Claw

Last updated August 11, 2024

A claw is a curved, pointed appendage found at the end of a toe or finger in most amniotes (mammals, reptiles, birds). Some invertebrates such as beetles and spiders have somewhat similar fine, hooked structures at the end of the leg or tarsus for gripping a surface as they walk. The pincers of crabs, lobsters and scorpions, more formally known as their chelae, are sometimes called claws.

Tetrapods

In tetrapods, claws are made of keratin and consist of two layers. The unguis is the harder external layer, which consists of keratin fibers arranged perpendicular to the direction of growth and in layers at an oblique angle. The subunguis is the softer, flaky underside layer whose grain is parallel to the direction of growth. The claw grows outward from the nail matrix at the base of the unguis and the subunguis grows thicker while travelling across the nail bed. The unguis grows outward faster than the subunguis to produce a curve and the thinner sides of the claw wear away faster than their thicker middle, producing a more or less sharp point. Tetrapods use their claws in many ways, commonly to grasp or kill prey, to dig and to climb and hang.

Mammals

A claw sheath from a cat Katzenkralle.jpg — A claw sheath from a cat

All carnivorans have claws, which vary considerably in length and shape. Claws grow out of the third phalanges of the paws and are made of keratin. Many predatory mammals have protractile claws that can partially hide inside the animal's paw, especially the cat family, Felidae, almost all of whose members have fully protractible claws. Outside of the cat family, retractable claws are found only in certain species of the Viverridae (and the extinct Nimravidae).^[2] A claw that is retractable is protected from wear and tear.

Most cats and dogs also have a dewclaw on the inside of the front paws. It is much less functional than the other claws but does help the cats to grasp prey. Because the dew claw does not touch the ground, it receives less wear and tends to be sharper and longer.

A nail is homologous to a claw but is flatter and has a curved edge instead of a point. A nail that is big enough to bear weight is called a "hoof". (Nevertheless, one side of the cloven-hoof of artiodactyl ungulates may also be called a claw).

Every so often, the growth of claws stops and restarts, as does hair. In a hair, this results in the hair falling out and being replaced by a new one. In claws, this results in an abscission layer, and the old segment breaks off. This process takes several months for human thumbnails. Cats are often seen working old unguis layers off on wood or on boards made for the purpose. Ungulates' hooves wear or self-trim by ground contact. Domesticated equids (horses, donkeys and mules) usually need regular trimming by a farrier, as a consequence of reduced activity on hard ground.

Primates

Primate nails consist of the unguis alone, as the subunguis has disappeared. With the evolution of grasping hands and feet, claws are no longer necessary for locomotion, and instead most digits exhibit nails. However, claw-like nails are found in small-bodied callitrichids on all digits except the hallux or big toe. A laterally flattened grooming claw, used for grooming, can be found on the second toe in living strepsirrhines, and the second and third in tarsiers. Aye-ayes have functional claws on all other digits except the hallux, including a grooming claw on the second toe.^[3] Less commonly known, a grooming claw is also found on the second pedal digit of night monkeys (Aotus), titis (Callicebus), and possibly other New World monkeys.^[4]

Reptiles

Most reptiles have well-developed claws. Most lizards have toes ending in stout claws.^[5] In snakes, feet and claws are absent, but in many boids such as Boa constrictor , remnants of highly reduced hind-limbs emerge with a single claw as "spurs" on each side of the anal opening.

Lizard claws are used as aids in climbing, and in holding down prey in carnivorous species.

Birds

A talon is the claw of a bird of prey, its primary hunting tool.^[6] The talons are very important; without them, most birds of prey would not be able to catch their food. Some birds also use claws for defensive purposes. Cassowaries use claws on their inner toe (digit I) for defence and have been known to disembowel people.^[7]^[8] All birds, however, have claws, which are used as general holdfasts and protection for the tip of the digits.

The hoatzin and turaco are unique among extant birds in having functional claws on the thumb and index finger (digits I and II) on the forelimbs as chicks, allowing them to climb trees until the adult plumage with flight feathers develop.^[9]^[10] However, several birds have a claw- or nail-like structure hidden under the feathers at the end of the hand digits, notably ostriches, emus, ducks, geese and kiwis.^[11]

Amphibians

The only amphibians to bear claws are the African clawed frogs. Claws evolved separately in the amphibian and amniote (reptiliomorph) line.^[12] However, the hairy frog has claw analogues on its feet; the frog intentionally dislocates the tips of its fingers to unsheathe the sharp points of its last phalanges.

Arthropods

The scientifically correct term for the "claw" of an arthropod, such as a lobster or crab, is a chela (plural chelae). Legs bearing a chela are called chelipeds . Chelae are also called pincers .

