The temporal and spatial processing of viewing eye movements was studied by
magnetoencephalography (MEG) in six normal subjects. Three visual stimulus
types were studied: (1) moving eyes (EYES), (2) moving simulated eyes (SLM
), consisting of checks moving in the same spatial location as EYES, and (3
) an inwardly moving radial pattern (RADIAL), A large clear MEG component,
1M, with mean peak latency of approximately 170 ms, was seen in the right h
emisphere to RADIAL and EYES in all six subjects, The 1M to EYES was signif
icantly longer in latency and smaller in amplitude than that seen to RADIAL
. A left hemisphere 1M to EYES and RADIAL was seen in three of six subjects
. In all subjects and both hemispheres the equivalent current dipoles (ECD)
for EYES and RADIAL were located near the occipitotemporal border, the MT/
V5 homologue in humans. The ECD to EYES was significantly more posterior an
d inferior than that to RADIAL, with a calculated significant separation di
stance of around 1 cm, No ECD was estimated in the fusiform gyrus, a struct
ure that plays a main role in static face perception. Although the 1M was d
etected in SIM in all six subjects, our criteria for a reliable ECD could o
nly be satisfied in only one subject. Our results suggest that the cortex o
f human MT/V5 and its surrounds is active both in the perception of eye mot
ion and motion in general, particularly in the right hemisphere. The areas
responsive to eye motion were separable from those responsive to radial mot
ion. These data suggest that there may be specialization within regions of
human cortex previously thought to be sensitive to motion in general, (C) 2
001 Academic Press.