Control of Body Temperature and Water Balance Chapter 25 Control of Body Temperature and Water Balance
Introduction During cold winters, bears are often dormant. Physiological processes aid homeostasis, keeping the body temperature about 5ºC below normal. Body fat and dense fur provide insulation. Blood flow to extremities is reduced. Nitrogen-containing wastes are metabolized differently. © 2012 Pearson Education, Inc. 2
Introduction Homeostasis is the maintenance of steady internal conditions despite fluctuations in the external environment. Examples of homeostasis include thermoregulation—the maintenance of internal temperature within narrow limits, osmoregulation—the control of the gain and loss of water and solutes, and excretion—the disposal of nitrogen-containing wastes. © 2012 Pearson Education, Inc. 3
Osmoregulation and Excretion Figure 25.0_1 Chapter 25: Big Ideas Figure 25.0_1 Chapter 25: Big Ideas Thermoregulation Osmoregulation and Excretion 4
Figure 25.0_2 Figure 25.0_2 Grizzly bears (Ursus arctos horribilis) 5
THERMOREGULATION © 2012 Pearson Education, Inc. 6
25.1 An animal’s regulation of body temperature helps maintain homeostasis Thermoregulation is the process by which animals maintain an internal temperature within a tolerable range and a form of homeostasis. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. The terms warm-blooded and cold-blooded are less precise than endotherm and ectotherm. Encourage students to discuss why the latter two terms are preferable. 2. Ask your students to explain the adaptive advantages of endothermy and ectothermy. You might prompt the discussion by noting that endotherms consume about 10 times as many calories as ectotherms of equivalent body mass. What advantages might be worth this additional “cost” for endotherms? 3. The heat generated by aerobic metabolism is analogous to the heat generated by the engine of an automobile. In both cases, the heat is a by-product of the process. In the winter, this excess heat helps keep the body and the interior of the car warm. In the summer, both the body and the automobile’s engine must work to keep from overheating. © 2012 Pearson Education, Inc. 7
25.1 An animal’s regulation of body temperature helps maintain homeostasis Ectothermic animals gain most of their heat from external sources and include many fish, most amphibians, lizards, and most invertebrates. Endothermic animals derive body heat mainly from their metabolism and include birds, mammals, a few reptiles and fish, and many insects. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. The terms warm-blooded and cold-blooded are less precise than endotherm and ectotherm. Encourage students to discuss why the latter two terms are preferable. 2. Ask your students to explain the adaptive advantages of endothermy and ectothermy. You might prompt the discussion by noting that endotherms consume about 10 times as many calories as ectotherms of equivalent body mass. What advantages might be worth this additional “cost” for endotherms? 3. The heat generated by aerobic metabolism is analogous to the heat generated by the engine of an automobile. In both cases, the heat is a by-product of the process. In the winter, this excess heat helps keep the body and the interior of the car warm. In the summer, both the body and the automobile’s engine must work to keep from overheating. © 2012 Pearson Education, Inc. 8
25.2 Heat is gained or lost in four ways Heat exchange with the environment may occur by conduction—the transfer of heat by direct contact, convection—the transfer of heat by movement of air or liquid past a surface, radiation—the emission of electromagnetic waves, or evaporation—the loss of heat from the surface of a liquid that is losing some of its molecules as a gas. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. © 2012 Pearson Education, Inc. 9
Evaporation Radiation Convection Conduction Figure 25.2 Figure 25.2 Mechanisms of heat exchange 10
25.3 Thermoregulation involves adaptations that balance heat gain and loss Five general categories of adaptations help animals thermoregulate. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. 4. Some students will be familiar with the type of foam insulation wrap surrounding interior pipes. These forms of insulation are especially necessary when hot- and cold-water pipes run parallel and in close proximity to each other. Without the insulation, heat would be easily transferred from hot-water to cold-water pipes, in a situation similar to countercurrent heat exchange systems in animals. © 2012 Pearson Education, Inc. 11