Related Research Articles

The foot is an anatomical structure found in many vertebrates. It is the terminal portion of a limb which bears weight and allows locomotion. In many animals with feet, the foot is a separate organ at the terminal part of the leg made up of one or more segments or bones, generally including claws and/or nails.

A finger is a prominent digit on the forelimbs of most tetrapod vertebrate animals, especially those with prehensile extremities such as humans and other primates. Most tetrapods have five digits (pentadactyly), and short digits are typically referred to as toes, while those that are notably elongated are called fingers. In humans, the fingers are flexibly articulated and opposable, serving as an important organ of tactile sensation and fine movements, which are crucial to the dexterity of the hands and the ability to grasp and manipulate objects.

<span class="mw-page-title-main">Thumb</span> First digit of the hand

The thumb is the first digit of the hand, next to the index finger. When a person is standing in the medical anatomical position, the thumb is the outermost digit. The Medical Latin English noun for thumb is pollex, and the corresponding adjective for thumb is pollical.

<span class="mw-page-title-main">Toe</span> Digit of a foot

Toes are the digits of the foot of a tetrapod. Animal species such as cats that walk on their toes are described as being digitigrade. Humans, and other animals that walk on the soles of their feet, are described as being plantigrade; unguligrade animals are those that walk on hooves at the tips of their toes.

In biology, dactyly is the arrangement of digits on the hands, feet, or sometimes wings of a tetrapod animal. The term is derived from the Greek word δακτυλος meaning "finger."

<span class="mw-page-title-main">Nail (anatomy)</span> Hard keratin protection of digit

A nail is a protective plate characteristically found at the tip of the digits of all primates, corresponding to the claws in other tetrapod animals. Fingernails and toenails are made of a tough rigid protein called alpha-keratin, a polymer also found in the claws, hooves and horns of vertebrates.

The hoof is the tip of a toe of an ungulate mammal, which is covered and strengthened with a thick and horny keratin covering. Artiodactyls are even-toed ungulates, species whose feet have an even number of digits; the ruminants with two digits are the most numerous, e.g. giraffe, deer, bison, cattle, goat, pigs, and sheep. The feet of perissodactyl mammals have an odd number of toes, e.g. the horse, the rhinoceros, and the tapir. Although hooves are limb structures primarily found in placental mammals, hadrosaurs such as Edmontosaurus possessed hoofed forelimbs. The marsupial Chaeropus also had hooves.

Prosimians are a group of primates that includes all living and extinct strepsirrhines, as well as the haplorhine tarsiers and their extinct relatives, the omomyiforms, i.e. all primates excluding the simians. They are considered to have characteristics that are more "primitive" than those of simians.

<span class="mw-page-title-main">Upper limb</span> Consists of the arm, forearm, and hand

The upper limbs or upper extremities are the forelimbs of an upright-postured tetrapod vertebrate, extending from the scapulae and clavicles down to and including the digits, including all the musculatures and ligaments involved with the shoulder, elbow, wrist and knuckle joints. In humans, each upper limb is divided into the arm, forearm and hand, and is primarily used for climbing, lifting and manipulating objects.

A dewclaw is a digit – vestigial in some animals – on the foot of many mammals, birds, and reptiles. It commonly grows higher on the leg than the rest of the foot, such that in digitigrade or unguligrade species, it does not make contact with the ground when the animal is standing. The name refers to the dewclaw's alleged tendency to brush dew away from grass. On dogs and cats, the dewclaws are on the inside of the front legs, similarly to a human's thumb, which shares evolutionary homology. Although many animals have dewclaws, other similar species do not, such as horses, giraffes and the African wild dog.

The phalanges are digital bones in the hands and feet of most vertebrates. In primates, the thumbs and big toes have two phalanges while the other digits have three phalanges. The phalanges are classed as long bones.

A forelimb or front limb is one of the paired articulated appendages (limbs) attached on the cranial (anterior) end of a terrestrial tetrapod vertebrate's torso. With reference to quadrupeds, the term foreleg or front leg is often used instead. In bipedal animals with an upright posture, the term upper limb is often used.

Notharctus tenebrosus was an early primate from the early Eocene, some 54–38 million years ago. Its fossil was found by Ferdinand V. Hayden in 1870 in southwestern Wyoming. When first found, Notharctus tenebrosus was thought to be a small pachyderm due to the concentration of pachyderm fossils in the area. However, after Walter W. Granger's discovery of a nearly complete skeleton, also in Wyoming, it was firmly established as a primate. Notharctus tenebrosus most resembles modern-day lemurs, although they are not directly related.

