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Colour Vision I The retinal basis of colour vision and the inherited colour vision deficiencies Prof. Kathy T. Mullen McGill Vision Research (H4.14) Dept. of Ophthalmology kathy.mullen@mcgill.ca 8th Sept 2005
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What is colour? What physical aspect of the world does our sense of colour inform us about?
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Spectral colors 425 500 550 600 650 Violet Indigo Blue Green Yellow Orange Red Wavelength (nm)
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Reflectance curves of some common foods Reflectance (percent) Wavelength (nm) Lemon Tomato Orange Cabbage
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The colour circle
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What is colour? Colour vision allows us to distinguish between surfaces with different spectral reflectances
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How do we see colour?
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White light is produced by mixing three colours
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Mixing red and green lights to match yellow. ABC A and B. Green and red lights on the top are mixed by the subject to match the yellow light presented on the bottom. C. The red-green mixture perfectly matches the yellow. The same match as it appears to a deuteranomalous observer.
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Principle of Trichromacy Mixing together three coloured lights in suitable proportions enables us to make an exact match to any other colour The 3 mixing lights are called ‘primaries’ The match is called ‘metameric’ - meaning that identical colour sensations are produced even though the stimuli are physically different 3 mixing lights test light to be matched L1 + L2 + L3 L4
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Spectral sensitivities of L, M & S cones Wavelength (nm) Log relative sensitivity Long Medium Short
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A single type of photoreceptor cannot signal colour Relative absorbance % 100 50 450550 (nm) L1L2
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Response curve for a single receptor Relative absorbance % Wavelength (nm) L1L2 L1 = 2 (L2)
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Principle of Univariance The response of a photoreceptor to any wavelength can be matched to any other wavelength simply by adjusting the relative intensities of the two stimuli Therefore: any single receptor type is colour blind
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Response curve for a two receptor system Cone 1Cone 2 540 565 Wavelength relative absorbance % 100
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How is colour coded? Each colour produces a unique pattern of relative activities in the three cone types
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The basis of colour mixing in a two receptor (dichromatic) system ML L1L2 L3 WL (nm) 100 50 0 M L L:M L1 L2 L1+L2L3 Relative absorbancy Receptors Lights The mixture of red and green light looks the same as the yellow light because the red-green mixture and the yellow produce the same quantal absorptions in the L and M cones A dichromatic system requires 2 mixing lights A trichromatic (three receptor) system requires 3 mixing lights (primaries) 9055145 5095145 1:1 95 1:1
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Colours with different wavelength distributions will look identical if they produce the same ratio of quantum catches in the L, M and S cone types
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Metameric (matched) colour pairs for colour deficient observers
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Inherited color vision deficiencies Systematic and predictable losses Both eyes affected Male - sex linked for L & M (red-green) deficiencies Genetic S cone deficiencies are autosomal and rare - many are undetected Color vision tests may not detect achromats
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Trichromats One of the three cone types is anomalous
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Trichromats Three colours are required to match any other See a full range of colours, but with poorer discrimination in some regions Types Protanomalous = anomalous L cones 1% (m) Deuteranomalous = anomalous M cones 5%(m) ‘Tritanomalous’ = incidence unknown
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Dichromats One of the three cone types is missing
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Dichromats Only need two colours to match any other Sees a much reduced range of colours Types Protanope = lacks L cones 1% (male) Deuteranope = lacks M cones 1% (male) Tritanope = lacks S cones 0.002%
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Genes for the L & M cone pigments
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Monochromats No colour vision: any colour matched with any other Rod monochromat (0.003%) All cones are functionally absent Blue cone monochromat (atypical monochromat) Only S cones are present (0.001%) Difficult to differentiate the two types May use colour names effectively May perform OK on some standard colour tests
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Original Tritanope Deuteranope Protanope
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Original Tritanope Deuteranope Protanope
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Visual scene as it appears to (a) normal and (b-d) colour deficient observers
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L/M cone opponent mechanisms
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The luminance mechanism
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Contrast sensitivity of red/green and luminance gratings red/green luminance
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S/(L+M) cone opponent mechanisms
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