25.3 Thermoregulation involves adaptations that balance heat gain and loss Increased metabolic heat production occurs when hormonal changes boost the metabolic rate in birds and mammals, birds and mammals shiver, organisms increase their physical activity, and honeybees cluster and shiver. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. 4. Some students will be familiar with the type of foam insulation wrap surrounding interior pipes. These forms of insulation are especially necessary when hot- and cold-water pipes run parallel and in close proximity to each other. Without the insulation, heat would be easily transferred from hot-water to cold-water pipes, in a situation similar to countercurrent heat exchange systems in animals. © 2012 Pearson Education, Inc. 12
Figure 25.3_UN01 Figure 25.3_UN01 Honeybees clustering together and shivering to produce heat 13
25.3 Thermoregulation involves adaptations that balance heat gain and loss Insulation is provided by hair, feathers, and fat layers. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. 4. Some students will be familiar with the type of foam insulation wrap surrounding interior pipes. These forms of insulation are especially necessary when hot- and cold-water pipes run parallel and in close proximity to each other. Without the insulation, heat would be easily transferred from hot-water to cold-water pipes, in a situation similar to countercurrent heat exchange systems in animals. © 2012 Pearson Education, Inc. 14
25.3 Thermoregulation involves adaptations that balance heat gain and loss Circulatory adaptations include increased or decreased blood flow to skin and countercurrent heat exchange, with warm and cold blood flowing in opposite directions. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. 4. Some students will be familiar with the type of foam insulation wrap surrounding interior pipes. These forms of insulation are especially necessary when hot- and cold-water pipes run parallel and in close proximity to each other. Without the insulation, heat would be easily transferred from hot-water to cold-water pipes, in a situation similar to countercurrent heat exchange systems in animals. © 2012 Pearson Education, Inc. 15
Figure 25.3_1 Figure 25.3_1 Heat dissipation via ear flapping (convection) and via water spray (evaporative cooling) 16
Blood returning to body core in vein Figure 25.3_2 Blood returning to body core in vein Blood from body core in artery Blood from body core in artery 35 33C Blood returning to body core in vein 30 27 Figure 25.3_2 Countercurrent heat exchange 20 18 10 9 17
25.3 Thermoregulation involves adaptations that balance heat gain and loss Evaporative cooling may involve sweating, panting, or spreading saliva on body surfaces. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. 4. Some students will be familiar with the type of foam insulation wrap surrounding interior pipes. These forms of insulation are especially necessary when hot- and cold-water pipes run parallel and in close proximity to each other. Without the insulation, heat would be easily transferred from hot-water to cold-water pipes, in a situation similar to countercurrent heat exchange systems in animals. © 2012 Pearson Education, Inc. 18
25.3 Thermoregulation involves adaptations that balance heat gain and loss Behavioral responses are used by endotherms and ectotherms and include moving to the sun or shade, migrating, and bathing. Student Misconceptions and Concerns 1. The concept of homeostasis may be new to some students, who have never considered how organisms must adjust to subtle changes in environmental conditions. Analogies to other systems that engage in self-regulation, such as the water regulation of a toilet or the temperature regulation of a furnace, may help. 2. One role of the circulatory system rarely discussed is the transport of heat. Blood vessels near the surface of the body expand when we are overheated, releasing some of this excess to the environment. Conversely, during periods of exposure to cold, blood is shunted away from the skin to conserve heat. Teaching Tips 1. Have students list the many factors that affect heat gain and loss during periods of physical activity, then have them identify which of the four physical processes for exchanging heat are involved. The factors include (a) the person’s physical condition, (b) the level of physical activity, (c) the age of the person (younger people tend to have higher metabolic rates), (d) the person’s level of hydration (which in turn affects the amount of sweating and evaporative cooling), (e) the external level of humidity (higher levels decrease evaporative cooling), (f) the intensity of the wind (greater intensity promotes evaporative cooling), (g) the intensity of sunlight, and (h) the color of the person’s clothing (which affects the amount of light energy the body absorbs). 2. You can extend the exercise above by challenging your class to identify environmental conditions when it would be too hot to play an outdoor sport. That is, when as a parent or coach would you want to prevent practice or a game because it is dangerously hot? 3. As an alternative to the above, challenge students to identify a human example of each of the four physical processes that involve heat exchange with the environment and that promote thermoregulation. Or, to check student comprehension, describe such examples and challenge the class to match the examples to the correct terminology. 4. Some students will be familiar with the type of foam insulation wrap surrounding interior pipes. These forms of insulation are especially necessary when hot- and cold-water pipes run parallel and in close proximity to each other. Without the insulation, heat would be easily transferred from hot-water to cold-water pipes, in a situation similar to countercurrent heat exchange systems in animals. © 2012 Pearson Education, Inc. 19
