Speed Selectivity for Optic Flow in Area 7a of the Behaving Macaque

doi:10.1093/cercor/10.4.413

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Cerebral Cortex, Vol. 10, No. 4, 413-421, April 2000
© 2000 Oxford University Press

Speed Selectivity for Optic Flow in Area 7a of the Behaving Macaque

Raymond E. Phinney and Ralph M. Siegel

Center for Molecular and Behavioral Neuroscience, Rutgers University, Newark, NJ 07102, USA

Area 7a, in the inferior parietal lobe, has been implicatedin optic flow processing to obtain spatial information aboutthe environment. Optic flow, angle-of-gaze and center-of-motiondependencies are already documented, but the selectivity ofarea 7a to speed is unknown. Such information is crucial asarea 7a provides the final step in visual motion analysis thatbegins at the lateral geniculate nucleus and passes throughMT, MST and LIP/VIP. Macaque area 7a neurons were tested withoptic flows with speeds of 0.5–128°/s. Of 161 neuronstested in four hemispheres of two adult male macaques, 53% (86/161)were speed selective at either the time of stimulus onset, atthe end of the trial, or at both times. Speed selec- tivitiesresembling the basic filter types (band-pass, band-reject, high-pass,low-pass, broadband) were found. Area 7a neurons exhibited twonovel properties not previously reported elsewhere. Speed selectivitywas found to be dynamic in that many cells gained, lost or changedspeed tuning over the course of a trial. In addition, speeddependence and optic flow selectivity interacted. For example,a cell could preferentially respond to one type of naviga- tionaloptic flow at a slow speed and a different navigational opticflow at a fast speed. The presence of speed selectivity combinedwith other properties of area 7a neurons indicates that theseneurons may have a role in the concurrent representation ofheading as well as multiple object speeds and directions.

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