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Beak

May 17, 2023

For other uses, see Beak (disambiguation).

The beak, bill, or rostrum is an external anatomical structure found mostly in birds, but also in turtles, non-avian dinosaurs and a few mammals. A beak is used for eating, preening, manipulating objects, killing prey, fighting, probing for food, courtship, and feeding young. The terms beak and rostrum are also used to refer to a similar mouth part in some ornithischians, pterosaurs, cetaceans, dicynodonts, anuran tadpoles, monotremes (i.e. echidnas and platypuses, which have a beak-like structure), sirens, pufferfish, billfishes and cephalopods.

Comparison of bird beaks, displaying different shapes adapted to different feeding methods. Not to scale.

Although beaks vary significantly in size, shape, color and texture, they share a similar underlying structure. Two bony projections – the upper and lower mandibles – are covered with a thin keratinized layer of epidermis known as the rhamphotheca. In most species, two holes called nares lead to the respiratory system.

Etymology

Although the word "beak" was, in the past, generally restricted to the sharpened bills of birds of prey,[1] in modern ornithology, the terms beak and bill are generally considered to be synonymous.[2] The word, which dates from the 13th century, comes from the Middle English bec, which itself comes from the Latin beccus.[3]

Anatomy

 
The bony core of the beak is a lightweight framework, like that seen on this barn owl's skull.

Although beaks vary significantly in size and shape from species to species, their underlying structures have a similar pattern. All beaks are composed of two jaws, generally known as the maxilla (upper) and mandible (lower).[4](p147) The upper, and in some cases the lower, mandibles are strengthened internally by a complex three-dimensional network of bony spicules (or trabeculae) seated in soft connective tissue and surrounded by the hard outer layers of the beak.[5](p149)[6] The avian jaw apparatus is made up of two units: one four-bar linkage mechanism and one five-bar linkage mechanism.[7]

Mandibles

 
A gull's upper mandible can flex upwards because it is supported by small bones which can move slightly backwards and forwards.

The upper mandible is supported by a three-pronged bone called the intermaxillary. The upper prong of this bone is embedded into the forehead, while the two lower prongs attach to the sides of the skull. At the base of the upper mandible a thin sheet of nasal bones is attached to the skull at the nasofrontal hinge, which gives mobility to the upper mandible, allowing it to move upwards and downwards.[2]

 
Position of vomer (shaded red) in neognathae (left) and paleognathae (right)

The base of the upper mandible, or the roof when seen from the mouth, is the palate, the structure of which differs greatly in the ratites. Here, the vomer is large and connects with premaxillae and maxillopalatine bones in a condition termed as a "paleognathous palate". All other extant birds have a narrow forked vomer that does not connect with other bones and is then termed as neognathous. The shape of these bones varies across the bird families.[a]

The lower mandible is supported by a bone known as the inferior maxillary bone—a compound bone composed of two distinct ossified pieces. These ossified plates (or rami), which can be U-shaped or V-shaped,[4](p147) join distally (the exact location of the joint depends on the species) but are separated proximally, attaching on either side of the head to the quadrate bone. The jaw muscles, which allow the bird to close its beak, attach to the proximal end of the lower mandible and to the bird's skull.[5](p148) The muscles that depress the lower mandible are usually weak, except in a few birds such as the starlings and the extinct huia, which have well-developed digastric muscles that aid in foraging by prying or gaping actions.[8] In most birds, these muscles are relatively small as compared to the jaw muscles of similarly sized mammals.[9]

Rhamphotheca

The outer surface of the beak consists of a thin sheath of keratin called the rhamphotheca,[2][5](p148) which can be subdivided into the rhinotheca of the upper mandible and the gnathotheca of the lower mandible.[10](p47) This covering arises from the Malpighian layer of the bird's epidermis,[10](p47) growing from plates at the base of each mandible.[11] There is a vascular layer between the rhamphotheca and the deeper layers of the dermis, which is attached directly to the periosteum of the bones of the beak.[12] The rhamphotheca grows continuously in most birds, and in some species, the color varies seasonally.[13] In some alcids, such as the puffins, parts of the rhamphotheca are shed each year after the breeding season, while some pelicans shed a part of the bill called a "bill horn" that develops in the breeding season.[14][15][16]

While most extant birds have a single seamless rhamphotheca, species in a few families, including the albatrosses[10](p47) and the emu, have compound rhamphothecae that consist of several pieces separated and defined by softer keratinous grooves.[17] Studies have shown that this was the primitive ancestral state of the rhamphotheca, and that the modern simple rhamphotheca resulted from the gradual loss of the defining grooves through evolution.[18]

Tomia

 
The sawtooth serrations on a common merganser's bill help it to hold tight to its fish prey.

The tomia (singular tomium) are the cutting edges of the two mandibles.[10](p598) In most birds, these range from rounded to slightly sharp, but some species have evolved structural modifications that allow them to handle their typical food sources better.[19]Granivorous (seed-eating) birds, for example, have ridges in their tomia, which help the bird to slice through a seed's outer hull.[20] Most falcons have a sharp projection along the upper mandible, with a corresponding notch on the lower mandible. They use this "tooth" to sever their prey's vertebrae fatally or to rip insects apart. Some kites, principally those that prey on insects or lizards, also have one or more of these sharp projections,[21] as do the shrikes.[22] The tomial teeth of falcons are underlain by bone, while the shrike tomial teeth are entirely keratinous.[23] Some fish-eating species, e.g., the mergansers, have sawtooth serrations along their tomia, which help them to keep hold of their slippery, wriggling prey.[10](p48)

Birds in roughly 30 families have tomia lined with tight bunches of very short bristles along their entire length. Most of these species are either insectivores (preferring hard-shelled prey) or snail eaters, and the brush-like projections may help to increase the coefficient of friction between the mandibles, thereby improving the bird's ability to hold hard prey items.[24] Serrations on hummingbird bills, found in 23% of all hummingbird genera, may perform a similar function, allowing the birds to effectively hold insect prey. They may also allow shorter-billed hummingbirds to function as nectar thieves, as they can more effectively hold and cut through long or waxy flower corollas.[25] In some cases, the color of a bird's tomia can help to distinguish between similar species. The snow goose, for example, has a reddish-pink bill with black tomia, while the whole beak of the similar Ross's goose is pinkish-red, without darker tomia.[26]

Culmen

 
A bird's culmen is measured in a straight line from the tip of the beak to a set point — here, where the feathering starts on the bird's forehead.[27]

The culmen is the dorsal ridge of the upper mandible.[10](p127) Likened by ornithologist E. Coues[4] to the ridge line of a roof, it is the "highest middle lengthwise line of the bill" and runs from the point where the upper mandible emerges from the forehead's feathers to its tip.[4](p152) The bill's length along the culmen is one of the regular measurements made during bird banding (ringing)[27] and is particularly useful in feeding studies.[28] There are several standard measurements that can be made—from the beak's tip to the point where feathering starts on the forehead, from the tip to the anterior edge of the nostrils, from the tip to the base of the skull, or from the tip to the cere (for raptors and owls)[10](p342) — and scientists from various parts of the world generally favor one method over another.[28] In all cases, these are chord measurements (measured in a straight line from point to point, ignoring any curve in the culmen) taken with calipers.[27]

The shape or color of the culmen can also help with the identification of birds in the field. For example, the culmen of the parrot crossbill is strongly decurved, while that of the very similar red crossbill is more moderately curved.[29] The culmen of a juvenile common loon is all dark, while that of the very similarly plumaged juvenile yellow-billed loon is pale towards the tip.[30]

Gonys

The gonys is the ventral ridge of the lower mandible, created by the junction of the bone's two rami, or lateral plates.[10](p254) The proximal end of that junction—where the two plates separate—is known as the gonydeal angle or gonydeal expansion. In some gull species, the plates expand slightly at that point, creating a noticeable bulge; the size and shape of the gonydeal angle can be useful in identifying between otherwise similar species. Adults of many species of large gulls have a reddish or orangish gonydeal spot near the gonydeal expansion.[31] This spot triggers begging behavior in gull chicks. The chick pecks at the spot on its parent's bill, which in turn stimulates the parent to regurgitate food.[32]

Commissure

Depending on its use, commissure may refer to the junction of the upper and lower mandibles,[4](p155) or alternately, to the full-length apposition of the closed mandibles, from the corners of the mouth to the tip of the beak.[10](p105)

Gape

"Gape" redirects here. For other uses, see gaping (disambiguation) and gapes (disambiguation).
 
