All Relations between color perception and retina cone cell

Publication Sentence Publish Date Extraction Date Species
M J Sankeralli, K T Mulle. Bipolar or rectified chromatic detection mechanisms? Visual neuroscience. vol 18. issue 1. 2001-09-13. PMID:11347810. it is widely accepted that human color vision is based on two types of cone-opponent mechanism, one differencing l and m cone types (loosely termed "red-green"), and the other differencing s with the l and m cones (loosely termed "blue-yellow"). 2001-09-13 2023-08-12 human
L Peichl, G Behrmann, R H Kröge. For whales and seals the ocean is not blue: a visual pigment loss in marine mammals. The European journal of neuroscience. vol 13. issue 8. 2001-07-12. PMID:11328346. most terrestrial mammals have colour vision based on two spectrally different visual pigments located in two types of retinal cone photoreceptors, i.e. 2001-07-12 2023-08-12 Not clear
H J Wagner, R H Kröge. Effects of long-term spectral deprivation on the morphological organization of the outer retina of the blue acara (Aequidens pulcher). Philosophical transactions of the Royal Society of London. Series B, Biological sciences. vol 355. issue 1401. 2001-04-05. PMID:11079408. to investigate the developmental plasticity of colour vision, we reared fish with a trichromatic cone system (aequidens pulcher) under three near-monochromatic lights, differentially stimulating each spectral cone type from the larval stage to the age of at least one year. 2001-04-05 2023-08-12 Not clear
K A Fritsches, J C Partridge, J D Pettigrew, N J Marshal. Colour vision in billfish. Philosophical transactions of the Royal Society of London. Series B, Biological sciences. vol 355. issue 1401. 2001-04-05. PMID:11079409. the cells are arranged in a regular mosaic pattern of single and twin cones as in many fishes, and this arrangement suggests that the different cone types also show different spectral sensitivity, which is the basis for colour vision. 2001-04-05 2023-08-12 Not clear
A M Shamshinova, A S Petrov, A P Dvorianchikova, Iu A Aref'eva, E N Eskina, T N Kiseleva, I V Zol'nikov. [Computer method for evaluating disorders in sense of color]. Vestnik oftalmologii. vol 116. issue 5. 2001-03-22. PMID:11221383. the new method can be used in the diagnosis of the initial pathological processes of different origin, involving the cone system at any level of visual route and associated with acquired disorders in color vision. 2001-03-22 2023-08-12 human
P Lenni. Color vision: putting it together. Current biology : CB. vol 10. issue 16. 2001-02-08. PMID:10985374. color vision depends on the visual system comparing signals that originate in different classes of cone photoreceptors. 2001-02-08 2023-08-12 Not clear
L Ng, J B Hurley, B Dierks, M Srinivas, C Saltó, B Vennström, T A Reh, D Forres. A thyroid hormone receptor that is required for the development of green cone photoreceptors. Nature genetics. vol 27. issue 1. 2001-02-01. PMID:11138006. color vision is facilitated by distinct populations of cone photoreceptors in the retina. 2001-02-01 2023-08-12 mouse
D M Dace. Parallel pathways for spectral coding in primate retina. Annual review of neuroscience. vol 23. 2000-09-08. PMID:10845080. trichromatic color vision begins when the image is sampled by short- (s), middle- (m) and long- (l) wavelength-sensitive cone photoreceptors. 2000-09-08 2023-08-12 human
O H Sundin, J M Yang, Y Li, D Zhu, J N Hurd, T N Mitchell, E D Silva, I H Maumene. Genetic basis of total colourblindness among the Pingelapese islanders. Nature genetics. vol 25. issue 3. 2000-08-11. PMID:10888875. in this disease, cone photoreceptors, the retinal sensory neurons mediating colour vision, seem viable but fail to generate an electrical response to light. 2000-08-11 2023-08-12 Not clear
