skeleton, showing elongated limb bones and extra joints. Red marks indicate bones which have been substantially elongated in frogs and joints which have become mobile. Blue indicates joints and bones which have not been modified or only somewhat elongated. Frogs have no tail, except as larvae. Most frogs have long hind legs, elongated ankle bones, webbed toes, no claws, large eyes, and either smooth or warty skin. They have short vertebral columns, with no more than 10 free vertebrae and fused tailbones (urostyle or coccyx). Frogs range in size from a
snout–vent length of (the
Paedophryne amauensis of
Papua New Guinea) to about (the
goliath frog (
Conraua goliath) of central Africa, which is about ). Some extinct prehistoric species were even larger.
Feet and legs A frog's foot and leg structure is related to its habitat. Across species, these structures vary based on whether the species lives primarily on the ground, in water, in trees, or in burrows. Adult anurans have four fingers on the hands and five toes on the feet, but the smallest species often have hands and feet where some of the digits are vestigial. Frogs must be able to move quickly through their environment to catch prey and escape predators, and numerous adaptations help them to do so. Most frogs are either proficient jumpers or descend from ancestors that were, with much of the
musculoskeletal morphology modified for this purpose. The tibia, fibula, and
tarsals have been fused into a single strong
bone, as have the radius and ulna in the fore limbs (which must absorb the impact on landing). The
metatarsals have become elongated to add to the leg length, allowing frogs to push against the ground for a longer period on take-off. The
ilium has elongated and formed a mobile joint with the
sacrum which, in specialist jumpers such as ranids and hylids, functions as an additional limb joint to further power the leaps. The tail vertebrae have fused into a urostyle which is retracted inside the pelvis. This enables frogs to transfer force from the legs to the body during a leap. The completely aquatic
African dwarf frog (
Hymenochirus sp.) has fully webbed toes, whereas those of
White's tree frog (
Litoria caerulea), an arboreal species, are only a quarter or half webbed. Exceptions include
flying frogs in the
Hylidae and
Rhacophoridae, which also have fully webbed toes used in gliding.
Arboreal frogs have pads located on the ends of their toes to help grip vertical surfaces. These are not suction pads, the surface consisting instead of columnar cells with flat tops with small gaps between them lubricated by mucous glands. When the frog applies pressure, the cells adhere to irregularities on the surface and the grip is maintained through
adhesion. This allows the frog to climb on smooth surfaces, but the system does not function efficiently when the pads are excessively wet. In many arboreal frogs, a small "intercalary structure" on each toe increases the surface area touching the
substrate. Furthermore, many arboreal frogs have hip joints that allow both hopping and walking. Some frogs that live high in trees even possess an elaborate degree of webbing between their toes. This allows the frogs to "parachute" or make a controlled glide from one position in the canopy to another. Ground-dwelling frogs generally lack the adaptations of aquatic and arboreal frogs. Most have smaller toe pads, if any, and little webbing. Some burrowing frogs such as
Couch's spadefoot (
Scaphiopus couchii) have a flap-like toe extension on the hind feet, a
keratinised
tubercle often referred to as a spade, that helps them to burrow. Sometimes during the tadpole stage, one of the developing rear legs is eaten by a predator such as a
dragonfly nymph. In some cases, the full leg still grows, but in others it does not, although the frog may still live out its normal lifespan with only three limbs. Occasionally, a parasitic
flatworm (
Ribeiroia ondatrae) digs into the rear of a tadpole, causing a rearrangement of the limb bud cells and the frog develops one or more extra legs. (
Rana pipiens) moulting and eating its skin
Skin A frog's skin is protective, has a respiratory function, can absorb water, and helps control body temperature. It has many glands, particularly on the head and back, which often exude distasteful and toxic substances (
granular glands). The secretion is often sticky and helps keep the skin moist, protects against the entry of moulds and bacteria, and makes the animal slippery and more able to escape from predators. The skin is shed every few weeks. It usually splits down the middle of the back and across the belly, and the frog pulls its arms and legs free. The sloughed skin is then worked towards the head where it is quickly eaten. Being cold-blooded, frogs have to adopt suitable behaviour patterns to regulate their temperature. To warm up, they can move into the sun or onto a warm surface; if they overheat, they can move into the shade or adopt a stance that exposes the minimum area of skin to the air. This posture is also used to prevent water loss and involves the frog squatting close to the substrate with its hands and feet tucked under its chin and body. The colour of a frog's skin is used for thermoregulation. In cool damp conditions, the colour will be darker than on a hot dry day. The
grey foam-nest tree frog (
Chiromantis xerampelina) is even able to turn white to minimise the chance of overheating. Many frogs are able to absorb water and oxygen directly through the skin, especially around the pelvic area, but the permeability of a frog's skin can also result in water loss. Glands located all over the body exude mucus which helps keep the skin moist and reduces evaporation. Some glands on the hands and chest of males are specialised to produce sticky secretions to aid in
amplexus. Similar glands in tree frogs produce a glue-like substance on the adhesive discs of the feet. Some arboreal frogs reduce water loss by having a waterproof layer of skin, and several South American species coat their skin with a waxy secretion. Other frogs have adopted behaviours to conserve water, including becoming
nocturnal and resting in a water-conserving position. Some frogs may also rest in large groups with each frog pressed against its neighbours. This reduces the amount of skin exposed to the air or a dry surface, and thus reduces water loss. The male
hairy frog (
Trichobatrachus robustus) has
dermal papillae projecting from its lower back and thighs, giving it a bristly appearance. These contain blood vessels and are thought to increase the area of the skin available for respiration. (
Assa darlingtoni) camouflaged against leaf litter (
Lithobates sylvaticus) uses
disruptive coloration. Some species have
bony plates embedded in the skin, a trait that appears to have evolved independently several times. In certain other species, the skin at the top of the head is compacted and the connective tissue of the dermis is co-ossified with the bones of the skull (
exostosis).
