Dichromacy Explained

Dichromacy should not be confused with Heterochromia iridum.

Dichromacy
Field:Ophthalmology

Dichromacy (from Greek di, meaning "two" and chromo, meaning "color") is the state of having two types of functioning photoreceptors, called cone cells, in the eyes. Organisms with dichromacy are called dichromats. Dichromats require only two primary colors to be able to represent their visible gamut. By comparison, trichromats need three primary colors, and tetrachromats need four. Likewise, every color in a dichromat's gamut can be evoked with monochromatic light. By comparison, every color in a trichromat's gamut can be evoked with a combination of monochromatic light and white light.

Dichromacy in humans is a color vision deficiency in which one of the three cone cells is absent or not functioning and color is thereby reduced to two dimensions.[1]

Perception

Dichromatic color vision is enabled by two types of cone cells with different spectral sensitivities and the neural framework to compare the excitation of the different cone cells. The resulting color vision is simpler than typical human trichromatic color vision, and much simpler than tetrachromatic color vision, typical of birds and fish.

A dichromatic color space can be defined by only two primary colors. When these primary colors are also the unique hues, then the color space contains the individuals entire gamut. In dichromacy, the unique hues can be evoked by exciting only a single cone at a time, e.g. monochromatic light near the extremes of the visible spectrum. A dichromatic color space can also be defined by non-unique hues, but the color space will not contain the individual's entire gamut. For comparison, a trichromatic color space requires three primary colors to be defined. However, even when choosing three pure spectral colors as the primaries, the resulting color space will never encompass the entire trichromatic individual's gamut.

The color vision of dichromats can be represented in a 2-dimensional plane, where one coordinate represented brightness, and the other coordinate represents hue. However, the perception of hue is not directly analogous to trichromatic hue, but rather a spectrum diverging from white (neutral) in the middle to two unique hues at the extreme, e.g. blue and yellow. Unlike trichromats, white (experienced when both cone cells are equally excited) can be evoked by monochromatic light. This means that dichromats see white in the rainbow.

Humans

See main article: Color blindness. Dichromacy in humans is a form of color blindness (color vision deficiency). Normal human color vision is trichromatic, so dichromacy is achieved by losing functionality of one of the three cone cells. The classification of human dichromacy depends on which cone is missing:

Diagnosis

The three determining elements of a dichromatic opponent-color space are the missing color, the null-luminance plane, and the null-chrominance plane.[3] The description of the phenomena itself does not indicate the color that is impaired to the dichromat, however, it does provide enough information to identify the fundamental color space, the colors that are seen by the dichromat. This is based on testing both the null-chrominance plane and null-luminance plane which intersect on the missing color. The cones excited to a corresponding color in the color space are visible to the dichromat and those that are not excited are the missing colors.[4]

Color detecting abilities of dichromats

According to color vision researchers at the Medical College of Wisconsin (including Jay Neitz), each of the three standard color-detecting cones in the retina of trichromats – blue, green and red – can pick up about 100 different gradations of color. If each detector is independent of the others, the total number of colors discernible by an average human is their product (100 × 100 × 100), i.e. about 1 million;[5] Nevertheless, other researchers have put the number at upwards of 2.3 million. The same calculation suggests that a dichromat (such as a human with red-green color blindness) would be able to distinguish about 100 × 100 = 10,000 different colors,[6] but no such calculation has been verified by psychophysical testing.

Furthermore, dichromats have a significantly higher threshold than trichromats for colored stimuli flickering at low (1 Hz) frequencies. At higher (10 or 16 Hz) frequencies, dichromats perform as well as or better than trichromats.[7] [8] This means such animals would still observe the flicker instead of a temporally fused visual perception as is the case in human movie watching at a high enough frame rate.

Mammals

Until the 1960s, popular belief held that most mammals outside of primates were monochromats. In the last half-century, however, a focus on behavioral and genetic testing of mammals has accumulated extensive evidence of dichromatic color vision in a number of mammalian orders. Mammals are now usually assumed to be dichromats (possessing S- and L-cones), with monochromats viewed as the exceptions.

The common vertebrate ancestor, extant during the Cambrian, was tetrachromatic, possessing 4 distinct opsins classes.[9] Early mammalian evolution would see the loss of two of these four opsins, due to the nocturnal bottleneck, as dichromacy may improve an animal's ability to distinguish colors in dim light.[10] Placental mammals are therefore – as a rule – dichromatic.[11]

The exceptions to this rule of dichromatic vision in placental mammals are old world monkeys and apes, which re-evolved trichromacy, and marine mammals (both pinnipeds and cetaceans) which are cone monochromats.[12] New World Monkeys are a partial exception: in most species, males are dichromats, and about 60% of females are trichromats, but the owl monkeys are cone monochromats,[13] and both sexes of howler monkeys are trichromats.[14] [15] [16]

Trichromacy has been retained or re-evolved in marsupials, where trichromatic vision is widespread.[17] Recent genetic and behavioral evidence suggests the South American marsupial Didelphis albiventris is dichromatic, with only two classes of cone opsins having been found within the genus Didelphis.[18]