The gapes of juvenile altricial birds are often brightly coloured, as in this common starling.

In bird anatomy, the gape is the interior of the open mouth of a bird, and the gape flange is the region where the two mandibles join together at the base of the beak.[33] The width of the gape can be a factor in the choice of food.[34]

 
The gape flange on this juvenile house sparrow is the yellowish region at the base of the beak.

Gapes of juvenile altricial birds are often brightly coloured, sometimes with contrasting spots or other patterns, and these are believed to be an indication of their health, fitness and competitive ability. Based on this, the parents decide how to distribute food among the chicks in the nest.[35] Some species, especially in the families Viduidae and Estrildidae, have bright spots on the gape known as gape tubercles or gape papillae. These nodular spots are conspicuous even in low light.[36] A study examining the nestling gapes of eight passerine species found that the gapes were conspicuous in the ultraviolet spectrum (visible to birds but not to humans).[37] Parents may, however, not rely solely on the gape coloration, and other factors influencing their decision remain unknown.[38]

Red gape color has been shown in several experiments to induce feeding. An experiment in manipulating brood size and immune system with barn swallow nestlings showed the vividness of the gape was positively correlated with T-cell–mediated immunocompetence, and that larger brood size and injection with an antigen led to a less vivid gape.[39] Conversely, the red gape of the common cuckoo (Cuculus canorus) did not induce extra feeding in host parents.[40] Some brood parasites, such as the Hodgson's hawk-cuckoo (C. fugax), have colored patches on the wing that mimic the gape color of the parasitized species.[41]

When born, the chick's gape flanges are fleshy. As it grows into a fledgling, the gape flanges remain somewhat swollen and can thus be used to recognize that a particular bird is young.[42] By the time it reaches adulthood, the gape flanges will no longer be visible.

Nares

 
Falcons have a small tubercule within each nare.[43]

Most species of birds have external nares (nostrils) located somewhere on their beak. The nares are two holes—circular, oval or slit-like in shape—which lead to the nasal cavities within the bird's skull, and thus to the rest of the respiratory system.[10](p375) In most bird species, the nares are located in the basal third of the upper mandible. Kiwi are a notable exception; their nares are located at the tip of their bills.[19] A handful of species have no external nares. Cormorants and darters have primitive external nares as nestlings, but these close soon after the birds fledge; adults of these species (and gannets and boobies of all ages, which also lack external nostrils) breathe through their mouths.[10](p47) There is typically a septum made of bone or cartilage that separates the two nares, but in some families (including gulls, cranes and New World vultures), the septum is missing.[10](p47) While the nares are uncovered in most species, they are covered with feathers in a few groups of birds, including grouse and ptarmigans, crows, and some woodpeckers.[10](p375) The feathers over a ptarmigan's nostrils help to warm the air it inhales,[44] while those over a woodpecker's nares help to keep wood particles from clogging its nasal passages.[45]

Species in the bird order Procellariformes have nostrils enclosed in double tubes which sit atop or along the sides of the upper mandible.[10](p375) These species, which include the albatrosses, petrels, diving petrels, storm petrels, fulmars and shearwaters, are widely known as "tubenoses".[46] A number of species, including the falcons, have a small bony tubercule which projects from their nares. The function of this tubercule is unknown. Some scientists suggest it may act as a baffle, slowing down or diffusing airflow into the nares (and thus allowing the bird to continue breathing without damaging its respiratory system) during high-speed dives, but this theory has not been proved experimentally. Not all species that fly at high speeds have such tubercules, while some species which fly at low speeds do.[43]

Operculum

 
The rock dove's operculum is a mass at the base of the bill.

The nares of some birds are covered by an operculum (plural opercula), a membraneous, horny or cartilaginous flap.[5](p117)[47] In diving birds, the operculum keeps water out of the nasal cavity;[5](p117) when the birds dive, the impact force of the water closes the operculum.[48] Some species which feed on flowers have opercula to help to keep pollen from clogging their nasal passages,[5](p117) while the opercula of the two species of Attagis seedsnipe help to keep dust out.[49] The nares of nestling tawny frogmouths are covered with large dome-shaped opercula, which help to reduce the rapid evaporation of water vapor, and may also help to increase condensation within the nostrils themselves—both critical functions, since the nestlings get fluids only from the food their parents bring them. These opercula shrink as the birds age, disappearing completely by the time they reach adulthood.[50] In pigeons, the operculum has evolved into a soft swollen mass that sits at the base of the bill, above the nares;[10](p84) though it is sometimes referred to as the cere, this is a different structure.[4](p151) Tapaculos are the only birds known to have the ability to move their opercula.[10](p375)

Rosette

Some species, such as the puffin, have a fleshy rosette, sometimes called a "gape rosette",[51] at the corners of the beak. In the puffin, this is grown as part of its display plumage.[52]

Cere

"Cere" redirects here. For other uses, see Cere (disambiguation).

Birds from a handful of families—including raptors, owls, skuas, parrots, turkeys and curassows—have a waxy structure called a cere (from the Latin cera, which means "wax") or ceroma[53][54] which covers the base of their bill. This structure typically contains the nares, except in the owls, where the nares are distal to the cere. Although it is sometimes feathered in parrots,[55] the cere is typically bare and often brightly colored.[19] In raptors, the cere is a sexual signal which indicates the "quality" of a bird; the orangeness of a Montagu's harrier's cere, for example, correlates to its body mass and physical condition.[56] The cere color of young Eurasian scops-owls has an ultraviolet (UV) component, with a UV peak that correlates to the bird's mass. A chick with a lower body mass has a UV peak at a higher wavelength than a chick with a higher body mass does. Studies have shown that parent owls preferentially feed chicks with ceres that show higher wavelength UV peaks, that is, lighter-weight chicks.[57]

The color or appearance of the cere can be used to distinguish between males and females in some species. For example, the male great curassow has a yellow cere, which the female (and young males) lack.[58] The male budgerigar's cere is royal blue, while the female's is a very pale blue, white, or brown.[59]

Nail

 
The nail is the black tip of this mute swan's beak.

All birds of the family Anatidae (ducks, geese, and swans) have a nail, a plate of hard horny tissue at the tip of the beak.[60] This shield-shaped structure, which sometimes spans the entire width of the beak, is often bent at the tip to form a hook.[61] It serves different purposes depending on the bird's primary food source. Most species use their nails to dig seeds out of mud or vegetation,[62] while diving ducks use theirs to pry molluscs from rocks.[63] There is evidence that the nail may help a bird to grasp objects. Species which use strong grasping motions to secure their food (such as when catching and holding onto a large squirming frog) have very wide nails.[64] Certain types of mechanoreceptors, nerve cells that are sensitive to pressure, vibration, or touch, are located under the nail.[65]

The shape or color of the nail can sometimes be used to help distinguish between similar-looking species or between various ages of waterfowl. For example, the greater scaup has a wider black nail than does the very similar lesser scaup.[66] Juvenile "grey geese" have dark nails, while most adults have pale nails.[67] The nail gave the wildfowl family one of its former names: "Unguirostres" comes from the Latin ungus, meaning "nail" and rostrum, meaning "beak".[61]

Rictal bristles

Rictal bristles are stiff hair-like feathers that arise around the base of the beak.[68] They are common among insectivorous birds, but are also found in some non-insectivorous species.[69] Their function is uncertain, although several possibilities have been proposed.[68] They may function as a "net", helping in the capture of flying prey, although to date, there has been no empirical evidence to support this idea.[70] There is some experimental evidence to suggest that they may prevent particles from striking the eyes if, for example, a prey item is missed or broken apart on contact.[69] They may also help to protect the eyes from particles encountered in flight, or from casual contact from vegetation.[70] There is also evidence that the rictal bristles of some species may function tactilely, in a manner similar to that of mammalian whiskers (vibrissae). Studies have shown that Herbst corpuscles, mechanoreceptors sensitive to pressure and vibration, are found in association with rictal bristles. They may help with prey detection, with navigation in darkened nest cavities, with the gathering of information during flight or with prey handling.[70]

Egg tooth

 
This Arctic tern chick still has its egg tooth, the small white projection near the tip of its upper mandible.
Main article: Egg tooth

