On the role of parvocellular (P) and magnocellular (M) pathways in cerebral achromatopsia

doi:10.1093/brain/117.2.245

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Brain, Vol. 117, No. 2, 245-254, 1994
© 1994 Oxford University Press

research-article

On the role of parvocellular (P) and magnocellular (M) pathways in cerebral achromatopsia

Charles A. Heywood¹, Alan Cowey¹^, and Freda Newcombe²

¹Department of Experimental Psychology, University of Oxford Oxford, UK ²Russell Cairns Head Injury Unit, Radcliffe Infirmary Oxford, UK

Correspondence to: Professor Alan Cowey, Department of Experimental Psychology, University of Oxford, South Parks Road, Oxford OX1 3UD, UK

We assessed the ability of an achromatopsic patient to detectand discriminate colour and form concealed in a static or dynamiccheckerboard display where the luminance differences among adjacentsquares were randomly assigned. There were no conditions underwhich he could discriminate two very different saturated coloursfrom each other. Nevertheless, he could discriminate chromaticfrom luminance boundaries in static displays when the colourdefining the boundary was saturated and the achromatic boundariesall had similar luminance contrast, i. e. varied over a narrowrange. However, he could not readily detect chromatic boundariesfrom among many achromatic boundaries that differed widely inluminance contrast. In addition, he was able to detect chromaticboundaries even when they were concealed by dynamic random luminancemasking. His ability to pick out chromatic borders was abolishedwhen desaturated colours were used. However, he was singularlyproficient at detecting coloured forms in static or dynamicdisplays even when the saturation of the colours of which theform was composed were such that they were rendered invisiblewhen concealed as a single square in a checkerboard. This impliesthat signals about chroma are still available in extractingshape. The patient performed flawlessly when asked to indicatethe direction of motion of a horizontal red/green isoluminantgrating which was phase shifted by 90° in either direction,demonstrating unequivocally that he has access to the sign ofcolours that he nevertheless does not perceive.

colour vision; visual cortex

Received May 4, 1993. Revised November 9, 1993. Accepted January 11, 1994.

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