An electrophysiological study of chromatic processing in the human visual system : using visual evoked potentials and electroretinograms to study cortical and retinal contributions to human trichromatic vision

Challa, Naveen Kumar

January 2011

The work in this thesis is concerned with examining the retinal and cortical contributions to human trichromatic colour vision. Chromatic processing at the cortex level was examined using visual evoked potentials (VEPs). These responses were elicited by chromatic spot stimuli, which were manipulated in order to selectively activate the chromatic processing system. Chromatic processing at the retinal level was examined using the electroretinograms (ERGs) for which cone isolating stimuli were used to assess the nature of L and M cone inputs to cone-opponent mechanisms. The results from the VEP experiments suggest VEP morphology is dependent upon 1) chromatic and or luminance contrast content of the stimulus, 2) stimulus size, and 3) extent to which the chromatic stimulus activates either the L/M or S/(L+M) opponent mechanism. The experiments indicate that chromatic stimulation is indexed by large N1 component and small offset responses. Optimal stimulus size for chromatic isolation is 2-4 ° along L/M axes and 6° along S/(L+M) axis. From the ERG experiments, It has been shown that the low (12Hz) and high (30Hz) temporal frequency flickering stimuli can isolate the chromatic and luminance processing mechanisms in the retina. For low temporal frequency ERGs, the L:M ratio was close to unity and L/M phase difference was close to 180°. For high temporal frequency ERGs, the L:M ratio was more than unity and L/M phase difference was close to 90°. In addition to this, the variation in L:M ratio across the retinal eccentricity was also examined. These results suggest, for the chromatic processing, L:M ratio is close to unity independent of retinal eccentricity and individuals. For the luminance processing, L:M ratio is more than unity and depends upon the region of the retina being stimulated. These findings indicate the maintenance of cone selective input for the chromatic processing across the human retina.

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Spontánní barvová preference u lidí a non-humánních primátů: Srovnávací studie / Spontaneous preference for colors in humans and non-human primates: Comparative study

Skalníková, Petra

January 2017

Colors and color-perception may play an important role in animal ethology (foraging, intra or inter-species communication). However, trichromatic color vision is quite rare among mammals and occurs only in some primate species. Humans, apes, and most of the Old World primates are trichromats, whereas color vision among New World primate species varies strikingly. The pigment gene perciving longer wavelenghts (red) have appeared most recently. Moreover, the pigment genes for the perception of red color have appear independently in these two primates lines (Old and New World) (Kainz et al, 1998). Although the genetic mechanism of trichromacy is quite understood, the question remains, what was the adaptive advantage responsible for the spreading of the above mentioned genes. The basic functions of trichromatic vision may be better detection of food (folivory and frugivory hypothesis), signaling or warning functions. The main goals of the thesis is to study spontaneous preference for color in children (pre- school and school age) and non-human Old World primates who have routine trichromic vision. Moreover, the thesis will focus on preference of red color to understand what was an adaptive function of red color perception. We assume that the spontaneous preference for color may reflect an adaptive...

An electrophysiological study of chromatic processing in the human visual system. Using visual evoked potentials and electroretinograms to study cortical and retinal contributions to human trichromatic vision.

Challa, Naveen K.

January 2011

The work in this thesis is concerned with examining the retinal and cortical contributions to human trichromatic colour vision. Chromatic processing at the cortex level was examined using visual evoked potentials (VEPs). These responses were elicited by chromatic spot stimuli, which were manipulated in order to selectively activate the chromatic processing system. Chromatic processing at the retinal level was examined using the electroretinograms (ERGs) for which cone isolating stimuli were used to assess the nature of L and M cone inputs to cone-opponent mechanisms. The results from the VEP experiments suggest VEP morphology is dependent upon 1) chromatic and or luminance contrast content of the stimulus, 2) stimulus size, and 3) extent to which the chromatic stimulus activates either the L/M or S/(L+M) opponent mechanism. The experiments indicate that chromatic stimulation is indexed by large N1 component and small offset responses. Optimal stimulus size for chromatic isolation is 2-4 ° along L/M axes and 6° along S/(L+M) axis. From the ERG experiments, It has been shown that the low (12Hz) and high (30Hz) temporal frequency flickering stimuli can isolate the chromatic and luminance processing mechanisms in the retina. For low temporal frequency ERGs, the L:M ratio was close to unity and L/M phase difference was close to 180°. For high temporal frequency ERGs, the L:M ratio was more than unity and L/M phase difference was close to 90°. In addition to this, the variation in L:M ratio across the retinal eccentricity was also examined. These results suggest, for the chromatic processing, L:M ratio is close to unity independent of retinal eccentricity and individuals. For the luminance processing, L:M ratio is more than unity and depends upon the region of the retina being stimulated. These findings indicate the maintenance of cone selective input for the chromatic processing across the human retina.

Colour vision

; Electrophysiology

; Visual evoked potentials

; Electroretinograms

; Human trichromatic colour vision

; Chromatic processing