Full-term chicks of most bird species have a small sharp, calcified projection on their beak, which they use to chip their way out of their egg.[10](p178) Commonly known as an egg tooth, this white spike is generally near the tip of the upper mandible, though some species have one near the tip of their lower mandible instead, and a few species have one on each mandible.[71] Despite its name, the projection is not an actual tooth, as the similarly-named projections of some reptiles are; instead, it is part of the integumentary system, as are claws and scales.[72] The hatching chick first uses its egg tooth to break the membrane around an air chamber at the wide end of the egg. Then it pecks at the eggshell while turning slowly within the egg, eventually (over a period of hours or days) creating a series of small circular fractures in the shell.[5](p427) Once it has breached the egg's surface, the chick continues to chip at it until it has made a large hole. The weakened egg eventually shatters under the pressure of the bird's movements.[5](p428)

The egg tooth is so critical to a successful escape from the egg that chicks of most species will perish unhatched if they fail to develop one.[71] However, there are a few species which do not have egg teeth. Megapode chicks have an egg tooth while still in the egg but lose it before hatching,[5](p427) while kiwi chicks never develop one; chicks of both families escape their eggs by kicking their way out.[73] Most chicks lose their egg teeth within a few days of hatching,[10](p178) though petrels keep theirs for nearly three weeks[5](p428) and marbled murrelets have theirs for up to a month.[74] Generally, the egg tooth drops off, though in songbirds it is reabsorbed.[5](p428)

Color

The color of a bird's beak results from concentrations of pigments — primarily melanins and carotenoids — in the epidermal layers, including the rhamphotheca.[75]Eumelanin, which is found in the bare parts of many bird species, is responsible for all shades of gray and black; the denser the deposits of pigment found in the epidermis, the darker the resulting color. Phaeomelanin produces "earth tones" ranging from gold and rufous to various shades of brown.[76]: 62  Although it is thought to occur in combination with eumelanin in beaks which are buff, tan, or horn-colored, researchers have yet to isolate phaeomelanin from any beak structure.[76]: 63  More than a dozen types of carotenoids are responsible for the coloration of most red, orange, and yellow beaks.[76]: 64 

The hue of the color is determined by the precise mix of red and yellow pigments, while the saturation is determined by the density of the deposited pigments. For example, bright red is created by dense deposits of mostly red pigments, while dull yellow is created by diffuse deposits of mostly yellow pigments. Bright orange is created by dense deposits of both red and yellow pigments, in roughly equal concentrations.[76]: 66  Beak coloration helps to make displays using those beaks more obvious.[77](p155) In general, beak color depends on a combination of the bird's hormonal state and diet. Colors are typically brightest as the breeding season approaches, and palest after breeding.[31]

Birds are capable of seeing colors in the ultraviolet range, and some species are known to have ultraviolet peaks of reflectance (indicating the presence of ultraviolet color) on their beaks.[78] The presence and intensity of these peaks may indicate a bird's fitness,[56] sexual maturity or pair bond status. [78]King and emperor penguins, for example, show spots of ultraviolet reflectance only as adults. These spots are brighter on paired birds than on courting birds. The position of such spots on the beak may be important in allowing birds to identify conspecifics. For instance, the very similarly-plumaged king and emperor penguins have UV-reflective spots in different positions on their beaks.[78]

Dimorphism

 
The beaks of the now-extinct Huia (female upper, male lower) show marked sexual dimorphism

The size and shape of the beak can vary across species as well as between them; in some species, the size and proportions of the beak vary between males and females. This allows the sexes to utilize different ecological niches, thereby reducing intraspecific competition.[79] For example, females of nearly all shorebirds have longer bills than males of the same species,[80] and female American avocets have beaks which are slightly more upturned than those of males.[81] Males of the larger gull species have bigger, stouter beaks than those of females of the same species, and immatures can have smaller, more slender beaks than those of adults.[82] Many hornbills show sexual dimorphism in the size and shape of both beaks and casques, and the female huia's slim, decurved bill was nearly twice as long as the male's straight, thicker one.[10](p48)

Color can also differ between sexes or ages within a species. Typically, such a color difference is due to the presence of androgens. For example, in house sparrows, melanins are produced only in the presence of testosterone; castrated male house sparrows—like female house sparrows—have brown beaks. Castration also prevents the normal seasonal color change in the beaks of male black-headed gulls and indigo buntings.[83]

Development

The beak of modern birds has a fused premaxillary bone, which is modulated by the expression of Fgf8 gene in the frontonasal ectodermal zone during embryonic development.[84]

The shape of the beak is determined by two modules: the prenasal cartilage during early embryonic stage and the premaxillary bone during later stages. Development of the prenasal cartilage is regulated by genes Bmp4 and CaM, while that of the premaxillary bone is controlled by TGFβllr, β-catenin, and Dickkopf-3.[85][86] TGFβllr codes for a serine/threonine protein kinase that regulates gene transcription upon ligand binding; previous work has highlighted its role in mammalian craniofacial skeletal development.[87] β-catenin is involved in the differentiation of terminal bone cells. Dickkopf-3 codes for a secreted protein also known to be expressed in mammalian craniofacial development. The combination of these signals determines beak growth along the length, depth, and width axes. Reduced expression of TGFβllr significantly decreased the depth and length of chicken embryonic beak due to the underdevelopment of the premaxillary bone.[88] Contrarily, an increase in Bmp4 signaling would result in a reduced premaxillary bone due to the overdevelopment of the prenasal cartilage, which takes up more mesenchymal cells for cartilage, instead of bone, formation.[85][86]

Functions

Three barn owls threatening an intruder. Barn owl threat displays usually include hissing and bill-snapping, as here
 
The platypus uses its bill to navigate underwater, detect food, and dig. The bill contains receptors that help detect prey.

Birds may bite or stab with their beaks to defend themselves.[89] Some species use their beaks in displays of various sorts. As part of his courtship, for example, the male garganey touches his beak to the blue speculum feathers on his wings in a fake preening display, and the male Mandarin duck does the same with his orange sail feathers.[77](p20) A number of species use a gaping, open beak in their fear and/or threat displays. Some augment the display by hissing or breathing heavily, while others clap their beak. The platypus uses its bill to navigate underwater, detect food, and dig. The bill contains electroreceptors and mechanoreceptors, causing muscular contractions to help detect prey. It is one of the few species of mammals to use electroreception.[90][91]

Preening

Main article: Preening

The beak of birds plays a role in removing skin parasites (ectoparasites) such as lice. It is mainly the tip of the beak that does this. Studies have shown that inserting a bit to stop birds from using the tip results in increased parasite loads in pigeons.[92] Birds that have naturally deformed beaks have also been noted to have higher levels of parasites.[93][94][95][96] It is thought that the overhang at the end of the top portion of the beak (that is the portion that begins to curve downwards) slides against the lower beak to crush parasites.[92]

This overhang of the beak is thought to be under stabilising natural selection. Very long beaks are thought to be selected against because they are prone to a higher number of breaks, as has been demonstrated in rock pigeons.[97] Beaks with no overhang would be unable to effectively remove and kill ectoparasites as mentioned above. Studies have supported there is a selection pressure for an intermediate amount of overhang. Western Scrub Jays who had more symmetrical bills (i.e. those with less of an overhang), were found to have higher amounts of lice when tested.[98] The same pattern has been seen in surveys of Peruvian birds.[99]

Additionally, because of the role beaks play in preening, this is evidence for coevolution of the beak overhang morphology and body morphology of parasites. Artificially removing the ability to preen in birds, followed by readdition of preening ability was shown to result in changes in body size in lice. Once the ability of the birds to preen was reintroduced, the lice were found to show declines in body size suggesting they may evolve in response to preening pressures from birds[92] who could respond in turn with changes in beak morphology.[92]

Communication

A number of species, including storks, some owls, frogmouths and the noisy miner, use bill clapping as a form of communication.[77](p83)

Heat exchange

Studies have shown that some birds use their beaks to rid themselves of excess heat. The toco toucan, which has the largest beak relative to the size of its body of any bird species, is capable of modifying the blood flow to its beak. This process allows the beak to work as a "transient thermal radiator", reportedly rivaling an elephant's ears in its ability to radiate body heat.[100]

Measurements of the bill sizes of several species of American sparrows found in salt marshes along the North American coastlines show a strong correlation with summer temperatures recorded in the locations where the sparrows breed; latitude alone showed a much weaker correlation. By dumping excess heat through their bills, the sparrows are able to avoid the water loss which would be required by evaporative cooling—an important benefit in a windy habitat where freshwater is scarce.[101] Several ratites, including the common ostrich, the emu and the southern cassowary, use various bare parts of their bodies (including their beaks) to dissipate as much as 40% of their metabolic heat production.[102] Alternately, studies have shown that birds from colder climates (higher altitudes or latitudes and lower environmental temperatures) have smaller beaks, lessening heat loss from that structure.[103]

Billing

 
When billing, northern gannets raise their beaks high and clatter them against each other.

