Oblique Effect: A Neural Basis in the Visual Cortex

doi:10.1152/jn.00954.2002

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Oblique Effect: A Neural Basis in the Visual Cortex

Baowang Li, Matthew R. Peterson and Ralph D. Freeman

Group in Vision Science, School of Optometry and Helen Wills Neuroscience Institute, University of California, Berkeley, California 94720-2020

Submitted 24 October 2002; accepted in final form 24 February 2003

The details of oriented visual stimuli are better resolved whenthey are horizontal or vertical rather than oblique. This "obliqueeffect" has been confirmed in numerous behavioral studies inhumans and to some extent in animals. However, investigationsof its neural basis have produced mixed and inconclusive results,presumably due in part to limited sample sizes. We have useda database to analyze a population of 4,418 cells in the cat's striate cortex to determine possible differences as a functionof orientation. We find that both the numbers of cells andthe widths of orientation tuning vary as a function of preferredorientation. Specifically, more cells prefer horizontal andvertical orientations compared with oblique angles. The largest population of cells is activated by orientations close to horizontal.In addition, orientation tuning widths are most narrow forcells preferring horizontal orientations. These findings aremost prominent for simple cells tuned to high spatial frequencies.Complex cells and simple cells tuned to low spatial frequenciesdo not exhibit these anisotropies. For a subset of simple cellsfrom our population (n = 104), we examined the relative contributionsof linear and nonlinear mechanisms in shaping orientation tuning curves. We find that linear contributions alone do not accountfor the narrower tuning widths at horizontal orientations.By modeling simple cells as linear filters followed by staticexpansive nonlinearities, our analysis indicates that horizontallytuned cells have a greater nonlinear component than those tunedto other orientations. This suggests that intracortical mechanismsplay a major role in shaping the oblique effect.

Address for reprint requests: R. Freeman, 360 Minor Hall, Berkeley, CA 94720-2020 (E-mail: freeman{at}neurovision.berkeley.edu).

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