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Journal home Advance online publication Current issue Archive Press releases Supplements Focuses Guide to authors Online submission Permissions For referees Free online issue Contact the journal Subscribe Advertising work@npg naturereprints About this site For librarians   NPG Resources Nature Nature Reviews Neuroscience Nature Cell Biology Nature Medicine Neuroscience Gateway UCSD-Nature Signaling Gateway NPG Subject areas Biotechnology Cancer Chemistry Clinical Medicine Dentistry Development Drug Discovery Earth Sciences Evolution & Ecology Genetics Immunology Materials Science Medical Research Microbiology Molecular Cell Biology Neuroscience Pharmacology Physics Browse all publications Article Nature Neuroscience  4, 513 - 518 (2001) doi:10.1038/87462 Joint-encoding of motion and depth by visual cortical neurons: neural basis of the Pulfrich effect Akiyuki Anzai1, 2, Izumi Ohzawa1, 3 & Ralph D. Freeman1 1  Group in Vision Science, School of Optometry, University of California, Berkeley, California 94720-2020, USA 2  Present address: Department of Anatomy and Neurobiology, Washington University School of Medicine, St. Louis, Missouri 63110, USA 3  Present address: Department of Biophysical Engineering, Graduate School of Engineering Science, Osaka University, Toyonaka, Osaka, 560-8531, Japan Correspondence should be addressed to Ralph D. Freeman freeman@neurovision.berkeley.eduMotion and stereoscopic depth are fundamental parameters of the structural analysis of visual scenes. Because they are defined by a difference in object position, either over time or across the eyes, a common neural machinery may be used for encoding these attributes. To examine this idea, we analyzed responses of binocular complex cells in the cat striate cortex to stimuli of various intra- and interocular spatial and temporal shifts. We found that most neurons exhibit space−time-oriented response profiles in both monocular and binocular domains. This indicates that these neurons encode motion and depth jointly, and it explains phenomena such as the Pulfrich effect. We also found that the relationship between neuronal tuning of motion and depth conforms to that predicted by the use of motion parallax as a depth cue. These results demonstrate a joint-encoding of motion and depth at an early cortical stage.  Top Abstract Previous | Next Table of contents Full text Download PDF Send to a friend Save this link Open Innovation Challenges Novel Approaches to Protecting Maize from Insect Damage Deadline: Nov 29 2009 Reward: $20,000 USD The Seeker is looking for novel approaches to protecting maize from insect damage. This Challenge re... Methods of Modeling Adaptation in Populations Deadline: Dec 30 2009 Reward: $15,000 USD The analysis of adaptation with a population is a frequently encountered computational modeling scen... More Challenges Powered by: nature jobs Professor of Cognitive Neuroscience Karolinska Institute Stockholm Sweden Assistant / Associate / Full Professor Northeastern University Boston, MA More science jobs Post a job for free Figures & Tables Export citation Search buyers guide:   ADVERTISEMENT

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