During courtship, mated pairs of many bird species touch or clasp each other's bills. Termed billing (also nebbing in British English),[104] this behavior appears to strengthen pair bonding.[105]

The amount of contact involved varies among species. Some gently touch only a part of their partner's beak while others clash their beaks vigorously together.[106]

Gannets raise their bills high and repeatedly clatter them, the male puffin nibbles at the female's beak, the male waxwing puts his bill in the female's mouth and ravens hold each other's beaks in a prolonged "kiss".[107] Billing can also be used as a gesture of appeasement or subordination. Subordinate Canada jay routinely bill more dominant birds, lowering their body and quivering their wings in the manner of a young bird food begging as they do so.[108] A number of parasites, including rhinonyssids and Trichomonas gallinae are known to be transferred between birds during episodes of billing.[109][110]

Use of the term extends beyond avian behavior; "billing and cooing" in reference to human courtship (particularly kissing) has been in use since Shakespeare's time,[111] and derives from the courtship of doves.[112]

Beak trimming

Main article: Debeaking

Because the beak is a sensitive organ with many sensory receptors, beak trimming (sometimes referred to as 'debeaking') is "acutely painful"[113] to the birds it is performed on. It is nonetheless routinely done to intensively farmed poultry flocks, particularly laying and broiler breeder flocks, because it helps reduce the damage the flocks inflict on themselves due to a number of stress-induced behaviors, including cannibalism, vent pecking and feather pecking. A cauterizing blade or infrared beam is used to cut off about half of the upper beak and about a third of the lower beak. Pain and sensitivity can persist for weeks or months after the procedure, and neuromas can form along the cut edges. Food intake typically decreases for some period after the beak is trimmed. However, studies show that trimmed poultry's adrenal glands weigh less, and their plasma corticosterone levels are lower than those found in untrimmed poultry, indicating that they are less stressed overall.[113]

A similar but separate practice, usually performed by an avian veterinarian or an experienced birdkeeper, involves clipping, filing or sanding the beaks of captive birds for health purposes – in order to correct or temporarily alleviate overgrowths or deformities and better allow the bird to go about its normal feeding and preening activities.[114]

Amongst raptor keepers, this practice is commonly known as "coping".[115]

Bill tip organ

 
Kiwis have a probing bill that allows them to detect motion

The bill tip organ is a region found near the tip of the bill in several types of birds that forage particularly by probing. The region has a high density of nerve endings known as the corpuscles of Herbst. This consists of pits in the bill surface which in the living bird is occupied by cells that sense pressure changes. The assumption is that this allows the bird to perform 'remote touch', which means that it can detect movements of animals which the bird does not directly touch. Bird species known to have a 'bill-tip organ' include ibises, shorebirds of the family Scolopacidae, and kiwis.[116]

There is a suggestion that across these species, the bill tip organ is better-developed among species foraging in wet habitats (water column, or soft mud) than in species using a more terrestrial foraging. However, it has been described in terrestrial birds too, including parrots, who are known for their dextrous extractive foraging techniques. Unlike probing foragers, the tactile pits in parrots are embedded in the hard keratin (or rhamphotheca) of the bill, rather than the bone, and along the inner edges of the curved bill, rather than being on the outside of the bill.[117]

See also

Footnotes

  1. ^ For an explanation of desmognathous, aegithognathous, etc. with images see "Catalogue of Species". 1891 – via Archive.org..

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Bibliography

 
Wikimedia Commons has media related to Beaks.


