Effect of Vertical Disparities on Depth Representation in Macaque Monkeys: MT Physiology and Behavior

Department of Anatomy and Neurobiology, Washington University School of Medicine, Saint Louis, Missouri Submitted 29 June 2007; accepted in final form 7 December 2007 Horizontal binocular disparities provide information about the distance of objects relative to the point of ocular fixation and must be combined with an estimate of viewing distance to recover the egocentric distance of an object. Vergence angle and the gradient of vertical disparities across the visual field are thought to provide independent sources of viewing distance information based on human behavioral studies. Although the effect of vergence angle on horizontal disparity selectivity in early visual cortex has been examined (with mixed results), the effect of the vertical disparity field has not been explored. We manipulated the vertical disparities in a large random-dot stimulus to simulate different viewing distances, and we examined the effect of this manipulation on both the responses of neurons in the middle temporal (MT) area and on the psychophysical performance of the animal in a curvature discrimination task. We report here that alterations to the vertical disparity field have no effect on the horizontal disparity tuning of MT neurons. However, the same manipulation strongly and systematically biases the monkey's judgments of curvature, consistent with previous human studies. We conclude that monkeys, like humans, make use of the vertical disparity field to estimate viewing distance, but that the physiological mechanisms for this effect occur either downstream of MT or in a different pathway. Present address and address for reprint requests and other correspondence: G. C. DeAngelis, Professor of Brain and Cognitive Sciences, Center for Visual Science, 245 Meliora Hall, University of Rochester, Rochester, NY 14627-0270 (E-mail: gdeangelis{at}cvs.rochester.edu )