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The Journal of Neurophysiology Vol. 84 No. 3 September 2000, pp. 1266-1278
Copyright ©2000 by the American Physiological Society
1Department of Molecular and Cell Biology and 2Department of Biophysics, University of California at Berkeley, Berkeley, California 94720-3200
Freeman, Walter J. and
John M. Barrie.
Analysis of Spatial Patterns of Phase in Neocortical Gamma EEGs
in Rabbit. J. Neurophysiol. 84: 1266-1278, 2000. Arrays of 64 electrodes (8 × 8, 7 × 7 mm)
were implanted epidurally on the surface of the visual, auditory or
somatosensory cortex of rabbits trained to discriminate conditioned
stimuli in the corresponding modality. The 64 electroencephalographic (EEG) traces at all times displayed a high degree of spatial coherence in wave form, averaging >90% of the variance in the largest principal components analysis component. The EEGs were decomposed with the fast
Fourier transform (FFT) to give the spatial distributions of amplitude
and phase modulation (AM and PM) in segments 128 ms in duration.
Spatial (2-dimensional) and temporal (1-dimensional) filters were
designed to optimize classification of the spatial AM patterns in the
gamma range (20-80 Hz) with respect to discriminative conditioned
stimuli. No evidence was found for stimulus-dependent classification of
the spatial PM patterns. Instead some spatial PM distributions
conformed to the pattern of a cone. The location and sign (maximal lead
or lag) of the conic apex varied randomly with each recurrence. The
slope of the phase gradient varied in a range corresponding to that of
the conduction velocities reported of axons to extend parallel to the
cortical surfaces. The durations and times of recurrence of the phase
cones corresponded to those of the optimally classified spatial AM
patterns. The interpretation is advanced that the phase cones are
manifestations of state transitions in the mesoscopic dynamics of
sensory cortices by which the intermittent AM patterns are formed. The
phase cones show that the gamma EEG spatial coherence is not due to
volume conduction from a single deep-lying dipole generator nor to
activity at the site of the reference lead on monopolar recording. The
random variation of the apical sign shows that gamma AM patterns are
self-organized and are not imposed by thalamic pacemakers. The
half-power radius of the phase gradient provides a useful measure of
the soft boundary condition for the formation and read-out of
cooperative cortical domains responsible for binding sensory
information into the context of prior experience in the process of perception.
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