The anatomy of bird legs and feet is diverse, encompassing many accommodations to perform a wide variety of functions.[1]
Most birds are classified as digitigrade animals, meaning they walk on their toes rather than the entire foot.[3][4] Some of the lower bones of the foot (the distals and most of the metatarsal) are fused to form the tarsometatarsus – a third segment of the leg, specific to birds.[5][6] The upper bones of the foot (proximals), in turn, are fused with the tibia to form the tibiotarsus, as over time the centralia disappeared.[7][6][4][8] The fibula also reduced.[5]
The legs are attached to a strong assembly consisting of the pelvic girdle extensively fused with the uniform spinal bone (also specific to birds) called the synsacrum, built from some of the fused bones.[8][9]
Birds are generally digitigrade animals (toe-walkers),[7][10] which affects the structure of their leg skeleton. They use only their hindlimbs to walk (bipedalism).[2] Their forelimbs evolved to become wings. Most bones of the avian foot (excluding toes) are fused together or with other bones, having changed their function over time.
Tarsometatarsus
Some lower bones of the foot are fused to form the tarsometatarsus – a third segment of the leg specific to birds.[8] It consists of merged distals and metatarsals II, III and IV.[6] Metatarsus I remains separated as a base of the first toe.[4] The tarsometatarsus is the extended foot area, which gives the leg extra lever length.[7]
Tibiotarsus
The foot's upper bones (proximals) are fused with the tibia to form the tibiotarsus, while the centralia are absent.[5][6] The anterior (frontal) side of the dorsal end of the tibiotarsus (at the knee) contains a protruding enlargement called the cnemial crest.[2]
Patella
At the knee above the cnemial crest is the patella (kneecap).[4] Some species do not have patellas, sometimes only a cnemial crest. In grebes both a normal patella and an extension of the cnemial crest are found.[2]
Fibula
The fibula is reduced and adheres extensively to the tibia, usually reaching two-thirds of its length.[2][7][8] Only penguins have full-length fibulae.[4]
Knee and ankle – confusions
The bird knee joint between the femur and tibia (or rather tibiotarsus) points forwards, but is hidden within the feathers. The backward-pointing "heel" (ankle) that is easily visible is a joint between the tibiotarsus and tarsometatarsus.[3][4] The joint inside the tarsus occurs also in some reptiles. It is worth noting here that the name "thick knee" of the members of the familyBurhinidae is a misnomer because their heels are large.[2][8]
The chicks in the orders Coraciiformes and Piciformes have ankles covered by a patch of tough skins with tubercles known as the heel-pad. They use the heel-pad to shuffle inside the nest cavities or holes.[11][12]
Toes and unfused metatarsals
Most birds have four toes, typically three facing forward and one pointing backward.[7][10][8] In a typical perching bird, they consist respectively of 3, 4, 5 and 2 phalanges.[2] Some birds, like the sanderling, have only the forward-facing toes; these are called tridactyl feet while the ostrich have only two toes (didactyl feet).[2][4] The first digit, called the hallux, is homologous to the human big toe.[7][10]
The claws are located on the extreme phalanx of each toe.[4] They consist of a horny keratinouspodotheca, or sheath,[2] and are not part of the skeleton.
The bird foot also contains one or two metatarsals not fused in the tarsometatarsus.[8]
The legs are attached to a very strong, lightweight assembly consisting of the pelvic girdle extensively fused with the uniform spinal bone called the synsacrum,[7][10] which is specific to birds. The synsacrum is built from the lumbar fused with the sacral, some of the first sections of the caudal, and sometimes the last one or two sections of the thoracicvertebrae, depending on species (birds have altogether between 10 and 22 vertebrae).[9] Except for those of ostriches and rheas, pubic bones do not connect to each other, easing egg-laying.[8]
Rigidity and reduction of mass
Fusions of individual bones into strong, rigid structures are characteristic.[1][7][10]
Most major bird bones are extensively pneumatized. They contain many air pockets connected to the pulmonary air sacs of the respiratory system.[13] Their spongy interior makes them strong relative to their mass.[2][7] The number of pneumatic bones depends on the species; pneumaticity is slight or absent in diving birds.[14] For example, in the long-tailed duck, the leg and wing bones are not pneumatic, in contrast with some of the other bones, while loons and puffins have even more massive skeletons with no aired bones.[15][16] The flightlessostrich and emu have pneumatic femurs, and so far this is the only known pneumatic bone in these birds[17] except for the ostrich's cervical vertebrae.[13]
Fusions (leading to rigidity) and pneumatic bones (leading to reduced mass) are some of the many adaptations of birds for flight.[1][7]
Loons tend to walk this way because their legs and pelvis are highly specialized for swimming. They have a narrow pelvis, which moves the attachment point of the femur to the rear, and their tibiotarsus is much longer than the femur. This shifts the feet (toes) behind the center of mass of the loon body. They walk usually by pushing themselves on their breasts; larger loons cannot take off from land.[10] This position, however, is highly suitable for swimming because their feet are located at the rear like the propeller on a motorboat.[2]