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May 17, 2023
beak, other, uses, disambiguation, beak, bill, rostrum, external, anatomical, structure, found, mostly, birds, also, turtles, avian, dinosaurs, mammals, beak, used, eating, preening, manipulating, objects, killing, prey, fighting, probing, food, courtship, fee. For other uses see Beak disambiguation The beak bill or rostrum is an external anatomical structure found mostly in birds but also in turtles non avian dinosaurs and a few mammals A beak is used for eating preening manipulating objects killing prey fighting probing for food courtship and feeding young The terms beak and rostrum are also used to refer to a similar mouth part in some ornithischians pterosaurs cetaceans dicynodonts anuran tadpoles monotremes i e echidnas and platypuses which have a beak like structure sirens pufferfish billfishes and cephalopods Comparison of bird beaks displaying different shapes adapted to different feeding methods Not to scale Although beaks vary significantly in size shape color and texture they share a similar underlying structure Two bony projections the upper and lower mandibles are covered with a thin keratinized layer of epidermis known as the rhamphotheca In most species two holes called nares lead to the respiratory system Contents 1 Etymology 2 Anatomy 2 1 Mandibles 2 2 Rhamphotheca 2 3 Tomia 2 4 Culmen 2 5 Gonys 2 6 Commissure 2 7 Gape 2 8 Nares 2 9 Operculum 2 10 Rosette 2 11 Cere 2 12 Nail 2 13 Rictal bristles 3 Egg tooth 4 Color 5 Dimorphism 6 Development 7 Functions 7 1 Preening 7 2 Communication 7 3 Heat exchange 8 Billing 9 Beak trimming 10 Bill tip organ 11 See also 12 Footnotes 13 References 13 1 BibliographyEtymology EditAlthough the word beak was in the past generally restricted to the sharpened bills of birds of prey 1 in modern ornithology the terms beak and bill are generally considered to be synonymous 2 The word which dates from the 13th century comes from the Middle English bec which itself comes from the Latin beccus 3 Anatomy Edit The bony core of the beak is a lightweight framework like that seen on this barn owl s skull Although beaks vary significantly in size and shape from species to species their underlying structures have a similar pattern All beaks are composed of two jaws generally known as the maxilla upper and mandible lower 4 p147 The upper and in some cases the lower mandibles are strengthened internally by a complex three dimensional network of bony spicules or trabeculae seated in soft connective tissue and surrounded by the hard outer layers of the beak 5 p149 6 The avian jaw apparatus is made up of two units one four bar linkage mechanism and one five bar linkage mechanism 7 Mandibles Edit A gull s upper mandible can flex upwards because it is supported by small bones which can move slightly backwards and forwards The upper mandible is supported by a three pronged bone called the intermaxillary The upper prong of this bone is embedded into the forehead while the two lower prongs attach to the sides of the skull At the base of the upper mandible a thin sheet of nasal bones is attached to the skull at the nasofrontal hinge which gives mobility to the upper mandible allowing it to move upwards and downwards 2 Position of vomer shaded red in neognathae left and paleognathae right The base of the upper mandible or the roof when seen from the mouth is the palate the structure of which differs greatly in the ratites Here the vomer is large and connects with premaxillae and maxillopalatine bones in a condition termed as a paleognathous palate All other extant birds have a narrow forked vomer that does not connect with other bones and is then termed as neognathous The shape of these bones varies across the bird families a The lower mandible is supported by a bone known as the inferior maxillary bone a compound bone composed of two distinct ossified pieces These ossified plates or rami which can be U shaped or V shaped 4 p147 join distally the exact location of the joint depends on the species but are separated proximally attaching on either side of the head to the quadrate bone The jaw muscles which allow the bird to close its beak attach to the proximal end of the lower mandible and to the bird s skull 5 p148 The muscles that depress the lower mandible are usually weak except in a few birds such as the starlings and the extinct huia which have well developed digastric muscles that aid in foraging by prying or gaping actions 8 In most birds these muscles are relatively small as compared to the jaw muscles of similarly sized mammals 9 Rhamphotheca Edit The outer surface of the beak consists of a thin sheath of keratin called the rhamphotheca 2 5 p148 which can be subdivided into the rhinotheca of the upper mandible and the gnathotheca of the lower mandible 10 p47 This covering arises from the Malpighian layer of the bird s epidermis 10 p47 growing from plates at the base of each mandible 11 There is a vascular layer between the rhamphotheca and the deeper layers of the dermis which is attached directly to the periosteum of the bones of the beak 12 The rhamphotheca grows continuously in most birds and in some species the color varies seasonally 13 In some alcids such as the puffins parts of the rhamphotheca are shed each year after the breeding season while some pelicans shed a part of the bill called a bill horn that develops in the breeding season 14 15 16 While most extant birds have a single seamless rhamphotheca species in a few families including the albatrosses 10 p47 and the emu have compound rhamphothecae that consist of several pieces separated and defined by softer keratinous grooves 17 Studies have shown that this was the primitive ancestral state of the rhamphotheca and that the modern simple rhamphotheca resulted from the gradual loss of the defining grooves through evolution 18 Tomia Edit The sawtooth serrations on a common merganser s bill help it to hold tight to its fish prey The tomia singular tomium are the cutting edges of the two mandibles 10 p598 In most birds these range from rounded to slightly sharp but some species have evolved structural modifications that allow them to handle their typical food sources better 19 Granivorous seed eating birds for example have ridges in their tomia which help the bird to slice through a seed s outer hull 20 Most falcons have a sharp projection along the upper mandible with a corresponding notch on the lower mandible They use this tooth to sever their prey s vertebrae fatally or to rip insects apart Some kites principally those that prey on insects or lizards also have one or more of these sharp projections 21 as do the shrikes 22 The tomial teeth of falcons are underlain by bone while the shrike tomial teeth are entirely keratinous 23 Some fish eating species e g the mergansers have sawtooth serrations along their tomia which help them to keep hold of their slippery wriggling prey 10 p48 Birds in roughly 30 families have tomia lined with tight bunches of very short bristles along their entire length Most of these species are either insectivores preferring hard shelled prey or snail eaters and the brush like projections may help to increase the coefficient of friction between the mandibles thereby improving the bird s ability to hold hard prey items 24 Serrations on hummingbird bills found in 23 of all hummingbird genera may perform a similar function allowing the birds to effectively hold insect prey They may also allow shorter billed hummingbirds to function as nectar thieves as they can more effectively hold and cut through long or waxy flower corollas 25 In some cases the color of a bird s tomia can help to distinguish between similar species The snow goose for example has a reddish pink bill with black tomia while the whole beak of the similar Ross s goose is pinkish red without darker tomia 26 Culmen Edit A bird s culmen is measured in a straight line from the tip of the beak to a set point here where the feathering starts on the bird s forehead 27 The culmen is the dorsal ridge of the upper mandible 10 p127 Likened by ornithologist E Coues 4 to the ridge line of a roof it is the highest middle lengthwise line of the bill and runs from the point where the upper mandible emerges from the forehead s feathers to its tip 4 p152 The bill s length along the culmen is one of the regular measurements made during bird banding ringing 27 and is particularly useful in feeding studies 28 There are several standard measurements that can be made from the beak s tip to the point where feathering starts on the forehead from the tip to the anterior edge of the nostrils from the tip to the base of the skull or from the tip to the cere for raptors and owls 10 p342 and scientists from various parts of the world generally favor one method over another 28 In all cases these are chord measurements measured in a straight line from point to point ignoring any curve in the culmen taken with calipers 27 The shape or color of the culmen can also help with the identification of birds in the field For example the culmen of the parrot crossbill is strongly decurved while that of the very similar red crossbill is more moderately curved 29 The culmen of a juvenile common loon is all dark while that of the very similarly plumaged juvenile yellow billed loon is pale towards the tip 30 Gonys Edit The gonys is the ventral ridge of the lower mandible created by the junction of the bone s two rami or lateral plates 10 p254 The proximal end of that junction where the two plates separate is known as the gonydeal angle or gonydeal expansion In some gull species the plates expand slightly at that point creating a noticeable bulge the size and shape of the gonydeal angle can be useful in identifying between otherwise similar species Adults of many species of large gulls have a reddish or orangish gonydeal spot near the gonydeal expansion 31 This spot triggers begging behavior in gull chicks The chick pecks at the spot on its parent s bill which in turn stimulates the parent to regurgitate food 32 Commissure Edit Depending on its use commissure may refer to the junction of the upper and lower mandibles 4 p155 or alternately to the full length apposition of the closed mandibles from the corners of the mouth to the tip of the beak 10 p105 Gape Edit Gape redirects here For other uses see gaping disambiguation and gapes disambiguation The gapes of juvenile altricial birds are often brightly coloured as in this common starling In bird anatomy the gape is the interior of the open mouth of a bird and the gape flange is the region where the two mandibles join together at the base of the beak 33 The width of the gape can be a factor in the choice of food 34 The gape flange on this juvenile house sparrow is the yellowish region at the base of the beak Gapes of juvenile altricial birds are often brightly coloured sometimes with contrasting spots or other patterns and these are believed to be an indication of their health fitness and competitive ability Based on this the parents decide how to distribute food among the chicks in the