Physics:Tapetum lucidum

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Short description: Layer of eye tissue which aids in night vision
The dark blue, teal, and gold tapetum lucidum from the eye of a cow
Retina of a mongrel dog with strong tapetal reflex

The tapetum lucidum for 'bright tapestry, coverlet'; /təˈptəm ˈlsɪdəm/ tə-PEE-təm LOO-sih-dəm; pl.: tapeta lucida)[1] is a layer of tissue in the eye of many vertebrates and some other animals. Lying immediately behind the retina, it is a retroreflector. It reflects visible light back through the retina, increasing the light available to the photoreceptors (although slightly blurring the image). The tapetum lucidum contributes to the superior night vision of some animals. Many of these animals are nocturnal, especially carnivores, while others are deep sea animals.

Similar adaptations occur in some species of spiders.[2] Haplorhine primates, including humans, are diurnal and lack a tapetum lucidum.[Note 1]

Function and mechanism

Choroid dissected from a calf's eye, tapetum lucidum appearing iridescent blue

The presence of a tapetum lucidum enables animals to see in dimmer light than would otherwise be possible. The tapetum lucidum, which is iridescent, reflects light roughly on the interference principles of thin-film optics, as seen in other iridescent tissues. However, the tapetum lucidum cells are leucophores, not iridophores.[dubious ]

The tapetum functions as a retroreflector which reflects light directly back along the light path. This serves to match the original and reflected light, thus maintaining the sharpness and contrast of the image on the retina. The tapetum lucidum reflects with constructive interference,[4] thus increasing the quantity of light passing through the retina. In the cat, the tapetum lucidum increases the sensitivity of vision by 44%, allowing the cat to see light that is imperceptible to human eyes.[5]

It has been speculated that some flashlight fish may use eyeshine both to detect and to communicate with other flashlight fish.[6] American scientist Nathan H. Lents has proposed that the tapetum lucidum evolved in vertebrates, but not in cephalopods, which have a very similar eye, because of the backwards-facing nature of vertebrate photoreceptors. The tapetum boosts photosensitivity under conditions of low illumination, thus compensating for the suboptimal design of the vertebrate retina.[7]

Classification

A classification of anatomical variants of tapeta lucida[3] defines four types:

  1. Retinal tapetum, as seen in teleosts (with a variety of reflecting materials from lipids to phenols), crocodiles (with guanine), marsupials (with lipid spheres), and fruit bats (with phospholipids).[3]:16 The tapetum lucidum is within the retinal pigment epithelium; in the other three types the tapetum is within the choroid behind the retina. Two anatomical classes can be distinguished: occlusible and non-occlusible.
  2. Choroidal guainine tapetum, as seen in cartilaginous fish[9] The tapetum is a palisade of cells containing stacks of flat hexagonal crystals of guanine.[4]
  3. Choroidal tapetum cellulosum, as seen in carnivores, rodents and cetacea. The tapetum consists of layers of cells containing organized, highly refractive crystals. These crystals are diverse in shape and makeup: dogs and ferrets use zinc, cats use riboflavin and zinc, and lemurs use only riboflavin.[3]:17
  4. Choroidal tapetum fibrosum, as seen in cows, sheep, goats and horses. The tapetum is an array of extracellular fibers, most commonly collagen.[3]:17

The functional differences between these four structural classes of tapeta lucida are not known.[3]

This classification does not include tapeta lucida in birds. Kiwis, stone-curlews, the boat-billed heron, the flightless kākāpō and many nightjars, owls, and other night birds such as the swallow-tailed gull also possess a tapetum lucidum.[10] Nightjars use a retinal tapetum lucidum composed of lipids.[11]

Like humans, some animals lack a tapetum lucidum and they usually are diurnal.[3] These include haplorhine primates, squirrels, some birds, red kangaroo, and pigs.[12] Strepsirrhine primates are mostly nocturnal and, with the exception of several diurnal Eulemur species, have a tapetum lucidum of riboflavin crystals.[13]

When a tapetum lucidum is present, its location on the eyeball varies with the placement of the eyeball in the head,[14] such that in all cases the tapetum lucidum enhances night vision in the center of the animal's field of view.

Apart from its eyeshine, the tapetum lucidum itself has a color. It is often described as iridescent. In tigers it is greenish.[15] In ruminants it may be golden green with a blue periphery,[12] or whitish or pale blue with a lavender periphery. In dogs it may be whitish with a blue periphery.[12] The color in reindeer changes seasonally, allowing the animals to better avoid predators in low-light winter at the price of blurrier vision.[16]

Eyeshine

Reflection of camera flash from the tapetum lucidum

Eyeshine is a visible effect of the tapetum lucidum. When light shines into the eye of an animal having a tapetum lucidum, the pupil appears to glow. Eyeshine can be seen in many animals, in nature and in flash photographs. In low light, a hand-held flashlight is sufficient to produce eyeshine that is highly visible to humans (despite their inferior night vision). Eyeshine occurs in a wide variety of colors including white, blue, green, yellow, pink and red. However, since eyeshine is a type of iridescence, the color varies with the angle at which it is seen and the minerals which make up the reflective tapetum lucidum crystals.

