Thermoregulatory responses to thermal stimulation of the preoptic anterior hypothalamus in the red fox (Vulpes vulpes)

Thermoregulatory responses to thermal stimulation of the preoptic anterior hypothalamus in the red fox (Vulpes vulpes)

The preoptic anterior hypothalamus (POAH) thermoregulatory controller can be characterized by two types of control, an adjustable setpoint temperature and changing POAH thermal sensitivity. Setpoint temperatures for shivering (Tshiver) and panting (Tpant) both increased with decreasing ambient tempe...

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Bibliographic Details
Published in:Comparative biochemistry and physiology. Part A, Physiology Vol. 109; no. 3; p. 557
Main Authors: Klir, J J, Heath, J E
Format: Journal Article
Language:English
Published: United States 01-11-1994
Subjects:
Acepromazine - pharmacology
Animals
Basal Metabolism - drug effects
Body Temperature Regulation - drug effects
Body Temperature Regulation - physiology
Cold Temperature
Foxes - physiology
Hot Temperature
Male
Pentobarbital - pharmacology
Preoptic Area - drug effects
Preoptic Area - metabolism
Preoptic Area - physiology
Regression Analysis
Respiratory Mechanics - physiology
Shivering - physiology
Skin Temperature - physiology
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Summary:The preoptic anterior hypothalamus (POAH) thermoregulatory controller can be characterized by two types of control, an adjustable setpoint temperature and changing POAH thermal sensitivity. Setpoint temperatures for shivering (Tshiver) and panting (Tpant) both increased with decreasing ambient temperature (Ta), and decreased with increasing Ta. The POAH controller is twice as sensitive to heating as to cooling. Metabolic rate (MR) increased during both heating and cooling of the POAH. Resting temperature of the POAH was lower than internal body temperature (Tb) at all temperatures. This indicates the presence of some form of brain cooling mechanism. Decreased Tb during POAH heating was a result of increased heat dissipation, while higher Tb during POAH cooling was a result of increased heat production and reduced heat dissipation. The surface temperature responses indicated that foxes can actively control heat flow from body surface. Such control can be achieved by increased peripheral blood flow and vasodilation during POAH heating, and reduced peripheral blood flow and vasoconstriction during POAH cooling. The observed surface temperature changes indicated that the thermoregulatory vasomotor responses can occur within 1 min following POAH heating or cooling. Such a degree of regulation can be achieved only by central neural control. Only surface regions covered with relatively short fur are used for heat dissipation. These thermoregulatory effective surface areas account for approximately 33% of the total body surface area, and include the area of the face, dorsal head, nose, pinna, lower legs, and paws.
ISSN:1096-4940
DOI:10.1016/0300-9629(94)90194-5