Grebes and many other waterfowl have shorter femur and a more or less narrow pelvis, too, which gives the impression that their legs are attached to the rear as in loons.[2]
Functions
Because avian forelimbs are wings, many forelimb functions are performed by the bill and hindlimbs.[10] It has been proposed that the hindlimbs are important in flight as accelerators when taking-off.[18][19] Some leg and foot functions, including conventional ones and those specific to birds, are:
Cradling and turning eggs during incubation.[3] Birds lacking a brood patch incubate the eggs with their feet – grasping one or even two of them (gannets, boobies) or keeping them on the top surfaces of their feet (penguins under a pouch of belly skin, murres).[1]
Preening and cleaning.[10] Sometimes birds use a special claw (for example, barn owls have a so-called "feather comb"). Some herons and nightjars use the claw for cleaning the head.[2]
Anisodactyl: three toes in front (2, 3, 4), and one in back (1); in nearly all songbirds and most other perching birds.[4][20]
Zygodactyl: two toes in front (2, 3) and two in back (1, 4) – the outermost front toe (4) is reversed. The zygodactyl arrangement is a case of convergence, because it evolved in birds in different ways nine times.[1][10]
Heterodactyl: two toes in front (3, 4) and two in back (2, 1) – the inner front toe (2) is reversed; heterodactyl arrangement only exists in trogons.[20]
Syndactyl: three toes in front (2, 3, 4), one in back (1); the inner and middle (2, 3) are joined for much of their length.[2][1] This is often found in Picocoraciae, though rollers, ground rollers, and Piciformes (who are zygodactyl) are exceptions.[7]
Pamprodactyl: two inner toes in front (2, 3), the two outer (1, 4) can rotate freely forward and backward. In mousebirds and some swifts. Some swifts move all four digits forward to use them as hooks to hang.[20]
The most common arrangement is the anisodactyl foot, and second among perching birds is the zygodactyl arrangement.[3][7][21]
Claws
All birds have claws at the end of the toes. The claws are typically curved and the radius of curvature tends to be greater as the bird is larger although they tend to be straighter in large ground dwelling birds such as ratites.[22] Some species (including nightjars, herons, frigatebirds, owls and pratincoles) have comb-like serrations on the claw of the middle toe that may aid in scratch preening.[23]
Palmations and lobes enable swimming or help walking on loose ground such as mud.[3] The webbed or palmated feet of birds can be categorized into several types:
Lobate: the anterior digits (2–4) are edged with lobes of skin. Lobes expand or contract when a bird swims. In grebes, coots, phalaropes, finfoots and some palmate-footed ducks on the hallux (1). Grebes have more webbing between the toes than coots and phalaropes.[20][4][21]
The arteries and veins intertwine in the legs, so heat can be transferred from arteries back to veins before reaching the feet. Such a mechanism is called countercurrent exchange. Gulls can open a shunt between these vessels, turning back the bloodstream above the foot, and constrict the vessels in the foot. This reduces heat loss by more than 90 percent. In gulls, the temperature of the base of the leg is 32 °C (89 °F), while that of the foot may be close to 0 °C (32 °F).[1]
However, for cooling, this heat-exchange network can be bypassed and blood-flow through the foot significantly increased (giant petrels). Some birds also excrete onto their feet, increasing heat loss via evaporation (storks, New World vultures).[1]
^ abcdRomer, Alfred Sherwood; Parsons, Thomas S. (1977). The Vertebrate Body. Philadelphia, PA: Holt-Saunders International. pp. 205–208. ISBN978-0-03-910284-5.
^ abcdefghijklmnProctor, Noble S.; Lynch, Patrick J. (1993). "Chapters: 6. Topography of the foot, 11. The pelvic girdle, and 12. The bones of the leg and foot Family". Manual of Ornithology. Avian Structure & Function. New Haven and London: Yale University Press. pp. 70–75, 140–141, 142–144. ISBN978-0-300-07619-6.
^ abcdefghDobrowolski, Kazimierz A.; Klimaszewski, Sędzimir M.; Szelęgiewicz, Henryk (1981). "Chapters: Gromada: Ptaki - Aves: Układ kostny; Pas miednicowy i kończyna tylna [Class: Birds: The skeletal system; The pelvic girdle and the hindlimb]". Zoologia [Zoology] (in Polish) (4th ed.). Warsaw: Wydawnictwo Szkolne i Pedagogiczne. pp. 462–464, 469. ISBN978-83-02-00608-1.
^ abKowalska-Dyrcz, Alina (1990). "Entry: synsakrum [synsacrum]". In Busse, Przemysław (ed.). Ptaki [Birds]. Mały słownik zoologiczny [Small zoological dictionary] (in Polish). Vol. II (1st ed.). Warsaw: Wiedza Powszechna. p. 245. ISBN978-83-214-0563-6.
^Chasen, F. N. (1923). "On The Heel-Pad in certain Malaysian Birds". Journal of the Malayan Branch of the Royal Asiatic Society. 1 (87): 237–246. JSTOR41559544.
^ abcdKalbe, Lothar (1983). "Besondere Formen für spezielle Aufgaben der Wassertiere [Special adaptations of aquatic animals to specific lifestyles]". Tierwelt am Wasser [Wildlife by the Water] (in German) (1st ed.). Leipzig-Jena-Berlin: Urania-Verlag. pp. 72–77.
^Pike, A. V. L.; Maitland, D. P. (2004). "Scaling of bird claws". Journal of Zoology. 262: 73–81. doi:10.1017/S0952836903004382.