OSMOREGULATION AND EXCRETION © 2012 Pearson Education, Inc. 20
25.4 Animals balance the level of water and solutes through osmoregulation Osmoregulation is the homeostatic control of the uptake and loss of water and solutes such as salt and other ions. Osmosis is one process whereby animals regulate their uptake and loss of fluids. Student Misconceptions and Concerns The idea that a freshwater fish never drinks can be conceptually challenging, especially for students who have heard the old saying “drinks like a fish”! Consider introducing your discussion of osmoregulation with this remarkable and seemingly counterintuitive fact to generate interest. Teaching Tips Students may better understand the challenges of osmoregulation in freshwater fish if they are reminded of what occurs when humans soak their hands in water. Students will likely recall that this causes the skin on their hands to wrinkle, and some may have noticed that their skin wrinkles even faster in soapy water. Skin absorbs water by osmosis (just as a freshwater fish gains water). Oils on our skin reduce the influx of water. Soapy water, which washes away these oils, speeds up the process. The wrinkling occurs because the skin can expand only in certain areas, creating puckers. © 2012 Pearson Education, Inc. 21
25.4 Animals balance the level of water and solutes through osmoregulation Osmoconformers have body fluids with a solute concentration equal to that of seawater, face no substantial challenges in water balance, and include many marine invertebrates. Student Misconceptions and Concerns The idea that a freshwater fish never drinks can be conceptually challenging, especially for students who have heard the old saying “drinks like a fish”! Consider introducing your discussion of osmoregulation with this remarkable and seemingly counterintuitive fact to generate interest. Teaching Tips Students may better understand the challenges of osmoregulation in freshwater fish if they are reminded of what occurs when humans soak their hands in water. Students will likely recall that this causes the skin on their hands to wrinkle, and some may have noticed that their skin wrinkles even faster in soapy water. Skin absorbs water by osmosis (just as a freshwater fish gains water). Oils on our skin reduce the influx of water. Soapy water, which washes away these oils, speeds up the process. The wrinkling occurs because the skin can expand only in certain areas, creating puckers. © 2012 Pearson Education, Inc. 22
25.4 Animals balance the level of water and solutes through osmoregulation Osmoregulators have body fluids whose solute concentrations differ from that of their environment, must actively regulate water movement, and include many land animals, freshwater animals such as trout, and marine vertebrates such as sharks. Student Misconceptions and Concerns The idea that a freshwater fish never drinks can be conceptually challenging, especially for students who have heard the old saying “drinks like a fish”! Consider introducing your discussion of osmoregulation with this remarkable and seemingly counterintuitive fact to generate interest. Teaching Tips Students may better understand the challenges of osmoregulation in freshwater fish if they are reminded of what occurs when humans soak their hands in water. Students will likely recall that this causes the skin on their hands to wrinkle, and some may have noticed that their skin wrinkles even faster in soapy water. Skin absorbs water by osmosis (just as a freshwater fish gains water). Oils on our skin reduce the influx of water. Soapy water, which washes away these oils, speeds up the process. The wrinkling occurs because the skin can expand only in certain areas, creating puckers. © 2012 Pearson Education, Inc. 23