The pes is the zoological term for the distal portion of the hind limb of tetrapod animals. It is the part of the pentadactyl limb that includes the metatarsals and digits (phalanges). During evolution, it has taken many forms and served a variety of functions. It can be represented by the foot of primates, the lower hind limb of hoofed animals, the lower portion of the leg of dinosaurs including birds or the rear paw. It is also represented in the rear 'paddle' of extinct marine reptiles, such as plesiosaurs. The oldest types of tetrapods had seven or eight digits.

An ungual is a highly modified distal toe bone which ends in a hoof, claw, or nail. Elephants and ungulates have ungual phalanges, as did the sauropods and horned dinosaurs. A claw is a highly modified ungual phalanx.

Paraves are a widespread group of theropod dinosaurs that originated in the Middle Jurassic period. In addition to the extinct dromaeosaurids, troodontids, anchiornithids, and possibly the scansoriopterygids, the group also contains the avialans, which include diverse extinct taxa as well as the over 10,000 species of living birds. Basal members of Paraves are well known for the possession of an enlarged claw on the second digit of the foot, which was held off the ground when walking in some species. A number of differing scientific interpretations of the relationships between paravian taxa exist. New fossil discoveries and analyses make the classification of Paraves an active subject of research.

A limb is a jointed, muscled appendage of a tetrapod vertebrate animal used for weight-bearing, terrestrial locomotion and physical interaction with other objects. The distalmost portion of a limb is known as its extremity. The limbs' bony endoskeleton, known as the appendicular skeleton, is homologous among all tetrapods, who use their limbs for walking, running and jumping, swimming, climbing, grasping, touching and striking.

<span class="mw-page-title-main">Digit (anatomy)</span> One of several most distal parts of a limb, such as fingers or toes

A digit is one of several most distal parts of a limb, such as fingers or toes, present in many vertebrates.

A grooming claw is the specialized claw or nail on the foot of certain primates, used for personal grooming. All prosimians have a grooming claw, but the digit that is specialized in this manner varies. Tarsiers have a grooming claw on second and third toes. In the suborder Strepsirrhini, which includes lemurs, galagos and lorises, the grooming claw is on the second toe. Less commonly known, a grooming claw is also found on the second pedal digit of night monkeys (Aotus), titis (Callicebus), and possibly other New World monkeys.

A hand is a prehensile, multi-fingered appendage located at the end of the forearm or forelimb of primates such as humans, chimpanzees, monkeys, and lemurs. A few other vertebrates such as the koala are often described as having "hands" instead of paws on their front limbs. The raccoon is usually described as having "hands" though opposable thumbs are lacking.

References

↑ Rand, A.L. (1954). "On the Spurs on Birds' Wings" (PDF). The Wilson Bulletin. 66 (2): 127–134. Retrieved 16 November 2012.
↑ Turner, Alan; Antón, Mauricio (1997). The Big Cats and their fossil relatives: an illustrated guide to their evolution and natural history. New York City: Columbia University Press. pp. 130–133. ISBN 978-0-231-10228-5.
↑ Soligo, C.; Müller, A. E. (1999). "Nails and claws in primate evolution". Journal of Human Evolution. 36 (1): 97–114. doi:10.1006/jhev.1998.0263. PMID 9924135.
↑ Maiolino, S.; Boyer, D. M.; Rosenberger, A. (2011). "Morphological Correlates of the Grooming Claw in Distal Phalanges of Platyrrhines and Other Primates: A Preliminary Study". The Anatomical Record. 294 (12): 1975–1990. doi:10.1002/ar.21498. PMID 22042603.
↑ Alibardi, L. (2008). "Microscopic analysis of lizard claw morphogenesis and hypothesis on its evolution". Acta Zoologica . 89 (2): 169–178. doi:10.1111/j.1463-6395.2007.00312.x.
↑ Fowler, Denver W.; Freedman, Elizabeth A.; Scannella, John B. (2009-11-25). Pizzari, Tom (ed.). "Predatory Functional Morphology in Raptors: Interdigital Variation in Talon Size Is Related to Prey Restraint and Immobilisation Technique". PLoS ONE. 4 (11): e7999. Bibcode:2009PLoSO...4.7999F. doi: 10.1371/journal.pone.0007999 . ISSN 1932-6203. PMC 2776979 . PMID 19946365.
↑ Lumeij, J. T. (1987). "Avian clinical pathology. General considerations". Veterinary Quarterly. 9 (3): 249–254. doi: 10.1080/01652176.1987.9694109 . PMID 3314103.
↑ Cho, Patricia; Brown, Rosanne; Anderson, Marilyn (1984-01-01). "Comparative gross anatomy of ratites". Zoo Biology. 3 (2): 133–144. doi:10.1002/zoo.1430030205. ISSN 1098-2361.
↑ Fain, Matthew G.; Houde, Peter (2004). "Parallel radiations in the primary clades of birds" (PDF). Evolution . 58 (11): 2558–2573. doi:10.1554/04-235. PMID 15612298. S2CID 1296408. Archived from the original (PDF) on 2017-07-09. Retrieved 2016-07-08.
↑ Parker, W. K. (1891). "On the Morphology of a Reptilian Bird, Opisthocomus hoazin". Transactions of the Zoological Society of London. 13 (2): 43–89. doi:10.1111/j.1096-3642.1891.tb00045.x.
↑ Sir Buller, Walter Lawry (1888). "Apteryx australis (South-Island Kiwi)". A History of the Birds of New Zealand. London: Sir Walter Lawry Buller. Archived from the original on 2021-10-20 – via New Zealand Electronic Text Collection.
↑ Maddin, HC; Eckhart, L; Jaeger, K; Russell, AP; Ghannadan, M (2009). "The anatomy and development of the claws of Xenopus laevis (Lissamphibia: Anura) reveal alternate pathways of structural evolution in the integument of tetrapods". Journal of Anatomy. 214 (4): 607–19. doi:10.1111/j.1469-7580.2009.01052.x. PMC 2736125 . PMID 19422431.

