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The Journal of Neurophysiology Vol. 86 No. 6 December 2001, pp. 3056-3060
Copyright ©2001 by the American Physiological Society
RAPID COMMUNICATION
1Department of Anatomy and 2Department of Ophthalmology, The University of Mississippi Medical Center, Jackson, Mississippi 39216
Yan, Yi-Jun,
Dong-Mei Cui, and
James C. Lynch.
Overlap of Saccadic and Pursuit Eye Movement Systems in the Brain
Stem Reticular Formation. J. Neurophysiol. 86: 3056-3060, 2001. Recent physiological studies have
suggested that there are several sites of interaction between the
neural pathways that control saccadic eye movements and those that
control visual pursuit movements. To address the question of
saccade/pursuit interaction from a neuroanatomical point of view, we
have studied the connections from the smooth and saccadic eye movement
subregions of the frontal eye field (FEFsem and FEFsac, respectively)
to the rostral interstitial nucleus of the medial longitudinal
fasciculus (riMLF) in four Cebus apella monkeys. The riMLF
has traditionally been considered to be a premotor center for vertical
saccadic eye movements on the basis of single neuron recording
experiments, microstimulation experiments, and surgical or chemical
lesion experiments. We localized the functional subregions of the FEF
with the use of low-threshold (
50 µA) intracortical
microstimulation. Biotinylated dextran amine or lectin from triticum
vulgaris (wheat germ), peroxidase labeled, was placed into these
functionally defined subregions to label anterogradely the terminals of
axons that originated in the FEF. Our results demonstrate that both the
FEFsem and FEFsac send direct projections to the ipsilateral riMLF. The
distribution and density of labeling from the FEFsem are comparable to
those from the FEFsac. The direct FEFsem-to-riMLF projection suggests a
possible role of the riMLF in smooth pursuit eye movements and supports
the hypothesis that there is interaction between the saccadic and
pursuit subsystems at the brain stem level.
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