25.4 Animals balance the level of water and solutes through osmoregulation Freshwater fish gain water by osmosis (mainly through gills), lose salt by diffusion to the more dilute environment, take in salt through their gills and in food, and excrete excess water in dilute urine. Student Misconceptions and Concerns The idea that a freshwater fish never drinks can be conceptually challenging, especially for students who have heard the old saying “drinks like a fish”! Consider introducing your discussion of osmoregulation with this remarkable and seemingly counterintuitive fact to generate interest. Teaching Tips Students may better understand the challenges of osmoregulation in freshwater fish if they are reminded of what occurs when humans soak their hands in water. Students will likely recall that this causes the skin on their hands to wrinkle, and some may have noticed that their skin wrinkles even faster in soapy water. Skin absorbs water by osmosis (just as a freshwater fish gains water). Oils on our skin reduce the influx of water. Soapy water, which washes away these oils, speeds up the process. The wrinkling occurs because the skin can expand only in certain areas, creating puckers. © 2012 Pearson Education, Inc. 24
Osmotic water gain through gills and other parts of body surface Figure 25.4_1 Osmotic water gain through gills and other parts of body surface Uptake of some ions in food Uptake of salt ions by gills Figure 25.4_1 Osmoregulation in a rainbow trout, a freshwater fish Excretion of large amounts of water in dilute urine from kidneys Fresh water 25
25.4 Animals balance the level of water and solutes through osmoregulation Saltwater fish lose water by osmosis from the gills and body surface, drink seawater, and use their gills and kidneys to excrete excess salt. Student Misconceptions and Concerns The idea that a freshwater fish never drinks can be conceptually challenging, especially for students who have heard the old saying “drinks like a fish”! Consider introducing your discussion of osmoregulation with this remarkable and seemingly counterintuitive fact to generate interest. Teaching Tips Students may better understand the challenges of osmoregulation in freshwater fish if they are reminded of what occurs when humans soak their hands in water. Students will likely recall that this causes the skin on their hands to wrinkle, and some may have noticed that their skin wrinkles even faster in soapy water. Skin absorbs water by osmosis (just as a freshwater fish gains water). Oils on our skin reduce the influx of water. Soapy water, which washes away these oils, speeds up the process. The wrinkling occurs because the skin can expand only in certain areas, creating puckers. © 2012 Pearson Education, Inc. 26
Gain of water and salt ions from food and by intake of seawater Figure 25.4_2 Gain of water and salt ions from food and by intake of seawater Osmotic water loss through gills and other parts of body surface Excretion of salt from gills Excretion of excess ions and small amounts of water in concentrated urine from kidneys Figure 25.4_2 Osmoregulation in a bluefin tuna, a saltwater fish Salt water 27
25.4 Animals balance the level of water and solutes through osmoregulation Land animals face the risk of dehydration, lose water by evaporation and waste disposal, gain water by drinking and eating, and conserve water by reproductive adaptations, behavior adaptations, waterproof skin, and efficient kidneys. Student Misconceptions and Concerns The idea that a freshwater fish never drinks can be conceptually challenging, especially for students who have heard the old saying “drinks like a fish”! Consider introducing your discussion of osmoregulation with this remarkable and seemingly counterintuitive fact to generate interest. Teaching Tips Students may better understand the challenges of osmoregulation in freshwater fish if they are reminded of what occurs when humans soak their hands in water. Students will likely recall that this causes the skin on their hands to wrinkle, and some may have noticed that their skin wrinkles even faster in soapy water. Skin absorbs water by osmosis (just as a freshwater fish gains water). Oils on our skin reduce the influx of water. Soapy water, which washes away these oils, speeds up the process. The wrinkling occurs because the skin can expand only in certain areas, creating puckers. © 2012 Pearson Education, Inc. 28
25.5 EVOLUTION CONNECTION: A variety of ways to dispose of nitrogenous wastes has evolved in animals Metabolism produces toxic by-products. Nitrogenous wastes are toxic breakdown products of proteins and nucleic acids. Animals dispose of nitrogenous wastes in different ways. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Student experience with osmoregulation not pertaining to their bodies may be quite limited. However, many students are familiar with the pasty white color of bird droppings. Consider beginning your discussion of nitrogenous wastes by asking your class to explain why bird droppings are white. © 2012 Pearson Education, Inc. 29
25.5 EVOLUTION CONNECTION: A variety of ways to dispose of nitrogenous wastes has evolved in animals Ammonia (NH3) is poisonous, too toxic to be stored in the body, soluble in water, and easily disposed of by aquatic animals. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Student experience with osmoregulation not pertaining to their bodies may be quite limited. However, many students are familiar with the pasty white color of bird droppings. Consider beginning your discussion of nitrogenous wastes by asking your class to explain why bird droppings are white. © 2012 Pearson Education, Inc. 30
