Interaction of the two frontal eye fields prior to saccade onset.
J. Schlag, P. Dassonville & M. Schlag-Rey.
Department of Neurobiology and Brain Research Institute, UCLA School of
Medicine, Los Angeles, CA 90095-1763.
APStracts 4:0254N, 1997.
ABSTRACT
A normal environment often contains many objects of interest that compete to
attract our gaze. Nevertheless, instead of initiating a flurry of conflicting
signals, central populations of oculomotor neurons always seem to agree on the
destination of the next saccade. How is such a consensus achieved? In a unit
recording and microstimulation study on trained monkeys, we sought to
elucidate the mechanism through which saccade-related cells in the frontal eye
fields (FEF) avoid issuing competing commands. Presaccadic neuronal activity
was recorded in one FEF while stimulating the contralateral FEF with low-
intensity currents that evoked saccades. When an eye-movement cell was
isolated, we determined: 1) the movement field of the cell, 2) the cell's
response to contralateral FEF microstimulation, 3) the cell's response when
the evoked saccade was in the preferred direction of the cell (using the
collision technique to deviate appropriately the evoked saccade vector), 4)
the cell's response to a stimulation applied during a saccade in the cell's
preferred direction, in order to reveal a possible inhibitory effect. Complete
results were obtained for 71 stimulation-recording pairs of FEF sites. The
unit responses observed were distributed as follows: 35% of the cells were
unaffected, 37% were inhibited and 20% excited by contralateral stimulation.
These response types depended on the site of contralateral stimulation and did
not vary when saccades were redirected by collision. This invariant excitation
or inhibition of cells, seemingly due to hardwired connections, depended on
the angular difference between their preferred vector and the vector
represented by the cells stimulated. By contrast, 8% of the cells were either
activated or inhibited depending on the vector of the saccade actually evoked
by collision. These results suggest that the consensus between cells of
oculomotor structures at the time of saccade initiation is implemented by
functional connections such that the cells which command similar movements
mutually excite each other while silencing those that would produce
conflicting movements. Such a rule would be an effective implementation of a
winner-take-all mechanism well suited to prevent conflicts.
Received 24 March 1997; accepted in final form 11 September 1997.
APS Manuscript Number J248-7.
Article publication pending J. Neurophysiol.
ISSN 1080-4757 Copyright 1997 The American Physiological Society.
Published in APStracts on 7 October 1997