was observed in OPNs. For both SCFNs and OPNs, the activity level before
target appearance was not correlated to saccadic reaction time. In contrast to
SCFNs, several OPNs responded with a transient phasic increase in discharge
immediately following the target presentation. Before their saccade-related
pause, there was a gradual reduction in the activity of SCFNs, whereas OPNs
had an abrupt cessation of discharge. SCFNs paused earlier than OPNs, but the
OPN pause onset was better synchronized to saccade onset than the SCFN pause
onset. OPNs resumed firing after their pause in activity earlier than SCFNs,
and the OPN pause end was better synchronized to saccade end than the SCFN
pause end. These physiological data reveal differences in the discharge
properties of SCFNs and OPNs that are irreconcilable with the hypothesis that
the discharge pattern of OPNs reflects simply the excitatory input from SCFNs.
It is most likely that additional inputs to OPNs compensate for the reduction
in discharge of SCFNs during these periods.
Received 8 July 1997; accepted in final form 21 October 1997.
APS Manuscript Number J568-7.
Article publication pending J. Neurophysiol.
ISSN 1080-4757 Copyright 1997 The American Physiological Society.
Published in APStracts on 29 October 1997