25.5 EVOLUTION CONNECTION: A variety of ways to dispose of nitrogenous wastes has evolved in animals Urea is produced in the vertebrate liver by combining ammonia and carbon dioxide, less toxic, easier to store, and highly soluble in water. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Student experience with osmoregulation not pertaining to their bodies may be quite limited. However, many students are familiar with the pasty white color of bird droppings. Consider beginning your discussion of nitrogenous wastes by asking your class to explain why bird droppings are white. © 2012 Pearson Education, Inc. 31
25.5 EVOLUTION CONNECTION: A variety of ways to dispose of nitrogenous wastes has evolved in animals Uric acid is excreted by some land animals (insects, land snails, and many reptiles), relatively nontoxic, largely insoluble in water, excreted as a semisolid paste, conserving water, but more energy expensive to produce. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Student experience with osmoregulation not pertaining to their bodies may be quite limited. However, many students are familiar with the pasty white color of bird droppings. Consider beginning your discussion of nitrogenous wastes by asking your class to explain why bird droppings are white. © 2012 Pearson Education, Inc. 32
Most aquatic animals, including most bony fishes Figure 25.5 Proteins Amino acids Nitrogenous bases Nucleic acids NH2 (amino groups) Most aquatic animals, including most bony fishes Mammals, most amphibians, sharks, some bony fishes Birds and many other reptiles, insects, land snails Figure 25.5 Nitrogen-containing metabolic waste products Uric acid Ammonia Urea 33
25.6 The urinary system plays several major roles in homeostasis forms and excretes urine and regulates water and solutes in body fluids. In humans, the kidneys are the main processing centers of the urinary system. Student Misconceptions and Concerns 1. The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. 2. Before addressing the human urinary system, challenge each student in your class to explain how a drink of water may end up as urine. Consider having students write out their answers on a 3 5 card in class. This quick survey will likely reveal misunderstandings that would otherwise be concealed by quiet students’ reluctance to speak up. Students might suggest that some sort of tube transports fluid from the digestive tract to the kidneys or urinary bladder. Such surveys provide a useful means of gauging the initial assumptions of your students as they approach a new subject. Teaching Tips 1. A moderately full human urinary bladder holds about 500 ml (or 1 pint) of fluid. The bladder’s maximum capacity may be up to double that volume, although if overdistended, it may burst! 2. Students must understand that blood consists of two main components, cells and plasma. If your course has not covered Chapter 23, consider assigning Module 23.12 to ensure that they have this important background knowledge. 3. During the production of urine, blood cells remain within blood vessels, and components of the plasma are filtered out and selectively reabsorbed. Students may appreciate your making this important distinction early on in the discussion of renal functions. © 2012 Pearson Education, Inc. 34
25.6 The urinary system plays several major roles in homeostasis Nephrons are the functional units of the kidneys, extract a fluid filtrate from the blood, and refine the filtrate to produce urine. Urine is drained from the kidneys by ureters, stored in the urinary bladder, and expelled through the urethra. Student Misconceptions and Concerns 1. The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. 2. Before addressing the human urinary system, challenge each student in your class to explain how a drink of water may end up as urine. Consider having students write out their answers on a 3 x 5 card in class. This quick survey will likely reveal misunderstandings that would otherwise be concealed by quiet students’ reluctance to speak up. Students might suggest that some sort of tube transports fluid from the digestive tract to the kidneys or urinary bladder. Such surveys provide a useful means of gauging the initial assumptions of your students as they approach a new subject. Teaching Tips 1. A moderately full human urinary bladder holds about 500 ml (or 1 pint) of fluid. The bladder’s maximum capacity may be up to double that volume, although if overdistended, it may burst! 2. Students must understand that blood consists of two main components, cells and plasma. If your course has not covered Chapter 23, consider assigning Module 23.12 to ensure that they have this important background knowledge. 3. During the production of urine, blood cells remain within blood vessels, and components of the plasma are filtered out and selectively reabsorbed. Students may appreciate your making this important distinction early on in the discussion of renal functions. © 2012 Pearson Education, Inc. 35
