Generating and conserving heat ) and an ectothermic animal (
reptile) as a function of core temperature Many endotherms have a larger amount of
mitochondria per
cell than ectotherms. This enables them to generate heat by increasing the rate at which they metabolize
fats and
sugars. Accordingly, to sustain their higher metabolism, endothermic animals typically require several times as much food as ectothermic animals do, and usually require a more sustained supply of metabolic fuel. In many endothermic animals, a controlled temporary state of
hypothermia conserves energy by permitting the body temperature to drop nearly to ambient levels. Such states may be brief, regular
circadian cycles called
torpor, or they might occur in much longer, even seasonal, cycles called
hibernation. The body temperatures of many small birds (e.g.
hummingbirds) and small mammals (e.g.
tenrecs) fall dramatically during daily inactivity, such as nightly in
diurnal animals or during the day in
nocturnal animals, thus reducing the energy cost of maintaining body temperature. Less drastic intermittent reduction in body temperature also occurs in other larger endotherms; for example human metabolism also slows down during sleep, causing a drop in core temperature, commonly of the order of 1 degree Celsius. There may be other variations in temperature, usually smaller, either endogenous or in response to external circumstances or vigorous exertion, and either an increase or a drop. The resting human body generates about two-thirds of its heat through metabolism in internal organs in the thorax and abdomen, as well as in the brain. The brain generates about 16% of the total heat produced by the body. Heat loss is a major threat to smaller creatures, as they have a larger ratio of
surface area to volume. Small warm-blooded animals have
insulation in the form of
fur or
feathers. Aquatic warm-blooded animals, such as
seals, generally have deep layers of
blubber under the
skin and any
pelage (fur) that they might have; both contribute to their insulation.
Penguins have both feathers and blubber. Penguin feathers are scale-like and serve both for insulation and streamlining. Endotherms that live in very cold circumstances or conditions predisposing to heat loss, such as polar waters, tend to have
specialised structures of blood vessels in their extremities that act as
heat exchangers. The veins are adjacent to the arteries full of warm blood. Some of the arterial heat is conducted to the cold blood and recycled back into the trunk. Birds, especially
waders, often have very well-developed
heat exchange mechanisms in their legs—those in the legs of
emperor penguins are part of the adaptations that enable them to spend months on Antarctic winter ice. In response to cold, many warm-blooded animals also reduce blood flow to the skin by
vasoconstriction to reduce heat loss. As a result, they blanch (become paler).
Avoiding overheating In
equatorial climates and during
temperate summers, overheating (
hyperthermia) is as great a threat as cold. In hot conditions, many warm-blooded animals increase heat loss by panting, which cools the animal by increasing water
evaporation in the breath, and/or flushing, increasing the blood flow to the skin so the heat will
radiate into the environment. Hairless and short-haired mammals, including humans and horses, also
sweat, since the evaporation of the water in sweat removes heat. Elephants keep cool by using their huge
ears like
radiators in automobiles. Their ears are thin and the
blood vessels are close to the skin, and flapping their ears to increase the airflow over them causes the blood to cool, which reduces their core body temperature when the blood moves through the rest of the circulatory system. ==Pros and cons of an endothermic metabolism==