White eyeshine occurs in many fish, especially walleye; blue eyeshine occurs in many mammals such as horses; green eyeshine occurs in mammals such as cats, dogs, and raccoons; and red eyeshine occurs in coyote, rodents, opossums and birds.[citation needed]

A three-month-old black Labrador puppy with apparent eyeshine

Although human eyes lack a tapetum lucidum, they still exhibit a weak reflection from the choroid, as can be seen in photography with the red-eye effect and with near-infrared eyeshine.[17][18] Another effect in humans and other animals that may resemble eyeshine is leukocoria, which is a white shine indicative of abnormalities such as cataracts and cancers.

In blue-eyed cats and dogs

Odd-eyed cat with eyeshine, plus red-eye effect in one eye
Red eyeshine from a siamese cat mix with blue eyes

Cats and dogs with a blue eye color may display both eyeshine and red-eye effect. Both species have a tapetum lucidum, so their pupils may display eyeshine. In flash color photographs, however, individuals with blue eyes may also display a distinctive red eyeshine. Individuals with heterochromia may display red eyeshine in the blue eye and normal yellow/green/blue/white eyeshine in the other eye. These include odd-eyed cats and bi-eyed dogs. The red-eye effect is independent of the eyeshine: in some photographs of individuals with a tapetum lucidum and heterochromia, the eyeshine is dim, yet the pupil of the blue eye still appears red. This is most apparent when the individual is not looking into the camera because the tapetum lucidum is far less extensive than the retina.

In spiders

Most species of spider also have a tapetum, which is located only in their smaller, lateral eyes; the larger central eyes have no such structure. This consists of reflective crystalline deposits, and is thought to have a similar function to the structure of the same name in vertebrates. Four general patterns can be distinguished in spiders:[19]

  1. Primitive type (e.g. Mesothelae, Orthognatha) – a simple sheet behind the retina
  2. Canoe-shape type (e.g. Araneidae, Theridiidae) – two lateral walls separated by a gap for the nerve fibres
  3. Grated type (e.g. Lycosidae, Pisauridae) – a relatively complex, grill-shaped structure
  4. No tapetum (e.g. Salticidae)

Uses by humans

In darkness, eyeshine reveals this raccoon

Humans use scanning for reflected eyeshine to detect and identify the species of animals in the dark, and deploying trained search dogs and search horses at night, as these animals benefit from improved night vision through this effect.[citation needed]

Using eyeshine to identify animals in the dark employs not only its color but also several other features. The color corresponds approximately to the type of tapetum lucidum, with some variation between species. Other features include the distance between pupils relative to their size; the height above ground; the manner of blinking (if any); and the movement of the eyeshine (bobbing, weaving, hopping, leaping, climbing, flying).[citation needed]

Artificial tapetum lucidum

Manufactured retroreflectors modeled after a tapetum lucidum are described in numerous patents and today have many uses. The earliest patent, first used in "Catseye" brand raised pavement markers, was inspired by the tapetum lucidum of a cat's eye. [citation needed]

Pathology

In dogs, certain drugs are known to disturb the precise organization of the crystals of the tapetum lucidum, thus compromising the dog's ability to see in low light. These drugs include ethambutol, macrolide antibiotics, dithizone, antimalarial medications, some receptor H2-antagonists, and cardiovascular agents. The disturbance "is attributed to the chelating action which removes zinc from the tapetal cells."[20]

Gallery

Traditionally it has been difficult to take retinal images of animals with a tapetum lucidum because ophthalmoscopy devices designed for humans rely on a high level of on-axis illumination.[21] This kind of illumination causes a great deal of reflex, or back-scatter, when it interacts with the tapetum. New devices with variable illumination can make this possible, however.

See also

Notes

  1. The one exception to this generalization is the neotropical night monkey genus Aotus; they are sometimes described as having a tapetum lucidum of collagen fibrils, but lack the reflective riboflavin crystals present in the eyes of nocturnal strepsirrhine primates.[3]