Animation: Nephron Introduction Student Misconceptions and Concerns 1. The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. 2. Before addressing the human urinary system, challenge each student in your class to explain how a drink of water may end up as urine. Consider having students write out their answers on a 3 x 5 card in class. This quick survey will likely reveal misunderstandings that would otherwise be concealed by quiet students’ reluctance to speak up. Students might suggest that some sort of tube transports fluid from the digestive tract to the kidneys or urinary bladder. Such surveys provide a useful means of gauging the initial assumptions of your students as they approach a new subject. Teaching Tips 1. A moderately full human urinary bladder holds about 500 ml (or 1 pint) of fluid. The bladder’s maximum capacity may be up to double that volume, although if overdistended, it may burst! 2. Students must understand that blood consists of two main components, cells and plasma. If your course has not covered Chapter 23, consider assigning Module 23.12 to ensure that they have this important background knowledge. 3. During the production of urine, blood cells remain within blood vessels, and components of the plasma are filtered out and selectively reabsorbed. Students may appreciate your making this important distinction early on in the discussion of renal functions. Animation: Nephron Introduction Right click on animation / Click play © 2012 Pearson Education, Inc. 36
Figure 25.6 Anatomy of the human excretory system Renal cortex Aorta Renal medulla Inferior vena cava Renal artery (red) and vein (blue) Kidney Ureter Urinary bladder Renal pelvis Urethra The urinary system Ureter Bowman’s capsule 1 Proximal tubule Arteriole from renal artery Glomerulus Capillaries The kidney 3 Distal tubule Bowman’s capsule Arteriole from glomerulus Collecting duct Tubule Renal cortex Branch of renal vein From another nephron Branch of renal artery Figure 25.6 Anatomy of the human excretory system Branch of renal vein Collecting duct Renal medulla 2 Loop of Henle with capillary network To renal pelvis Detailed structure of a nephron Orientation of a nephron within the kidney 37
The urinary system Aorta Inferior vena cava Figure 25.6_1 Aorta Inferior vena cava Renal artery (red) and vein (blue) Kidney Ureter Figure 25.6_1 Anatomy of the human excretory system: the urinary system (part 1) Urinary bladder Urethra The urinary system 38
Renal cortex Renal medulla Renal pelvis Ureter The kidney Figure 25.6_2 Renal cortex Renal medulla Renal pelvis Ureter Figure 25.6_2 Anatomy of the human excretory system: the kidney (part 2) The kidney 39
Orientation of a nephron within the kidney Figure 25.6_3 Bowman’s capsule Tubule Renal cortex Branch of renal artery Branch of renal vein Collecting duct Renal medulla Figure 25.6_3 Anatomy of the human excretory system: nephron orientation (part 3) To renal pelvis Orientation of a nephron within the kidney 40
Arteriole from renal artery Glomerulus Capillaries Figure 25.6_4 Bowman’s capsule 1 Proximal tubule Arteriole from renal artery Glomerulus Capillaries 3 Distal tubule Collecting Duct Arteriole from glomerulus Branch of renal vein From another nephron Figure 25.6_4 Anatomy of the human excretory system: nephron structure (part 4) 2 Loop of Henle with capillary network Detailed structure of a nephron 41
25.7 Overview: The key processes of the urinary system are filtration, reabsorption, secretion, and excretion Filtration Blood pressure forces water and many small molecules through a capillary wall into the start of the kidney tubule. Reabsorption refines the filtrate, reclaims valuable solutes (such as glucose, salt, and amino acids) from the filtrate, and returns these to the blood. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips 1. Students must understand that blood consists of two main components, cells and plasma. If your course has not covered Chapter 23, consider assigning Module 23.12 to ensure that they have this important background knowledge. 2. During the production of urine, blood cells remain within blood vessels, and components of the plasma are filtered out and selectively reabsorbed. Students may appreciate your making this important distinction early on in the discussion of renal functions. 3. Some drugs are excreted in urine. This is the basis of drug testing using samples of a person’s urine. Making this simple connection can help generate interest and improve comprehension in your students. 4. Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. © 2012 Pearson Education, Inc. 42
Figure 25.7 Major processes of the urinary system Bowman’s capsule From renal artery Filtration Reabsorption Secretion Excretion Nephron tubule H2O, other small molecules Urine Interstitial fluid Capillary To renal vein Figure 25.7 Major processes of the urinary system 43