See also

Sources

External links

Notes and References

  1. Web site: Guidelines: Colour Blindness. . deviated . https://web.archive.org/web/20030503105719if_/http://www.tiresias.org:80/guidelines/colour_blindness.htm . 3 May 2003 . 29 September 2006 .
  2. Hanggi. Evelyn B.. Ingersoll. Jerry F.. Waggoner. Terrace L.. Color vision in horses (Equus caballus): Deficiencies identified using a pseudoisochromatic plate test.. Journal of Comparative Psychology. 121. 1. 2007. 65–72. 1939-2087. 10.1037/0735-7036.121.1.65. 17324076.
  3. Scheibner . H. . Cleveland . S. . 1998 . Dichromacy characterized by chrominance planes . Vision Research . 38 . 21. 3403–3407 . 10.1016/s0042-6989(97)00373-8. 9893856 .
  4. Scheibner . H. . Cleveland . S. . 1997 . Dichromacy characterized by chrominance planes . Vision Research . 38 . 1. 3403–3407 . 10.1016/s0042-6989(97)00373-8. 9893856 .
  5. Web site: Some women who are tetrachromats may see 100,000,000 colors, thanks to their genes . Mark Roth . Pittsburgh Post-Gazette . 13 September 2006 .
  6. "Color Vision: Almost Reason for Having Eyes" by Jay Neitz, Joseph Carroll, and Maureen Neitz Optics & Photonics News January 2001 1047-6938/01/01/0026/8- Optical Society of America
  7. Sharpe Lindsay . T. . de Luca . Emanuela . Thorsten . Hansen . Gegenfurtner Karl . R. . 2006. Advantages and disadvantages of human dichromacy . Journal of Vision . 6. 3. 213–23 . 10.1167/6.3.3 . 16643091 . free .
  8. Bayer Florian . S. . Vivian Paulun . C. . David . Weiss . Gegenfurtner Karl . R. . 2015. A tetrachromatic display for the spatiotemporal control of rod and cone stimulation . Journal of Vision . 15. 11. 15. 10.1167/15.11.15 . 26305863 . free .
  9. Jacobs . G. H. . 2009 . Evolution of colour vision in mammals . . 364 . 2957–67 . 10.1098/rstb.2009.0039 . 2781854 . 19720656 . 1531.
  10. Vorobyev . M. . 2006 . Evolution of colour vision: The story of lost visual pigments . Perception . 35 . ECVP Abstract Supplement . 1 February 2013 . https://web.archive.org/web/20141006111136/http://www.perceptionweb.com/abstract.cgi?id=v060037 . 6 October 2014 . dead .
  11. Bowmaker. JK. Evolution of colour vision in vertebrates. Eye. 1998. 12 (Pt 3b). 3. 541–7. 9775215. 10.1038/eye.1998.143. free.
  12. Vorobyev. M. Ecology and evolution of primate colour vision. Clinical & Experimental Optometry. Jul 2004. 87. 4–5. 230–8. 15312027. 7 January 2013. 10.1111/j.1444-0938.2004.tb05053.x. free.
  13. Jacobs . G. H. . Deegan . J. F. . Neitz . Neitz . J. . Crognale . M. A. . 1993 . Photopigments and colour vision in the nocturnal monkey, Aotus . Vision Research . 33 . 13. 1773–1783 . 10.1016/0042-6989(93)90168-V . 8266633. 3745725 .
  14. Jacobs . G. H. . Deegan . J. F. . 2001 . Photopigments and colour vision in New World monkeys from the family Atelidae . Proceedings of the Royal Society B . 268 . 1468. 695–702 . 10.1098/rspb.2000.1421. 11321057 . 1088658.
  15. Mollon . J. D. . Bowmaker . J. K. . Jacobs . G. H. . 1984 . Variations of colour vision in a New World primate can be explained by polymorphism of retinal photopigments . Proceedings of the Royal Society B . 222 . 1228. 373–399 . 10.1098/rspb.1984.0071 . 6149558 . 1984RSPSB.222..373M. 24416536 .
  16. Sternberg, Robert J. (2006) Cognitive Psychology. 4th Ed. Thomson Wadsworth.
  17. Arrese . C. A. . Oddy . A. Y. . Runham . P. B. . Hart . N. S. . Shand . J. . Hunt . D. M. . Beazley . L. D. . 2005 . Cone topography and spectral sensitivity in two potentially trichromatic marsupials, the quokka (Setonix brachyurus) and quenda (Isoodon obesulus) . Proceedings of the Royal Society B . 272 . 1565. 791–796 . 10.1098/rspb.2004.3009 . 15888411 . 1599861.
  18. Gutierrez . E.A. . Pegoraro . B.M. . Magalhães-Castro . B. . Pessoa . V.F. . 2011 . Behavioural evidence of dichromacy in a species of South American marsupial . Animal Behaviour . 81 . 5. 1049–1054 . 10.1016/j.anbehav.2011.02.012. 53176187 .