References

  1. "Latin Word Lookup". Archives.nd.edu. http://www.archives.nd.edu/cgi-bin/lookup.pl?stem=tapet&ending=um. 
  2. Ruppert, E. E.; Fox, R. S.; Barnes, R. D. (2004). "Chelicerata: Araneae". Invertebrate Zoology (7th ed.). Brooks/Cole. pp. 578–81. ISBN 978-0-03-025982-1. https://archive.org/details/isbn_9780030259821/page/571. 
  3. 3.0 3.1 3.2 3.3 3.4 3.5 3.6 "Comparative morphology of the tapetum lucidum (among selected species)". Veterinary Ophthalmology 7 (1): 11–22. 2004. doi:10.1111/j.1463-5224.2004.00318.x. PMID 14738502. 
  4. 4.0 4.1 Locket NA (July 1974). "The choroidal tapetum lucidum of Latimeria chalumnae". Proceedings of the Royal Society B 186 (84): 281–290. doi:10.1098/rspb.1974.0049. PMID 4153107. Bibcode1974RSPSB.186..281L. 
  5. "Spectral reflexion factor of the cat's tapetum". Nature 168 (4268): 293–4. August 1951. doi:10.1038/168293a0. PMID 14875072. Bibcode1951Natur.168..293G. 
  6. "Detection of eyeshine by flashlight fishes of the family Anomalopidae". Vision Res. 32 (4): 765–9. April 1992. doi:10.1016/0042-6989(92)90191-K. PMID 1413559. 
  7. Vee, Samantha; Barclay, Gerald; Lents, Nathan H. (2022). "The glow of the night: The tapetum lucidum as a co‐adaptation for the inverted retina.". BioEssays 44 (10): e2200003. doi:10.1002/bies.202200003. PMID 36028472. https://onlinelibrary.wiley.com/doi/abs/10.1002/bies.202200003. 
  8. "A novel vertebrate eye using both refractive and reflective optics". Curr. Biol. 19 (2): 108–114. January 2009. doi:10.1016/j.cub.2008.11.061. PMID 19110427. 
  9. Denton, EJ; Nichol, JAC (1964). "The chorioidal tapeta of some cartilaginous fishes (Chondrichthyes)". J. Mar. Biol. Assoc. U.K. 44 (1): 219–258. doi:10.1017/S0025315400024760. Bibcode1964JMBUK..44..219D. http://sabella.mba.ac.uk/2257/01/The_chorioidal_tapeta_of_some_cartilaginous_fishes_(Chondrichthyes).pdf. Retrieved 2011-09-12. 
  10. Gill, Frank, B (2007) "Ornithology", Freeman, New York
  11. Nicol, J. A.; Arnott, H. J. (5 November 1974). "Tapeta lucida in the eyes of goatsuckers (Caprimulgidae)". Proceedings of the Royal Society of London. Series B. Biological Sciences 187 (1088): 349–352. doi:10.1098/rspb.1974.0079. PMID 4154455. Bibcode1974RSPSB.187..349N. 
  12. 12.0 12.1 12.2 Orlando Charnock Bradley, 1896, Outlines of Veterinary Anatomy. Part I. The Anterior and Posterior Limbs, Baillière, Tindall & Cox, p. 224. Free full text on Google Books
  13. Ankel-Simons, Friderun (2007). Primate Anatomy (3rd ed.). Academic Press. p. 375. ISBN 978-0-12-372576-9. 
  14. Lee, Henry (1886). "On the Tapetum Lucidum". Med Chir Trans 69: 239–245. doi:10.1177/095952878606900113. PMID 20896672. 
  15. Fayrer, Sir Joseph (1889) The deadly wild beasts of India, pp. 218–240 in James Knowls (ed) The Nineteenth Century, Henry S. King & Co., v. 26; p. 219. via Google Books
  16. Karl-Arne Stokkan; Lars Folkow; Juliet Dukes; Magella Neveu; Chris Hogg; Sandra Siefken; Steven C. Dakin; Glen Jeffery (22 December 2013). "Shifting mirrors: adaptive changes in retinal reflections to winter darkness in Arctic reindeer". Proceedings of the Royal Society B 280 (1773). doi:10.1098/rspb.2013.2451. PMID 24174115. 
  17. Forrest M. Mims III (2013-10-03). "How to Make and Use Retroreflectors". Make. https://makezine.com/projects/make-35/how-to-make-and-use-retroreflectors/. Retrieved 2017-10-21. 
  18. van de Kraats, Jann; van Norren, Dirk (2008). "Directional and nondirectional spectral reflection from the human fovea". Journal of Biomedical Optics 13 (2): 024010. doi:10.1117/1.2899151. PMID 18465973. Bibcode2008JBO....13b4010V. 
  19. Rainer F. Foelix (1996). Biology of Spiders, 2nd ed.. Oxford University Press. pp. 84–85. ISBN 978-0-19-509594-4. https://archive.org/details/biologyofspiders00foel_0/page/84. 
  20. Cohen, Gerald D. (1986). Target organ toxicity. Boca Raton: CRC Press. pp. 121–122. ISBN 978-0-8493-5776-3. 
  21. Maggs, David; Miller, Paul; Ofri, Ron. Slatter's Fundamentals of Veterinary Ophthalmology. pp. 94. 

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