D J Calkin. Representation of cone signals in the primate retina. Journal of the Optical Society of America. A, Optics, image science, and vision. vol 17. issue 3. 2000-03-23. PMID:10708041. for color vision, the photon catch between different cone types is compared for discrimination of fine spectral differences on the basis of hue. 2000-03-23 2023-08-12 Not clear
G H Jacobs, J F Deega. Uniformity of colour vision in Old World monkeys. Proceedings. Biological sciences. vol 266. issue 1432. 2000-03-06. PMID:10584339. cone pigments maximally sensitive to short wavelengths were also detected, implying the presence of trichromatic colour vision. 2000-03-06 2023-08-12 monkey
G H Jacobs, J F Deega. Uniformity of colour vision in Old World monkeys. Proceedings. Biological sciences. vol 266. issue 1432. 2000-03-06. PMID:10584339. direct comparisons of the spectral sensitivity functions of old world monkeys suggest there are no significant variations in the spectral positions of the cone pigments underlying the trichromatic colour vision of old world monkeys. 2000-03-06 2023-08-12 monkey
H Terasaki, Y Miyake, R Nomura, M Horiguchi, S Suzuki, M Kond. Blue-on-yellow perimetry in the complete type of congenital stationary night blindness. Investigative ophthalmology & visual science. vol 40. issue 11. 1999-10-07. PMID:10509678. to resolve the discrepancy between nonrecordable full-field short wavelength cone electroretinograms (s-cone ergs) and the presence of normal color vision in patients with the complete type of congenital stationary night blindness (csnb1). 1999-10-07 2023-08-12 Not clear
P R Martin, U Grüner. Analysis of the short wavelength-sensitive ("blue") cone mosaic in the primate retina: comparison of New World and Old World monkeys. The Journal of comparative neurology. vol 406. issue 1. 1999-05-11. PMID:10100889. the distribution of short wavelength-sensitive (sws or "blue") cone photoreceptors was compared in primates with dichromatic ("red-green colour blind") and trichromatic colour vision. 1999-05-11 2023-08-12 human
P R Marti. Colour processing in the primate retina: recent progress. The Journal of physiology. vol 513 ( Pt 3). 1999-03-03. PMID:9824705. colour vision in the majority of humans is trichromatic, relying on a comparison of the quantal absorption in three different types of cone photoreceptors. 1999-03-03 2023-08-12 Not clear
P M Kainz, M Neitz, J Neit. Molecular genetic detection of female carriers of protan defects. Vision research. vol 38. issue 21. 1999-02-16. PMID:9893850. females heterozygous for congenital colour vision defects are of interest because they are believed to have cone photoreceptor ratios and cone photopigments that differ from normal. 1999-02-16 2023-08-12 Not clear
T W Kraft, J Neitz, M Neit. Spectra of human L cones. Vision research. vol 38. issue 23. 1999-02-08. PMID:9893797. variations in the amino acid sequences of the human cone opsins give rise to spectrally variant subtypes of l and m cone pigments even in the population with normal color vision. 1999-02-08 2023-08-12 human
J K Bowmake. Evolution of colour vision in vertebrates. Eye (London, England). vol 12 ( Pt 3b). 1998-10-29. PMID:9775215. the complement of four spectrally distinct cone classes endows these species with the potential for tetrachromatic colour vision. 1998-10-29 2023-08-12 Not clear
J K Bowmake. Evolution of colour vision in vertebrates. Eye (London, England). vol 12 ( Pt 3b). 1998-10-29. PMID:9775215. in contrast, probably because of their nocturnal ancestry, mammals have rod-dominated retinas with colour vision reduced to a basic dichromatic system subserved by only two spectral classes of cone. 1998-10-29 2023-08-12 Not clear
M P Simunovic, A T Moor. The cone dystrophies. Eye (London, England). vol 12 ( Pt 3b). 1998-10-29. PMID:9775217. the major clinical features of cone dystrophy are photophobia, reduced visual acuity and abnormal colour vision. 1998-10-29 2023-08-12 Not clear