External links

Rat Claws (archived from the original on 16 April 2022), also explains much about mammalian claws in general.

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[1] Rand, A.L. (1954). "On the Spurs on Birds' Wings" (PDF). The Wilson Bulletin. 66 (2): 127–134. Retrieved 16 November 2012.

[2] Turner, Alan; Antón, Mauricio (1997). The Big Cats and their fossil relatives: an illustrated guide to their evolution and natural history. New York City: Columbia University Press. pp. 130–133. ISBN 978-0-231-10228-5.

[Soligo-3] Soligo, C.; Müller, A. E. (1999). "Nails and claws in primate evolution". Journal of Human Evolution. 36 (1): 97–114. doi:10.1006/jhev.1998.0263. PMID 9924135.

[Maiolino-4] Maiolino, S.; Boyer, D. M.; Rosenberger, A. (2011). "Morphological Correlates of the Grooming Claw in Distal Phalanges of Platyrrhines and Other Primates: A Preliminary Study". The Anatomical Record. 294 (12): 1975–1990. doi:10.1002/ar.21498. PMID 22042603.

[5] Alibardi, L. (2008). "Microscopic analysis of lizard claw morphogenesis and hypothesis on its evolution". Acta Zoologica . 89 (2): 169–178. doi:10.1111/j.1463-6395.2007.00312.x.

[6] Fowler, Denver W.; Freedman, Elizabeth A.; Scannella, John B. (2009-11-25). Pizzari, Tom (ed.). "Predatory Functional Morphology in Raptors: Interdigital Variation in Talon Size Is Related to Prey Restraint and Immobilisation Technique". PLoS ONE. 4 (11): e7999. Bibcode:2009PLoSO...4.7999F. doi: 10.1371/journal.pone.0007999 . ISSN 1932-6203. PMC 2776979 . PMID 19946365.

[7] Lumeij, J. T. (1987). "Avian clinical pathology. General considerations". Veterinary Quarterly. 9 (3): 249–254. doi: 10.1080/01652176.1987.9694109 . PMID 3314103.

[8] Cho, Patricia; Brown, Rosanne; Anderson, Marilyn (1984-01-01). "Comparative gross anatomy of ratites". Zoo Biology. 3 (2): 133–144. doi:10.1002/zoo.1430030205. ISSN 1098-2361.

[Parallel-9] Fain, Matthew G.; Houde, Peter (2004). "Parallel radiations in the primary clades of birds" (PDF). Evolution . 58 (11): 2558–2573. doi:10.1554/04-235. PMID 15612298. S2CID 1296408. Archived from the original (PDF) on 2017-07-09. Retrieved 2016-07-08.

[10] Parker, W. K. (1891). "On the Morphology of a Reptilian Bird, Opisthocomus hoazin". Transactions of the Zoological Society of London. 13 (2): 43–89. doi:10.1111/j.1096-3642.1891.tb00045.x.

[11] Sir Buller, Walter Lawry (1888). "Apteryx australis (South-Island Kiwi)". A History of the Birds of New Zealand. London: Sir Walter Lawry Buller. Archived from the original on 2021-10-20 – via New Zealand Electronic Text Collection.

[12] Maddin, HC; Eckhart, L; Jaeger, K; Russell, AP; Ghannadan, M (2009). "The anatomy and development of the claws of Xenopus laevis (Lissamphibia: Anura) reveal alternate pathways of structural evolution in the integument of tetrapods". Journal of Anatomy. 214 (4): 607–19. doi:10.1111/j.1469-7580.2009.01052.x. PMC 2736125 . PMID 19422431.

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