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Chp 9 Thermal relations. Importance of Temperature. Temperature is a major factor affecting live of individuals. The ambient temperature is important in determining the animal metabolic rate the rate of food acquisition
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Importance of Temperature • Temperature is a major factor affecting live of individuals. • The ambient temperature is important in determining the animal metabolic rate the rate of food acquisition • The animal’s tissue temperature affects the biophysical processes, the efficiency of protein function, the viscosity of the cell fluids. • Definitions: • Ectotherms: animal temperature is dictated by environmental temperature poikilotherms because their temperature varies • Endotherms: animals that regulate their tissue tissue temperature • Homeotherms: use endogenous heat to thermoregulate • Heterothermy: difference in thermal realtions temporal if difference in time (ex: hibernation) or regional (body parts)
Temperature and Heat • Temperature: measure of the intensity of molecular movement within an object. • Heat: a form of energy due to the motion of the atoms forming the object. The amount of heat depends on the size of the object as well as its temperature • Heat moves by conduction or convection from high to low temperatures • The transfer of heat raises the temperature of the object receiving heat and vice versa • Thermal equilibrium = temperatures are the same
Heat transfer between animals and their environment Conduction: transfer of heat through atomic-molecular interactions by direct contact Convection: heat transferred through macroscopic motion flow = wind Radiation: all objects emit electromagnetic radiations which reflects against surface and warm them. Evaporation: the transformation of water from liquid to gas use energy loss of heat due to vaporization
Heat gain and loss in nature Radiant temperature of the sky The sky temperature is cooler than the earth and animals loss of energy from earth sky Solar radiation High and visible in the color spectrum heat gained by earth and animals
Poikilothermy - Ectothermy • Most common: all invertebrates and many vertebrates animal’s body temperature varies with the environment. • Terrestrial animals have the possibility to adjust their body temperature with behavior pattern (basking in the sun, resting underground..) behavior thermoregulation if body temperature is fairly constant • Eurythermal: can function over a wide range of temp • Stenothermal: function in a narrow range of temperature
Physiological responses in poikilotherms Acute response: rapid changes in metabolic rate follows an exponential function of body temperature Factor by which the MR increase when body temperature increase by 10 = temperature coefficient Q10 Q10= Rt/R(t-10) Around 2-3 for poikilotherms
Physiological responses in poikilotherms Chronic response: Exposure to different temperature will induce different metabolic response acclimation Initial response is a drop in metabolism Followed by an increase compensation Acclimation is due to a change in the number and activities of enzymes involved in metabolism.
Enzymes work faster at higher temperatures Lipids are more fluid at higher temperatures Effects of temperature at the biochemical levels
Core body temperature fairly constant Require regulation brain involvement Basal metabolic rate in these species is the metabolism rate when the animal is resting, fasting and at thermoneutral zone (TNZ) Metabolic rate increases in both cold and hot environments Why? Homeothermy in Mammals and Birds
Varies with species Some mouse species have a TNZ of 30-35oC Eskimo dogs: - 25oC to 30oC Thermoneutrality
http://physio1.utmem.edu/~blatteisc/index.php How does Fever relate to thermoregulation?
Often, the external temperatures are lower than the animal’s core body temp animal needs to energy to increase body temp The rate of loss varies with the animals: M = C(TB-TA ) C characterizes the animal’s ability to loose heat If I=1/C, I = insulation = measure an animal overall resistance to loose heat Main factors affecting I: Fur Posture others Thermoregulation: basis
A) the cooler the temperature, the higher the metabolic rate B) however, near the TNZ the metabolism does not fall to 0 but reach BMR The slope of the line is directly related to the level of insulation present in the animal Temperatures below thermoneutrality
Pelage: pilomotor response Plumage: pilomotor response Blood flow: vasoconstriction/dilation Posture Insulation
Metabolism Shivering Non shivering thermogenesis brown adipose tissue = brown fat Heat production
Behavorial defenses Insulation Body reactions such as panting, increased breathing rate Regional heterothermy Countercurrent exchange Evaporation: costly loss of water: ultimate line of defense Mammals and birds in hot environments
Three active mechanisms: Sweating: common in human loss of water and salts in plasma, absent in some species such as rodents, rabbits Panting: in birds, some mammals such as dogs Gular fluttering in birds Consequences: Animals adapt to changing temperatures, especially winter/summer acclimatization Evolutionary changes: Heat loss
A mean to escape the demands of homeothermy Torpor Controlled hypothermia Body temperature fall to close approximate ambient temperatures During winter hibernation During summer estivation During certain part of the day daily torpor Hibernation – Estivation – Daily torpor
Most likely the animal turn down its metabolism cooling Animals control their arousal Animals arouse from hypothermia once in a while during the hibernation Animals able to thermoregulate if the temperatures fall to levels too low Animals need to prepare for hibernation by storing fat Several mammal groups use hibernation to survive winter Rare in birds Hypothermia
Some species allow their temperature to decrease but not to ambient temperature Chickadee’s temperature decrease by 7oC Bears temperatures reach31-33oC What are the advantages of such process? Compared to no hypothermia Compared to full hypothermia Controlled hypothermia
Most fishes are poilokilotherm. However, larger predator fishes such as some sharks and tunas have muscles which have a higher temperature than the body They need to swim vigorously in order to catch fast preys They have: A higher metabolic rate in these muscles heat production However, in order not to loose it through blood circulation presence of a counter-current mechanism. Warm-bodied fishes
At rest, not enough heat is produced to warm up the insect Heat is produced by muscles during flight Temporal and spatial heterothermy: Endothermy when active only and in the thorax muscles Ex: sphinx moth, bumble bee (the flight muscles can be used for shivering) Endothermy in Insects
The higher the temperature, the more efficient the flying the more energy and heat produced They thermoregulate by controlling blood circulation from thorax to abdomen, by varying the degree of body insulation and by controlling muscle activity Ex: Bumble bee warm themselves before being able to fly (sun exposure and shivering). Then, flight can maintain the warmth What’s a mosquito to do in order to fly? It has a large body surface and very low weight (muscles). It cannot produce much heat and loose it fast Endothermy in insects