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Citation |
Cottereau BR, McKee SP, Norcia AM. J. Neurophysiol. 2014; 111(3): 533-543. |
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Affiliation |
CerCo, CNRS UMR5549. |
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Copyright |
(Copyright © 2014, American Physiological Society) |
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DOI |
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PMID |
24198326 |
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Abstract |
The perception of motion-in-depth is important for avoiding collisions and for the control of vergence eye-movements and other motor actions. Previous psychophysical studies have suggested that sensitivity to motion-in-depth has a lower temporal processing limit than the perception of lateral motion. The present study used fMRI-informed EEG source-imaging to study the spatio-temporal properties of the responses to lateral motion and motion-in-depth in human visual cortex. Lateral motion and motion-in-depth displays comprised stimuli whose only difference was inter-ocular phase - monocular oscillatory motion was either in-phase in the two eyes (lateral motion) or in anti-phase (motion-in-depth). Spectral analysis was used to break the steady-state visually evoked potentials (SSVEP) responses down into even and odd harmonic components within five functionally defined regions of interest (ROIs): V1, V4, lateral occipital complex (LOC), V3A and hMT+. We also characterized the responses within two anatomically defined regions: the inferior and superior parietal cortex. Even harmonic components dominated the evoked responses and were a factor of approximately two larger for lateral motion than motion-in-depth. These responses were slower for motion-in-depth and were largely independent of absolute disparity. In each of our ROIs, responses at odd-harmonics were relatively small, but were larger for motion-in-depth than lateral motion, especially in parietal cortex and depended on absolute disparity. Taken together, our results suggest a plausible neural basis for reduced psychophysical sensitivity to rapid motion-in-depth. Language: en |