Camouflage is a common defensive mechanism in frogs. Features such as warts and
skin folds are usually on ground-dwelling frogs, for whom smooth skin would not provide such effective camouflage. Certain frogs change colour between night and day, as light and moisture stimulate the pigment cells and cause them to expand or contract. Some are even able to control their skin texture. The
Pacific tree frog (
Pseudacris regilla) has green and brown morphs, plain or spotted, and changes colour depending on the time of year and general background colour. The
Wood frog (
Lithobates sylvaticus) uses
disruptive coloration including black eye markings similar to voids between leaves, bands of the dorsal skin (dorsolateral dermal plica) similar to a leaf
midrib as well as stains, spots and leg stripes similar to fallen leaf features.
Respiration and circulation Like other amphibians,
oxygen can pass through their highly permeable skins. This unique feature allows them to remain in places without access to the air, respiring through their skins. Ribs are generally absent, so the lungs are filled by
buccal pumping and a frog deprived of its lungs can maintain its body functions without them. Frogs have three-chambered
hearts, a feature they share with
lizards. Oxygenated blood from the lungs and de-oxygenated blood from the
respiring tissues enter the heart through separate
atria. When these chambers contract, the two blood streams pass into a common
ventricle before being pumped via a spiral valve to the appropriate vessel, the
aorta for oxygenated blood and
pulmonary artery for deoxygenated blood. Some species of frog have adaptations that allow them to survive in oxygen deficient water. The
Titicaca water frog (
Telmatobius culeus) is one such species and has wrinkly skin that increases its surface area to enhance gas exchange. It normally makes no use of its rudimentary lungs but will sometimes raise and lower its body rhythmically while on the lake bed to increase the flow of water around it.
Digestion and excretion Frogs have
maxillary teeth along their upper jaw which are used to hold food before it is swallowed. These teeth are very weak, and cannot be used to chew or catch and harm agile prey. Instead, the frog uses its sticky, cleft tongue to catch insects and other small moving prey. The tongue normally lies coiled in the mouth, free at the back and attached to the mandible at the front. It can be shot out and retracted at great speed. Some frogs have no tongue and just stuff food into their mouths with their hands. The food then moves through the oesophagus into the stomach where digestive enzymes are added and it is churned up. It then proceeds to the small intestine (duodenum and ileum) where most digestion occurs. Pancreatic juice from the pancreas, and bile, produced by the liver and stored in the gallbladder, are secreted into the small intestine, where the fluids digest the food and the nutrients are absorbed. The food residue passes into the large intestine where excess water is removed and the wastes are passed out through the
cloaca. Although adapted to terrestrial life, frogs resemble freshwater fish in their inability to conserve body water effectively. When they are on land, much water is lost by evaporation from the skin. The excretory system is similar to that of mammals and there are two
kidneys that remove nitrogenous products from the blood. Frogs produce large quantities of dilute urine in order to flush out toxic products from the kidney tubules. The nitrogen is excreted as
ammonia by tadpoles and aquatic frogs but mainly as
urea, a less toxic product, by most terrestrial adults. A few species of tree frog with little access to water excrete the even less toxic
uric acid.
Reproductive system In the male frog, the two
testes are attached to the kidneys and
semen passes into the kidneys through fine tubes called
efferent ducts. It then travels on through the ureters, which are consequently known as urinogenital ducts. There is no penis, and sperm is ejected from the cloaca directly onto the eggs as the female lays them. The ovaries of the female frog are beside the kidneys and the eggs pass down a pair of oviducts and through the cloaca to the exterior. The male frog has certain hormone-dependent
secondary sexual characteristics. These include the development of special pads on his thumbs in the breeding season, to give him a firm hold. The grip of the male frog during amplexus stimulates the female to release eggs, usually wrapped in jelly, as spawn. In many species the male is smaller and slimmer than the female. Males have vocal cords and make a range of croaks, particularly in the breeding season, and in some species they also have
vocal sacs to amplify the sound.
