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SaintlyPrologue

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University of Guelph

G. Bedecarrats

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homeostasis thermoregulation animal science physiology

Summary

This lecture covers the concept of homeostasis and thermoregulation in animals, using examples to explain the integrated response involved in maintaining homeostasis. It explores the relationship between body functions and external adjustments. It also provides practical temperature information for different animal species.

Full Transcript

Homeostasis and Integration: Case of Thermoregulation ANSC 3080 G. Bedecarrats Learning Objectives Explain the general concept of homeostatic control systems Using thermoregulation as an example, explain the integrated response involved in maintaining h...

Homeostasis and Integration: Case of Thermoregulation ANSC 3080 G. Bedecarrats Learning Objectives Explain the general concept of homeostatic control systems Using thermoregulation as an example, explain the integrated response involved in maintaining homeostasis What major body systems/functions are important? What controls the response? Homeostasis Definition: Maintenance of a constant (normal) internal environment Coordinated responses of organs/systems that automatically compensate for environmental changes Body temperature, blood pressure, O2/CO2 levels Coordinated response = more than 1 system Automatically: involves autonomic nervous system (reflexes) 1 Body Temperature Mammals and birds are homeotherms Warm-blooded animals - maintain body temperature within narrow limits Low and high temperature NOT tolerated Species State Temp (°C) Dog 37.5-39.0 Cat 38.0-39.5 Horse 37.5-38.5 Dairy Cow Non-Pregnant 38.0-38.5 Dairy Cow Lactation 38.3-38.9 Sheep 38.4-39.5 Sow 38.5-39.0 Broiler Chicken Rapid Growth 40.5-42 Laying Hen Egg production 40.5-42 Core body temperature: Protects vital organs Measured by rectal insertion of thermometer Influenced by environment, exercise, metabolism Thermoneutral Zone  The thermoneutral zone is the ambient temperature at which no adjustment is needed  No additional energy required to maintain body temperature = perfect husbandry conditions  Critical temperatures (hot or cold) = energy required to maintain homeothermic condition (produce or actively dissipate heat) 2  Hyperthermia (heat stress): generally fatal, cells cannot function (enzymes and proteins denatured)  Hypothermia (cold stress): cells can survive freezing. However, blood circulation and respiration fail = death.  How can a horse survive heavy exercising?  How can a cow survive outdoors in summer and winter? Balance Between Heat Production and Heat Loss  In mammals and birds, heat comes mainly from body production = endothermic (not energy efficient)  Metabolism = conversion of nutrients to heat (energy), mainly in heart, liver, kidneys and brain  Growth and production (body factory)  Exercise: about 80% of energy produced is heat  Heat transported by the blood needs to be released in the environment. Four physical processes:  Radiation  Conduction  Convection  Evaporation/Condensation How is Extra-Heat Produced? Muscle activity: exposure to cold  shivering Rhythmic (15/sec) involuntary muscle contractions Antagonistic muscles contract simultaneously Nervous input No exercise = 100% energy goes to heat production Non-shivering thermogenesis:  metabolism Sympathetic nervous system results in secretion of catecholamines (adrenalin)   metabolism (calorigenic) especially from brown fat Thyroid hormones   metabolism 3 How is Extra-Heat Lost?  Under normal conditions, metabolic heat is removed from the core by the blood through the skin  Insulation property of the skin inversely proportional to the blood flow High heat loss Low heat loss Hair, plumage Mechanisms of Heat Transport  Gradient physical laws = transfer from high to low.  Radiation: electromagnetic radiation is emitted and absorbed; relative to the surface and temperature of the object/animal  Conduction: transfer through contact; depends on the conductivity (inverse of insulation). Animal  ground  Convection: transfer via moving air or water  Evaporation: very efficient, requires energy to break water molecules apart. Through skin and airways.  Passive evaporation: normal water loss  Sweating: active process under sympathetic nervous system. Also results in loss of ions.  Panting: rapid shallow breathing (not in horses or pigs)  Bathing: water absorb energy before evaporating Most of the time, all processes occur simultaneously. Type of animal (fur, size, etc…) also important. 4 Thermoregulation: System Components  Involves participation of numerous physiological systems  Automatic = reflex = sensor + integration + effectors  Thermoreceptors = nerve cells  Integration Center = hypothalamus: information compared to internal reference set points  Effectors  Neurons connected to muscles (somatic) for shivering  Sympathetic nervous system for blood flow, sweat gland and metabolism  Hormones: Hypothalamo- pituitary axis System Components continued Voluntary component: Hypothalamus connected to the cortex = exchange of information Change of behavioral response, put your jacket on! = cognitive behavior. Response to Heat  Heat receptors:  In the skin (below epidermis), in the body core (especially hypothalamus - sensitivity of 0.1°C), blood vessels, viscera  Information transferred through warm sensory fibers  Hypothalamus: activation of the heat-loss center (anterior)  Effectors:  Sympathetic vasoconstriction fibers slow down = vasodilatation  Sympathetic activity increase for evaporative heat loss: sweating, panting  Reduction of physical activity  Behavioral response: increased exposure area to air, seeking shade, wind 5 Sensitivity to Heat Depends on the animal and the external conditions (humidity level) Cattle and sheep very good Pigs very bad = little sweat, small mouth forpanting (transport at night preferred) In birds: air sac (extension to the lung) deep in body cavity = ventilation helps cooling Response to Cold  Cold receptors:  In the skin (below epidermis). In the body core (hypothalamus, blood vessels, viscera)  Information transferred through cold sensory fibers. Much more numerous than warm fibers  Hypothalamus: activation of heat-producing center (post.)  Effectors:  Reduction of heat loss: Sympathetic vasoconstriction fibers fire; Pili muscles from hair follicle contract; “Curl-up” position  Production of heat: Muscular contraction (shivering) by somatic motor system; Sympathetic and hormonal activity  (catecholamines, thyroid hormones) = metabolism  (especially in brown fat). 6 Adaptation Mechanisms To heat: Prolonged exposure to heat = lots of sweat. Increase in aldosterone (hormone) stimulates reabsorption of Na+ and Cl- from sweat glands Shedding To cold: Change of fur coat, increase in insulation properties (subcutaneous fat) Hibernation: voluntary decrease in core body temperature, followed by a rapid raise. Pathology  Fever:  Occurs by “resetting” hypothalamic thermostat to higher level  Response is equivalent to a decrease in temperature  Caused by pyrogens released during infection and tissue damage  Hyperthermia:  Happens when temperature exceeds the regulating capability. Heat production exceeds heat loss. Convulsions, nausea, loss of consciousness, death.  Excessive exercise, exposure to high temperatures  Hypothermia:  Heat loss exceeds heat production capability. Slow nervous activity, muscular failure (cardiac, pulmonary), death  Critical with newborns 7

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