By numerous observations upon
humans and other animals,
John Hunter showed that the essential difference between the so-called
warm-blooded and
cold-blooded animals lies in observed constancy of the temperature of the former, and the observed variability of the temperature of the latter. Almost all birds and mammals have a high temperature almost constant and independent of that of the surrounding air (
homeothermy). Almost all other animals display a variation of body temperature, dependent on their surroundings (
poikilothermy).
Brain control Thermoregulation in both ectotherms and endotherms is primarily controlled by the
preoptic area (POA) of the
anterior hypothalamus. In rats, neurons in the POA that express the
prostaglandin E receptor 3 (EP3) play a crucial role in thermoregulation by regulating body temperature in both directions. EP3-expressing neurons in the POA provide continuous (tonic) inhibitory signals with the transmitter
gamma-aminobutyric acid (GABA) to control
sympathetic output neurons in the
dorsomedial hypothalamus (DMH) and the rostral
raphe pallidus nucleus of the
medulla oblongata (rRPa). In a hot environment, the tonic inhibitory signals from EP3-expressing POA neurons are augmented to suppress sympathetic output. This results in suppressed heat production and dilated skin blood vessels, the latter of which promote heat loss from the body surface. In a cold environment, the tonic inhibition from EP3-expressing POA neurons is attenuated to increase (disinhibit) sympathetic output. This results in increased heat production and constricted skin blood vessels to reduce heat loss. The tonic inhibition from EP3-expressing POA neurons is also attenuated by an action of
prostaglandin E2 (PGE2) to induce
fever.
In birds and mammals its arms to cool down In cold environments, birds and mammals employ the following adaptations and strategies to minimize heat loss: • Using small smooth muscles (
arrector pili in mammals), which are attached to feather or hair shafts; this distorts the surface of the skin making feather/hair shaft stand erect (called
goose bumps or goose pimples) which slows the movement of air across the skin and minimizes heat loss. • Increasing body size to more easily maintain core body temperature (warm-blooded animals in cold climates tend to be larger than similar species in warmer climates (see
Bergmann's rule)) • Having the ability to store energy as fat for
metabolism • Have shortened extremities • Have
countercurrent blood flow in extremities – this is where the warm arterial blood travelling to the limb passes the cooler venous blood from the limb and heat is exchanged warming the venous blood and cooling the arterial (e.g.,
Arctic wolf or penguins) In warm environments, birds and mammals employ the following adaptations and strategies to maximize heat loss: • Behavioural adaptations like living in burrows during the day and being nocturnal • Evaporative cooling by perspiration and panting or
urohidrosis in the case of birds. • Storing fat reserves in one place (e.g., camel's hump) to avoid its insulating effect • Elongated, often vascularized extremities to conduct body heat to the air In humans of human thermoregulation. As in other mammals, thermoregulation is an important aspect of human
homeostasis. Most body heat is generated in the deep organs, especially the liver, brain, and heart, and in contraction of skeletal muscles. Humans have been able to adapt to a great diversity of climates, including hot humid and hot arid. High temperatures pose serious stresses for the human body, placing it in great danger of injury or even death. For example, one of the most common reactions to hot temperatures is heat exhaustion, which is an illness that could happen if one is exposed to high temperatures, resulting in some symptoms such as dizziness, fainting, or a rapid heartbeat. For humans,
adaptation to varying climatic conditions includes both physiological mechanisms resulting from
evolution and behavioural mechanisms resulting from conscious cultural adaptations. The physiological control of the body's core temperature takes place primarily through the hypothalamus, which assumes the role as the body's "thermostat". This organ possesses control mechanisms as well as key temperature sensors, which are connected to nerve cells called thermoreceptors. Thermoreceptors come in two subcategories; ones that respond to cold temperatures and ones that respond to warm temperatures. Scattered throughout the body in both peripheral and central nervous systems, these nerve cells are sensitive to changes in temperature and are able to provide useful information to the hypothalamus through the process of negative feedback, thus maintaining a constant core temperature. There are four avenues of heat loss: evaporation, convection, conduction, and radiation. If skin temperature is greater than that of the surrounding air temperature, the body can lose heat by convection and conduction. However, if air temperature of the surroundings is greater than that of the skin, the body
gains heat by convection and conduction. In such conditions, the only means by which the body can rid itself of heat is by evaporation. So, when the surrounding temperature is higher than the skin temperature, anything that prevents adequate evaporation will cause the internal body temperature to rise. During intense physical activity (e.g. sports), evaporation becomes the main avenue of heat loss. Humidity affects thermoregulation by limiting sweat evaporation and thus heat loss.
In reptiles Thermoregulation is also an integral part of a reptile's life, specifically lizards such as
Microlophus occipitalis and
Ctenophorus decresii who must change microhabitats to keep a constant body temperature. By moving to cooler areas when it is too hot and to warmer areas when it is cold, they can thermoregulate their temperature to stay within their necessary bounds. ==In plants==