Sight The eyes of most frogs are located on either side of the head near the top and project outwards as hemispherical bulges. They provide
binocular vision over a field of 100° to the front and a total visual field of almost 360°. They may be the only part of an otherwise submerged frog to protrude from the water. Each eye has closable upper and lower lids and a
nictitating membrane which provides further protection, especially when the frog is swimming. Members of the aquatic family
Pipidae have the eyes located at the top of the head, a position better suited for detecting prey in the water above. more recent research has shown that frogs can see in colour, even in very low light.
Hearing '', with ear parts highlighted Frogs can hear both in the air and below water. They do not have
external ears; the eardrums (
tympanic membranes) are directly exposed or may be covered by a layer of skin and are visible as a circular area just behind the eye. The size and distance apart of the eardrums is related to the frequency and wavelength at which the frog calls. In some species such as the bullfrog, the size of the tympanum indicates the sex of the frog; males have tympani that are larger than their eyes while in females, the eyes and tympani are much the same size. A noise causes the tympanum to vibrate and the sound is transmitted to the middle and inner ear. The middle ear contains semicircular canals which help control balance and orientation. In the inner ear, the auditory hair cells are arranged in two areas of the cochlea, the basilar papilla and the amphibian papilla. The former detects high frequencies and the latter low frequencies. Because the cochlea is short, frogs use
electrical tuning to extend their range of audible frequencies and help discriminate different sounds. This arrangement enables detection of the territorial and breeding calls of their
conspecifics. In some species that inhabit arid regions, the sound of thunder or heavy rain may arouse them from a dormant state. Additionally, some species have been found to use man-made structures such as drain pipes for artificial amplification of their call. The
coastal tailed frog (
Ascaphus truei) lives in mountain streams in North America and does not vocalise. The main function of calling is for male frogs to attract mates. Males may call individually or there may be a chorus of sound where numerous males have converged on breeding sites. In many frog species, such as the
common tree frog (
Polypedates leucomystax), females reply to males' calls, which acts to reinforce reproductive activity in a breeding colony. Female frogs prefer males that produce sounds of greater intensity and lower frequency, attributes that stand out in a crowd. The rationale for this is thought to be that by demonstrating his prowess, the male shows his fitness to produce superior offspring. A different call is emitted by a male frog or unreceptive female when mounted by another male. This is a distinct chirruping sound and is accompanied by a vibration of the body. Tree frogs and some non-aquatic species have a rain call that they make on the basis of humidity cues prior to a shower. The
Pacific tree frog (
Pseudacris regilla) produces the
onomatopoeic "ribbit" often heard in films. Other renderings of frog calls into speech include "brekekekex koax koax", the call of the marsh frog (
Pelophylax ridibundus) in
The Frogs, an Ancient Greek comic drama by
Aristophanes. The calls of the
Concave-eared torrent frog (
Amolops tormotus) are unusual in many aspects. The males are notable for their varieties of calls where upward and downward frequency modulations take place. When they communicate, they produce calls that fall in the
ultrasound frequency range. The last aspect that makes this species of frog's calls unusual is that nonlinear acoustic phenomena are important components in their acoustic signals.
Torpor During extreme conditions, some frogs enter a state of
torpor and remain inactive for months. In colder regions, many species of frog
hibernate in winter. Those that live on land such as the
American toad (
Bufo americanus) dig a burrow and make a
hibernaculum in which to lie
dormant. Others, less proficient at digging, find a crevice or bury themselves in dead leaves. Aquatic species such as the
American bullfrog (
Rana catesbeiana) normally sink to the bottom of the pond where they lie, semi-immersed in mud but still able to access the oxygen dissolved in the water. Their metabolism slows down and they live on their energy reserves. Some frogs such as the
wood frog,
moor frog, or
spring peeper can even survive being frozen. Ice crystals form under the skin and in the body cavity but the essential organs are protected from freezing by a high concentration of glucose. An apparently lifeless, frozen frog can resume respiration and its heartbeat can restart when conditions warm up. At the other extreme, the
striped burrowing frog (
Cyclorana alboguttata) regularly
aestivates during the hot, dry season in Australia, surviving in a dormant state without access to food and water for nine or ten months of the year. It burrows underground and curls up inside a protective
cocoon formed by its shed skin. Researchers at the
University of Queensland have found that during aestivation, the
metabolism of the frog is altered and the operational efficiency of the
mitochondria is increased. This means that the limited amount of energy available to the comatose frog is used in a more efficient manner. This survival mechanism is only useful to animals that remain completely unconscious for an extended period of time and whose energy requirements are low because they are cold-blooded and have no need to generate heat. Other research showed that, to provide these energy requirements, muscles atrophy, but hind limb muscles are preferentially unaffected. Frogs have been found to have upper critical temperatures of around 41 degrees Celsius. ==Locomotion==