nest 35 Some species especially in the families Viduidae and Estrildidae have bright spots on the gape known as gape tubercles or gape papillae These nodular spots are conspicuous even in low light 36 A study examining the nestling gapes of eight passerine species found that the gapes were conspicuous in the ultraviolet spectrum visible to birds but not to humans 37 Parents may however not rely solely on the gape coloration and other factors influencing their decision remain unknown 38 Red gape color has been shown in several experiments to induce feeding An experiment in manipulating brood size and immune system with barn swallow nestlings showed the vividness of the gape was positively correlated with T cell mediated immunocompetence and that larger brood size and injection with an antigen led to a less vivid gape 39 Conversely the red gape of the common cuckoo Cuculus canorus did not induce extra feeding in host parents 40 Some brood parasites such as the Hodgson s hawk cuckoo C fugax have colored patches on the wing that mimic the gape color of the parasitized species 41 When born the chick s gape flanges are fleshy As it grows into a fledgling the gape flanges remain somewhat swollen and can thus be used to recognize that a particular bird is young 42 By the time it reaches adulthood the gape flanges will no longer be visible Nares Edit Falcons have a small tubercule within each nare 43 Most species of birds have external nares nostrils located somewhere on their beak The nares are two holes circular oval or slit like in shape which lead to the nasal cavities within the bird s skull and thus to the rest of the respiratory system 10 p375 In most bird species the nares are located in the basal third of the upper mandible Kiwi are a notable exception their nares are located at the tip of their bills 19 A handful of species have no external nares Cormorants and darters have primitive external nares as nestlings but these close soon after the birds fledge adults of these species and gannets and boobies of all ages which also lack external nostrils breathe through their mouths 10 p47 There is typically a septum made of bone or cartilage that separates the two nares but in some families including gulls cranes and New World vultures the septum is missing 10 p47 While the nares are uncovered in most species they are covered with feathers in a few groups of birds including grouse and ptarmigans crows and some woodpeckers 10 p375 The feathers over a ptarmigan s nostrils help to warm the air it inhales 44 while those over a woodpecker s nares help to keep wood particles from clogging its nasal passages 45 Species in the bird order Procellariformes have nostrils enclosed in double tubes which sit atop or along the sides of the upper mandible 10 p375 These species which include the albatrosses petrels diving petrels storm petrels fulmars and shearwaters are widely known as tubenoses 46 A number of species including the falcons have a small bony tubercule which projects from their nares The function of this tubercule is unknown Some scientists suggest it may act as a baffle slowing down or diffusing airflow into the nares and thus allowing the bird to continue breathing without damaging its respiratory system during high speed dives but this theory has not been proved experimentally Not all species that fly at high speeds have such tubercules while some species which fly at low speeds do 43 Operculum Edit The rock dove s operculum is a mass at the base of the bill The nares of some birds are covered by an operculum plural opercula a membraneous horny or cartilaginous flap 5 p117 47 In diving birds the operculum keeps water out of the nasal cavity 5 p117 when the birds dive the impact force of the water closes the operculum 48 Some species which feed on flowers have opercula to help to keep pollen from clogging their nasal passages 5 p117 while the opercula of the two species of Attagis seedsnipe help to keep dust out 49 The nares of nestling tawny frogmouths are covered with large dome shaped opercula which help to reduce the rapid evaporation of water vapor and may also help to increase condensation within the nostrils themselves both critical functions since the nestlings get fluids only from the food their parents bring them These opercula shrink as the birds age disappearing completely by the time they reach adulthood 50 In pigeons the operculum has evolved into a soft swollen mass that sits at the base of the bill above the nares 10 p84 though it is sometimes referred to as the cere this is a different structure 4 p151 Tapaculos are the only birds known to have the ability to move their opercula 10 p375 Rosette Edit Some species such as the puffin have a fleshy rosette sometimes called a gape rosette 51 at the corners of the beak In the puffin this is grown as part of its display plumage 52 Cere Edit Cere redirects here For other uses see Cere disambiguation Birds from a handful of families including raptors owls skuas parrots turkeys and curassows have a waxy structure called a cere from the Latin cera which means wax or ceroma 53 54 which covers the base of their bill This structure typically contains the nares except in the owls where the nares are distal to the cere Although it is sometimes feathered in parrots 55 the cere is typically bare and often brightly colored 19 In raptors the cere is a sexual signal which indicates the quality of a bird the orangeness of a Montagu s harrier s cere for example correlates to its body mass and physical condition 56 The cere color of young Eurasian scops owls has an ultraviolet UV component with a UV peak that correlates to the bird s mass A chick with a lower body mass has a UV peak at a higher wavelength than a chick with a higher body mass does Studies have shown that parent owls preferentially feed chicks with ceres that show higher wavelength UV peaks that is lighter weight chicks 57 The color or appearance of the cere can be used to distinguish between males and females in some species For example the male great curassow has a yellow cere which the female and young males lack 58 The male budgerigar s cere is royal blue while the female s is a very pale blue white or brown 59 Nail Edit The nail is the black tip of this mute swan s beak All birds of the family Anatidae ducks geese and swans have a nail a plate of hard horny tissue at the tip of the beak 60 This shield shaped structure which sometimes spans the entire width of the beak is often bent at the tip to form a hook 61 It serves different purposes depending on the bird s primary food source Most species use their nails to dig seeds out of mud or vegetation 62 while diving ducks use theirs to pry molluscs from rocks 63 There is evidence that the nail may help a bird to grasp objects Species which use strong grasping motions to secure their food such as when catching and holding onto a large squirming frog have very wide nails 64 Certain types of mechanoreceptors nerve cells that are sensitive to pressure vibration or touch are located under the nail 65 The shape or color of the nail can sometimes be used to help distinguish between similar looking species or between various ages of waterfowl For example the greater scaup has a wider black nail than does the very similar lesser scaup 66 Juvenile grey geese have dark nails while most adults have pale nails 67 The nail gave the wildfowl family one of its former names Unguirostres comes from the Latin ungus meaning nail and rostrum meaning beak 61 Rictal bristles Edit Rictal bristles are stiff hair like feathers that arise around the base of the beak 68 They are common among insectivorous birds but are also found in some non insectivorous species 69 Their function is uncertain although several possibilities have been proposed 68 They may function as a net helping in the capture of flying prey although to date there has been no empirical evidence to support this idea 70 There is some experimental evidence to suggest that they may prevent particles from striking the eyes if for example a prey item is missed or broken apart on contact 69 They may also help to protect the eyes from particles encountered in flight or from casual contact from vegetation 70 There is also evidence that the rictal bristles of some species may function tactilely in a manner similar to that of mammalian whiskers vibrissae Studies have shown that Herbst corpuscles mechanoreceptors sensitive to pressure and vibration are found in association with rictal bristles They may help with prey detection with navigation in darkened nest cavities with the gathering of information during flight or with prey handling 70 Egg tooth Edit This Arctic tern chick still has its egg tooth the small white projection near the tip of its upper mandible Main article Egg tooth Full term chicks of most bird species have a small sharp calcified projection on their beak which they use to chip their way out of their egg 10 p178 Commonly known as an egg tooth this white spike is generally near the tip of the upper mandible though some species have one near the tip of their lower mandible instead and a few species have one on each mandible 71 Despite its name the projection is not an actual tooth as the similarly named projections of some reptiles are instead it is part of the integumentary system as are claws and scales 72 The hatching chick first uses its egg tooth to break the membrane around an air chamber at the wide end of the egg Then it pecks at the eggshell while turning slowly within the egg eventually over a period of hours or days creating a series of small circular fractures in the shell 5 p427 Once it has breached the egg s surface the chick continues to chip at it until it has made a large hole The weakened egg eventually shatters under the pressure of the bird s movements 5 p428 The egg tooth is so critical to a successful escape from the egg that chicks of most species will perish unhatched if they fail to develop one 71 However there are a few species which do not have egg teeth Megapode chicks have an egg tooth while still in the egg but lose it before hatching 5 p427 while kiwi chicks never develop one chicks of both families escape their eggs by kicking their way out 73 Most chicks lose their egg teeth within a few days of hatching 10 p178 though petrels keep theirs for nearly three weeks 5 p428 and marbled murrelets have theirs for up to a month 74 Generally the egg tooth drops off though in songbirds it is reabsorbed 5 p428 Color EditThe color of a bird s beak results from concentrations of pigments primarily melanins and carotenoids in the epidermal layers including the rhamphotheca 75 Eumelanin which is found in the bare parts of many bird species is responsible for all shades of gray and black the denser the deposits of pigment found in the epidermis the darker the resulting color Phaeomelanin produces earth tones ranging from gold and rufous to various shades of brown 76 62 Although it is thought to occur in combination with eumelanin in beaks which are buff tan or horn colored researchers have yet to isolate phaeomelanin