H2O, other small molecules Figure 25.7_1 Bowman’s capsule From renal artery Filtration Nephron tubule H2O, other small molecules Interstitial fluid Figure 25.7_1 Major processes of the urinary system (part 1) Capillary 44
Reabsorption Secretion Excretion Nephron tubule Urine To renal vein Figure 25.7_2 Reabsorption Secretion Excretion Nephron tubule Urine To renal vein Figure 25.7_2 Major processes of the urinary system (part 2) Capillary 45
25.7 Overview: The key processes of the urinary system are filtration, reabsorption, secretion, and excretion Substances in the blood are transported into the filtrate by the process of secretion. By excretion the final product, urine, is excreted via the ureters, urinary bladder, and urethra. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips 1. Students must understand that blood consists of two main components, cells and plasma. If your course has not covered Chapter 23, consider assigning Module 23.12 to ensure that they have this important background knowledge. 2. During the production of urine, blood cells remain within blood vessels, and components of the plasma are filtered out and selectively reabsorbed. Students may appreciate your making this important distinction early on in the discussion of renal functions. 3. Some drugs are excreted in urine. This is the basis of drug testing using samples of a person’s urine. Making this simple connection can help generate interest and improve comprehension in your students. 4. Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. © 2012 Pearson Education, Inc. 46
Figure 25.7 Major processes of the urinary system Bowman’s capsule From renal artery Filtration Reabsorption Secretion Excretion Nephron tubule H2O, other small molecules Urine Interstitial fluid Capillary To renal vein Figure 25.7 Major processes of the urinary system 47
25.8 Blood filtrate is refined to urine through reabsorption and secretion Reabsorption in the proximal and distal tubules removes nutrients, salt, and water. pH is regulated by reabsorption of HCO3– and secretion of H+. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. © 2012 Pearson Education, Inc. 48
25.8 Blood filtrate is refined to urine through reabsorption and secretion High NaCl concentration in the medulla promotes reabsorption of water. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. © 2012 Pearson Education, Inc. 49
Animation: Bowman’s Capsule and Proximal Tubule Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. Animation: Bowman’s Capsule and Proximal Tubule Right click on animation / Click play © 2012 Pearson Education, Inc. 50
Animation: Collecting Duct Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. Animation: Collecting Duct Right click on animation / Click play © 2012 Pearson Education, Inc. 51
Animation: Effect of ADH Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. Animation: Effect of ADH Right click on animation / Click play © 2012 Pearson Education, Inc. 52
Animation: Loop of Henle and Distal Tubule Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Many students do not know about interstitial fluid or its functions. They may think that blood delivers nutrients directly to cells, perhaps through direct contact between capillaries and cells. Instead, interstitial fluids typically act as an intermediate and promote homeostasis in many ways. Interstitial fluid is discussed in detail in Module 23.7, which may not have been addressed previously in your class. Animation: Loop of Henle and Distal Tubule Right click on animation / Click play © 2012 Pearson Education, Inc. 53
Urine (to renal pelvis) Figure 25.8 Bowman’s capsule Proximal tubule Distal tubule Nutrients H2O 1 H2O NaCl HCO3 NaCl HCO3 Blood Some drugs and poisons H K H 3 Collecting duct Cortex Filtrate composition Medulla H2O Salts (NaCl and others) HCO3 H Urea Glucose Amino acids Some drugs Interstitial fluid Loop of Henle 2 NaCl NaCl H2O Urea Figure 25.8 Reabsorption and secretion in a nephron NaCl H2O Reabsorption Secretion Filtrate movement Urine (to renal pelvis) 54
Bowman’s capsule Proximal tubule Nutrients H2O HCO3 NaCl Blood Figure 25.8_1 Bowman’s capsule Proximal tubule Nutrients H2O NaCl HCO3 Blood Some drugs and poisons H Cortex Filtrate composition Medulla H2O Salts (NaCl and others) HCO3 H Urea Glucose Amino acids Some drugs Figure 25.8_1 Reabsorption and secretion in a nephron (part 1) Reabsorption Secretion Filtrate movement 55
Proximal tubule Distal tubule Nutrients H2O H2O NaCl HCO3 NaCl Figure 25.8_2 Proximal tubule Distal tubule Nutrients H2O 1 H2O NaCl HCO3 NaCl HCO3 Some drugs and poisons H K H 3 Collecting duct Cortex Medulla Interstitial fluid Loop of Henle 2 NaCl NaCl H2O Figure 25.8_2 Reabsorption and secretion in a nephron (part 2) Reabsorption Urea NaCl Secretion H2O Filtrate movement Urine (to renal pelvis) 56