from any beak structure 76 63 More than a dozen types of carotenoids are responsible for the coloration of most red orange and yellow beaks 76 64 The hue of the color is determined by the precise mix of red and yellow pigments while the saturation is determined by the density of the deposited pigments For example bright red is created by dense deposits of mostly red pigments while dull yellow is created by diffuse deposits of mostly yellow pigments Bright orange is created by dense deposits of both red and yellow pigments in roughly equal concentrations 76 66 Beak coloration helps to make displays using those beaks more obvious 77 p155 In general beak color depends on a combination of the bird s hormonal state and diet Colors are typically brightest as the breeding season approaches and palest after breeding 31 Birds are capable of seeing colors in the ultraviolet range and some species are known to have ultraviolet peaks of reflectance indicating the presence of ultraviolet color on their beaks 78 The presence and intensity of these peaks may indicate a bird s fitness 56 sexual maturity or pair bond status 78 King and emperor penguins for example show spots of ultraviolet reflectance only as adults These spots are brighter on paired birds than on courting birds The position of such spots on the beak may be important in allowing birds to identify conspecifics For instance the very similarly plumaged king and emperor penguins have UV reflective spots in different positions on their beaks 78 Dimorphism Edit The beaks of the now extinct Huia female upper male lower show marked sexual dimorphism The size and shape of the beak can vary across species as well as between them in some species the size and proportions of the beak vary between males and females This allows the sexes to utilize different ecological niches thereby reducing intraspecific competition 79 For example females of nearly all shorebirds have longer bills than males of the same species 80 and female American avocets have beaks which are slightly more upturned than those of males 81 Males of the larger gull species have bigger stouter beaks than those of females of the same species and immatures can have smaller more slender beaks than those of adults 82 Many hornbills show sexual dimorphism in the size and shape of both beaks and casques and the female huia s slim decurved bill was nearly twice as long as the male s straight thicker one 10 p48 Color can also differ between sexes or ages within a species Typically such a color difference is due to the presence of androgens For example in house sparrows melanins are produced only in the presence of testosterone castrated male house sparrows like female house sparrows have brown beaks Castration also prevents the normal seasonal color change in the beaks of male black headed gulls and indigo buntings 83 Development EditThe beak of modern birds has a fused premaxillary bone which is modulated by the expression of Fgf8 gene in the frontonasal ectodermal zone during embryonic development 84 The shape of the beak is determined by two modules the prenasal cartilage during early embryonic stage and the premaxillary bone during later stages Development of the prenasal cartilage is regulated by genes Bmp4 and CaM while that of the premaxillary bone is controlled by TGFbllr b catenin and Dickkopf 3 85 86 TGFbllr codes for a serine threonine protein kinase that regulates gene transcription upon ligand binding previous work has highlighted its role in mammalian craniofacial skeletal development 87 b catenin is involved in the differentiation of terminal bone cells Dickkopf 3 codes for a secreted protein also known to be expressed in mammalian craniofacial development The combination of these signals determines beak growth along the length depth and width axes Reduced expression of TGFbllr significantly decreased the depth and length of chicken embryonic beak due to the underdevelopment of the premaxillary bone 88 Contrarily an increase in Bmp4 signaling would result in a reduced premaxillary bone due to the overdevelopment of the prenasal cartilage which takes up more mesenchymal cells for cartilage instead of bone formation 85 86 Functions Edit source source source source source source source source source source Three barn owls threatening an intruder Barn owl threat displays usually include hissing and bill snapping as here The platypus uses its bill to navigate underwater detect food and dig The bill contains receptors that help detect prey Birds may bite or stab with their beaks to defend themselves 89 Some species use their beaks in displays of various sorts As part of his courtship for example the male garganey touches his beak to the blue speculum feathers on his wings in a fake preening display and the male Mandarin duck does the same with his orange sail feathers 77 p20 A number of species use a gaping open beak in their fear and or threat displays Some augment the display by hissing or breathing heavily while others clap their beak The platypus uses its bill to navigate underwater detect food and dig The bill contains electroreceptors and mechanoreceptors causing muscular contractions to help detect prey It is one of the few species of mammals to use electroreception 90 91 Preening Edit Main article Preening The beak of birds plays a role in removing skin parasites ectoparasites such as lice It is mainly the tip of the beak that does this Studies have shown that inserting a bit to stop birds from using the tip results in increased parasite loads in pigeons 92 Birds that have naturally deformed beaks have also been noted to have higher levels of parasites 93 94 95 96 It is thought that the overhang at the end of the top portion of the beak that is the portion that begins to curve downwards slides against the lower beak to crush parasites 92 This overhang of the beak is thought to be under stabilising natural selection Very long beaks are thought to be selected against because they are prone to a higher number of breaks as has been demonstrated in rock pigeons 97 Beaks with no overhang would be unable to effectively remove and kill ectoparasites as mentioned above Studies have supported there is a selection pressure for an intermediate amount of overhang Western Scrub Jays who had more symmetrical bills i e those with less of an overhang were found to have higher amounts of lice when tested 98 The same pattern has been seen in surveys of Peruvian birds 99 Additionally because of the role beaks play in preening this is evidence for coevolution of the beak overhang morphology and body morphology of parasites Artificially removing the ability to preen in birds followed by readdition of preening ability was shown to result in changes in body size in lice Once the ability of the birds to preen was reintroduced the lice were found to show declines in body size suggesting they may evolve in response to preening pressures from birds 92 who could respond in turn with changes in beak morphology 92 Communication Edit A number of species including storks some owls frogmouths and the noisy miner use bill clapping as a form of communication 77 p83 Heat exchange Edit Studies have shown that some birds use their beaks to rid themselves of excess heat The toco toucan which has the largest beak relative to the size of its body of any bird species is capable of modifying the blood flow to its beak This process allows the beak to work as a transient thermal radiator reportedly rivaling an elephant s ears in its ability to radiate body heat 100 Measurements of the bill sizes of several species of American sparrows found in salt marshes along the North American coastlines show a strong correlation with summer temperatures recorded in the locations where the sparrows breed latitude alone showed a much weaker correlation By dumping excess heat through their bills the sparrows are able to avoid the water loss which would be required by evaporative cooling an important benefit in a windy habitat where freshwater is scarce 101 Several ratites including the common ostrich the emu and the southern cassowary use various bare parts of their bodies including their beaks to dissipate as much as 40 of their metabolic heat production 102 Alternately studies have shown that birds from colder climates higher altitudes or latitudes and lower environmental temperatures have smaller beaks lessening heat loss from that structure 103 Billing Edit When billing northern gannets raise their beaks high and clatter them against each other During courtship mated pairs of many bird species touch or clasp each other s bills Termed billing also nebbing in British English 104 this behavior appears to strengthen pair bonding 105 The amount of contact involved varies among species Some gently touch only a part of their partner s beak while others clash their beaks vigorously together 106 Gannets raise their bills high and repeatedly clatter them the male puffin nibbles at the female s beak the male waxwing puts his bill in the female s mouth and ravens hold each other s beaks in a prolonged kiss 107 Billing can also be used as a gesture of appeasement or subordination Subordinate Canada jay routinely bill more dominant birds lowering their body and quivering their wings in the manner of a young bird food begging as they do so 108 A number of parasites including rhinonyssids and Trichomonas gallinae are known to be transferred between birds during episodes of billing 109 110 Use of the term extends beyond avian behavior billing and cooing in reference to human courtship particularly kissing has been in use since Shakespeare s time 111 and derives from the courtship of doves 112 Beak trimming EditMain article Debeaking Because the beak is a sensitive organ with many sensory receptors beak trimming sometimes referred to as debeaking is acutely painful 113 to the birds it is performed on It is nonetheless routinely done to intensively farmed poultry flocks particularly laying and broiler breeder flocks because it helps reduce the damage the flocks inflict on themselves due to a number of stress induced behaviors including cannibalism vent pecking and feather pecking A cauterizing blade or infrared beam is used to cut off about half of the upper beak and about a third of the lower beak Pain and sensitivity can persist for weeks or months after the procedure and neuromas can form along the cut edges Food intake typically decreases for some period after the beak is trimmed However studies show that trimmed poultry s adrenal glands weigh less and their plasma corticosterone levels are lower than those found in untrimmed poultry indicating that they are less stressed overall 113 A similar but separate practice usually performed by an avian veterinarian or an experienced birdkeeper involves clipping filing or sanding the beaks of captive birds for health purposes in order to correct or temporarily alleviate overgrowths or deformities and better allow the bird to go about its normal feeding and preening activities 114 Amongst raptor keepers this practice is commonly known as coping 115 