25.9 Hormones regulate the urinary system Antidiuretic hormone (ADH) regulates the amount of water excreted by the kidneys by signaling nephrons to reabsorb water from the filtrate, returning it to the blood, and decreasing the amount of water excreted. Diuretics inhibit the release of ADH and include alcohol and caffeine. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips Students may be particularly interested in the diuretic effects of alcohol and caffeine. The text notes that the diuretic effects of alcohol may contribute to some of the symptoms of a hangover. However, the concentration of alcohol and caffeine are important factors. Higher urine output resulting from the high consumption of low-alcohol (1–5%) beer may largely be the consequence of increased water consumption. Drinks with higher alcohol levels, such as shots of hard liquor (gin, vodka, whiskey) or higher caffeine levels (espresso) and low fluid volume would be expected to better reveal the diuretic effects. © 2012 Pearson Education, Inc. 57
25.10 CONNECTION: Kidney dialysis can be lifesaving Kidney failure can result from hypertension, diabetes, and prolonged use of common drugs, including alcohol. A dialysis machine removes wastes from the blood and maintains its solute concentration. Student Misconceptions and Concerns The kidney’s role in filtration and selective reabsorption may initially be confusing to many students. The process is a bit like cleaning up a closet by removing all the contents and then selectively returning to it what you wish to store. Teaching Tips 1. The loss of one kidney in a human typically results in enlargement of the remaining kidney, a process known as compensatory hypertrophy. As your time permits, this can provide material for a class discussion or for a special-topic assignment for students with a particular interest. 2. The unfortunate shortage of kidneys and other organs available for transplant is a major health issue. Consider discussing this problem with your class. Many state and federal organ donation organizations can by located by a quick Internet search. The National Kidney Foundation site www.kidney.org/atoz/atozTopic_Organ-Tissue-Donation.cfm includes information on kidney donation. © 2012 Pearson Education, Inc. 58
Line from artery to apparatus Figure 25.9 Line from artery to apparatus Pump Tubing made of a selectively permeable membrane Dialyzing solution Line from apparatus to vein Figure 25.9 Kidney dialysis Fresh dialyzing solution Used dialyzing solution (with urea and excess ions) 59
Line from artery to apparatus Figure 25.9_1 Line from artery to apparatus Pump Tubing made of a selectively permeable membrane Dialyzing solution Line from apparatus to vein Figure 25.9_1 Kidney dialysis (part 1) Fresh dialyzing solution Used dialyzing solution (with urea and excess ions) 60
Figure 25.9_2 Figure 25.9_2 Kidney dialysis (part 2) 61
You should now be able to Explain how bear physiology adjusts during dormancy. Describe four ways that heat is gained or lost by an animal. Describe five categories of adaptations that help animals thermoregulate. Compare the osmoregulatory problems of freshwater fish, saltwater fish, and terrestrial animals. © 2012 Pearson Education, Inc. 62
You should now be able to Compare the three ways that animals eliminate nitrogenous wastes. Describe the structure and functions of the human kidney. Explain how the kidney promotes homeostasis. Describe four major processes that produce urine. Describe the key events in the conversion of filtrate into urine. Explain why a dialysis machine is necessary and how it works. © 2012 Pearson Education, Inc. 63
Figure 25.4_UN01 Figure 25.4_UN01 The tough, water-tight shell of a turtle egg 64
Figure 25.UN01 35 33C 30 27 20 18 10 9 Figure 25.UN01 Reviewing the Concepts, 25.3 65
Evaporation, urinary system Figure 25.UN02 Gain Water Lose Water Salt Freshwater Fish Osmosis Excretion Pump in Saltwater Fish Drinking Osmosis Excrete, pump out Land Animal Drinking, eating Evaporation, urinary system Figure 25.UN02 Reviewing the Concepts, 25.4 66
Figure 25.UN03 Urea Figure 25.UN03 Reviewing the Concepts, 25.5 67
Kidney Ureter Bladder Figure 25.UN04 Figure 25.UN04 Reviewing the Concepts, 25.7 68
requirements depend on form may be Figure 25.UN05 Homeostasis involves processes of (a) (b) (c) maintains balance of involves removal of both done by animal may be water and solutes human kidney nitrogenous wastes (d) requirements depend on form may be (e) endotherm mechanisms mostly (f) mechanisms include (g) Figure 25.UN05 Connecting the Concepts, question 1 depends on (h) (i) reproduction (where embryo develops) may be heat production, insulation, countercurrent heat exchange ocean, fresh water, land 69
(a) (b) (c) Bowman’s capsule From renal artery To renal vein Figure 25.UN06 (a) (b) (c) Bowman’s capsule From renal artery To renal vein Collecting duct Glomerulus Tubule Loop of Henle Capillaries Figure 25.UN06 Connecting the Concepts, question 2 (d) 70