Bill tip organ Edit Kiwis have a probing bill that allows them to detect motion The bill tip organ is a region found near the tip of the bill in several types of birds that forage particularly by probing The region has a high density of nerve endings known as the corpuscles of Herbst This consists of pits in the bill surface which in the living bird is occupied by cells that sense pressure changes The assumption is that this allows the bird to perform remote touch which means that it can detect movements of animals which the bird does not directly touch Bird species known to have a bill tip organ include ibises shorebirds of the family Scolopacidae and kiwis 116 There is a suggestion that across these species the bill tip organ is better developed among species foraging in wet habitats water column or soft mud than in species using a more terrestrial foraging However it has been described in terrestrial birds too including parrots who are known for their dextrous extractive foraging techniques Unlike probing foragers the tactile pits in parrots are embedded in the hard keratin or rhamphotheca of the bill rather than the bone and along the inner edges of the curved bill rather than being on the outside of the bill 117 See also EditBird anatomy Anatomy of birds Rostrum anatomy Anatomy term Snout Extended part of an animal s mouthFootnotes Edit For an explanation of desmognathous aegithognathous etc with images see Catalogue of Species 1891 via Archive org References Edit Partington Charles Frederick 1835 The British cyclopaeedia of natural history Combining a scientific classification of animals plants and minerals Orr amp Smith p 417 a b c Proctor Noble S Lynch Patrick J 1998 Manual of Ornithology Avian structure and function New Haven CT Yale University Press p 66 ISBN 978 0 300 07619 6 Beak Merriam Webster Retrieved 1 July 2016 a b c d e f Coues Elliott 1890 Handbook of Field and General Ornithology London UK Macmillan and Co pp 1 147 151 152 155 OCLC 263166207 a b c d e f g h i j k Gill Frank B 1995 Ornithology 2nd ed New York NY W H Freeman and Company pp 149 427 428 ISBN 978 0 7167 2415 5 Seki Yasuaki Bodde Sara G Meyers Marc A 2009 Toucan and hornbill beaks A comparative study PDF Acta Biomaterialia 6 2 331 343 doi 10 1016 j actbio 2009 08 026 PMID 19699818 Archived from the original PDF on 2012 04 02 Olsen A M 3 7 Jan 2012 Beyond the beak Modeling avian cranial kinesis and the evolution of bird skull shapes Society for Integrative amp Comparative Biology Charleston South Carolina Mayr Gerald 2005 A new eocene Chascacocolius like mousebird Aves Coliiformes with a remarkable gaping adaptation PDF Organisms Diversity amp Evolution 5 3 167 171 doi 10 1016 j ode 2004 10 013 Kaiser Gary W 2007 The Inner Bird Anatomy and Evolution Vancouver BC UBC Press p 19 ISBN 978 0 7748 1343 3 a b c d e f g h i j k l m n o p q r s Campbell Bruce Lack Elizabeth eds 1985 A Dictionary of Birds Carlton England T and A D Poyser ISBN 978 0 85661 039 4 Girling 2003 p 4 Samour 2000 p 296 Bonser R H amp Witter M S 1993 Indentation hardness of the bill keratin of the European starling PDF The Condor 95 3 736 738 doi 10 2307 1369622 JSTOR 1369622 Beddard Frank E 1898 The structure and classification of birds London UK Longmans Green and Co p 5 Pitocchelli Jay John F Piatt Harry R Carter 2003 Variation in plumage molt and morphology of the Whiskered Auklet Aethia pygmaea in Alaska Journal of Field Ornithology 74 1 90 98 doi 10 1648 0273 8570 74 1 90 S2CID 85982302 Knopf F L 1974 Schedule of presupplemental molt of white pelicans with notes on the bill horn PDF Condor 77 3 356 359 doi 10 2307 1366249 JSTOR 1366249 Chernova O F Fadeeva E O 2009 The peculiar architectonics of contour feathers of the emu Dromaius novaehollandiae Struthioniformes Doklady Biological 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Belmont CA Thomson Brooks Cole p 1255 ISBN 978 0 495 01033 3 Newman Kenneth B 2000 Newman s birds by colour Struik p 14 ISBN 978 1 86872 448 2 Wheelwright N T 1985 Fruit size gape width and the diets of fruit eating birds PDF Ecology 66 3 808 818 doi 10 2307 1940542 JSTOR 1940542 Archived from the original PDF on 2016 04 08 Retrieved 2013 10 31 Soler J J Aviles J M 2010 Halsey Lewis George ed Sibling competition and conspicuousness of nestling gapes in altricial birds A comparative study PLoS ONE 5 5 e10509 Bibcode 2010PLoSO 510509S doi 10 1371 journal pone 0010509 PMC 2865545 PMID 20463902 Hauber Mark amp Rebecca M Kilner 2007 Coevolution communication and host chick mimicry in parasitic finches who mimics whom PDF Behav Ecol Sociobiol 61 4 497 503 doi 10 1007 s00265 006 0291 0 S2CID 44030487 Archived from the original PDF on 2012 03 20 Hunt Sarah Kilner Rebecca M Langmore Naomi E Bennett Andrew T D 2003 Conspicuous ultravioletrich mouth colours in begging chicks Biology Letters 270 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integrative approach to major transitions in vertebrate history DEVELOPMENTAL MECHANISM FOR ORIGIN OF BIRD BEAK Evolution 69 7 1665 1677 doi 10 1111 evo 12684 PMID 25964090 S2CID 205124061 a b Abzhanov Arhat Protas Meredith Grant B Rosemary Grant Peter R Tabin Clifford J 2004 09 03 Bmp4 and Morphological Variation of Beaks in Darwin s Finches Science 305 5689 1462 1465 Bibcode 2004Sci 305 1462A doi 10 1126 science 1098095 ISSN 0036 8075 PMID 15353802 S2CID 17226774 a b Abzhanov Arhat Kuo Winston P Hartmann Christine Grant B Rosemary Grant Peter R Tabin Clifford J August 2006 The calmodulin pathway and evolution of elongated beak morphology in Darwin s finches Nature 442 7102 563 567 Bibcode 2006Natur 442 563A doi 10 1038 nature04843 ISSN 0028 0836 PMID 16885984 S2CID 2416057 Ito Yoshihiro Yeo Jae Yong Chytil Anna Han Jun Bringas Pablo Nakajima Akira Shuler Charles F Moses Harold L Chai Yang 2003 11 01 Conditional inactivation of Tgfbr2 in cranial neural crest causes cleft palate and calvaria defects Development 130 21 5269 5280 doi 10 1242 dev 00708 ISSN 1477 9129 PMID 12975342 S2CID 10925294 Mallarino R Grant P R Grant B R Herrel A Kuo W P Abzhanov A 2011 03 08 Two developmental modules establish 3D beak shape variation in Darwin s finches Proceedings of the National Academy of Sciences 108 10 4057 4062 Bibcode 2011PNAS 108 4057M doi 10 1073 pnas 1011480108 ISSN 0027 8424 PMC 3053969 PMID 21368127 Samour 2000 p 7 Patel Meera Fall 2007 Platypus electroreception Biology 342 Animal Behavior Portland OR Reed College Platypus LiveScience 4 August 2014 27572 a b c d Clayton deficient citation Lee deficient citation Tompkins deficient citation Brodie deficient citation September 1999 Reciprocal Natural Selection on Host Parasite Phenotypes PDF The American Naturalist 154 3 261 270 doi 10 1086 303237 hdl 10536 DRO DU 30056229 ISSN 1537 5323 PMID 10506542 S2CID 4369897 full citation needed Pomeroy D E February 1962 Birds with abnormal bills PDF British Birds 55 2 49 72 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0010 5422 2002 104 0675 iobsoe 2 0 co 2 hdl 1808 16618 ISSN 0010 5422 S2CID 32708877 Clayton D H Walther B A 2001 09 01 Influence of host ecology and morphology on the diversity of Neotropical bird lice Oikos 94 3 455 467 doi 10 1034 j 1600 0706 2001 940308 x ISSN 1600 0706 Tattersall Glenn J Andrade Denis V Abe Augusto S 24 July 2009 Heat Exchange from the Toucan Bill Reveals a Controllable Vascular Thermal Radiator Science 325 5949 468 470 Bibcode 2009Sci 325 468T doi 10 1126 science 1175553 PMID 19628866 S2CID 42756257 Greenbert Russell Danner Raymond Olsen Brian Luther David 14 July 2011 High summer temperature explains bill size variation in salt marsh sparrows Ecography online first 2 146 152 doi 10 1111 j 1600 0587 2011 07002 x Phillips Polly K Sanborn Allen F December 1994 An infrared thermographic study of surface temperature in three ratites Ostrich emu and double wattled cassowary Journal of Thermal Biology 19 6 423 430 doi 10 1016 0306 4565 94 90042 6 Evolution of bird 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Australia Veterinary Association 89 3 82 88 doi 10 1111 j 1751 0813 2010 00681 x PMID 21323655 Partridge Eric 2001 Shakespeare s bawdy 4 ed London UK Routledge Classics 2001 p 82 ISBN 978 0 415 25553 0 Burton Maurice Burton Robert 1980 The International Wildlife Encyclopedia Vol 12 New York NY Marshall Cavendish Corp p 1680 a b Grandin Temple 2010 Improving Animal Welfare A practical approach Oxfordshire UK CABI p 110 ISBN 978 1 84593 541 2 Foster amp Smith Bird Beaks Anatomy care and diseases Veterinary amp Aquatic Services Department Archived from the original on 4 June 2012 Retrieved 16 April 2012 a href Template Cite web html title Template Cite web cite web a CS1 maint uses authors parameter link Ash Lydia 2020 2004 Coping your Raptor The Modern Apprentice Archived from the original on 2005 04 06 Retrieved 16 April 2012 Cunningham Susan J Alley M R Castro I Potter M A Cunningham M Pyne M J 2010 Bill morphology or Ibises suggests a remote tactile sensory system for prey detection The Auk 127 2 308 316 doi 10 1525 auk 2009 09117 S2CID 85254980 Demery Zoe P Chappell J Martin G R 2011 Vision touch and object manipulation in Senegal parrots Poicephalus senegalus Proceedings of the Royal Society B 278 1725 3687 3693 doi 10 1098 rspb 2011 0374 PMC 3203496 PMID 21525059 Bibliography Edit Wikimedia Commons has media related to Beaks Armstrong Edward Allworthy 1965 Bird Display and Behaviour An introduction to the study of bird psychology New York NY Dover Publications LCCN 64013457 Campbell Bruce Lack Elizabeth eds 1985 A Dictionary of Birds Carlton England T and A D Poyser ISBN 978 0 85661 039 4 Coues Elliott 1890 Handbook of Field and General Ornithology London UK Macmillan and Co p 1 OCLC 263166207 Gilbertson Lance 1999 Zoology Lab Manual 4 ed New York NY McGraw Hill Companies ISBN 978 0 07 237716 3 Gill Frank B 1995 Ornithology 2 ed New York NY W H Freeman and Company ISBN 978 0 7167 2415 5 Girling Simon 2003 Veterinary Nursing of Exotic Pets Oxford UK Blackwell Publishing ISBN 978 1 4051 0747 1 Hill Geoffrey E 2010 National Geographic Bird Coloration Washington DC National Geographic ISBN 978 1 4262 0571 2 Howell Steve N G 2007 Gulls of the Americas New York NY Houghton Mifflin Company ISBN 978 0 618 72641 7 King Anthony Stuart McLelland John eds 1985 Form and Function in Birds Vol 3 London UK Academic Press ISBN 978 0 12 407503 0 Mullarney Killian Svensson Lars Zetterstrom Dan Grant Peter J 1999 Collins Bird Guide The Most Complete Field Guide to the Birds of Britain and Europe London UK Harper Collins ISBN 978 0 00 711332 3 Proctor Noble S Lynch Patrick J 1998 Manual of Ornithology Avian Structure and Function New Haven CT Yale University Press ISBN 978 0 300 07619 6 Rogers Lesley J Kaplan Gisela T 2000 Songs Roars and Rituals Communication in birds mammals and other animals Boston MA Harvard University Press ISBN 978 0 674 00827 4 Samour Jaime ed 2000 Avian Medicine London UK Mosby ISBN 978 0 7234 2960 9 Retrieved from https en wikipedia org w index php title Beak amp oldid 1148933157, wikipedia, wiki, book, books, library,

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