1. Excretion
AP Biology
Unit 6

2. Osmolarity Osmolarity = total solute concentration of a solution
Which way will the water move?
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3. Question…
What would happen if your body did not maintain proper osmolarity?
You would either have an excess of water (bloated) or too little water (dehydrated)
Cells wouldn’t have the correct balance of solutes and H2O  won’t function properly
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4. Osmoregulators versus Osmoconformers

5. Osmoconformers
Animals whose internal osmolarity changes in relation to their external environment
There are limits to this– too high or too low will cause death
Marine invertebrates, sharks, rays
Ex. Brine Shrimp (Artemia)
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6. Osmoregulators
Animals who can maintain their internal osmolarity at a particular level regardless of the external environment
Ex. Fish, humans, lots of other animals 
Slide 5 of 26

7. Question…
How does the environment one lives in affect how osmoregulation takes place?
Depending on the environment one lives in, osmoregulation can be very different
Slide 6 of 26

8. Saltwater Fish
Challenge: Prevent too much water from leaving the body (to go into the outside environment)
Higher osmolarity outside compared to inside of body
Solution…
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9. Freshwater Fish
Challenge: Prevent too much water from coming into the body from the outside
Higher osmolarity inside body compared to outside
Solution…
Slide 8 of 26

11. What about 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. 11

12. What is Nitrogenous Waste?
Metabolic waste produced by cells from the breakdown of Proteins and Nucleic Acids into NH2 groups
This waste must be excreted
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13. 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 13

14. What are the three major kinds of nitrogenous wastes?
Ammonia: Most toxic. Only produced by aquatic animals
Urea: Formed by combining Ammonia with CO2; Not as toxic; Released with less water
Uric Acid: Least soluble; Excreted with the least amount of water
Slide 11 of 26

15. Excretion in Aquatic Animals
For most aquatic animals, excreting ammonia is not an issue - why?
Ammonia is highly soluble in H2O, diffuses away rapidly (won’t stay concentrated around them)
Aquatic animals continuously lose ammonia from their bodies through diffusion across their gill membranes
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16. Question…
Why don’t terrestrial animals and some aquatic animals just excrete dilute ammonia in liquid?
Since ammonia is toxic even at fairly low levels, it would have to use a lot of water to dilute it
Too much water loss = dehydration
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17. Why do some land animals excrete uric acid instead of urea?
Helps conserve H2O because it isn’t very soluble in water  semi solid
Ex. Birds, reptiles, insects, some amphibians
Slide 16 of 26

18. Stages of Excretion Figure 25.7
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 18

19. Excretory Process
Filtration: Initial movement of fluid and solutes from the body
Selective Reabsorption: Water and
desirable solutes are reabsorbed into the
body
Secretion: Excess waste solute is added
to the filtrate
Excretion: Modified filtrate is expelled
from the body
Slide 17 of 26

20. Invertebrate: Flatworm Excretory System
Protonephridia are tiny tubules that interstitial fluid moves through
Filtrate is produced through the action of ciliated “flame bulb cells”
Filtrate modified as it flows and exits through openings in the body wall
Slide 21 of 26

21. Invertebrate: Earthworms
Due to pressure from blood water and solutes are pushed from the blood into the metanephridia
Reabsorption and Secretion takes place between metanephridium and capillaries
Stored urine excreted through external openings
Slide 23 of 26

22. Vertebrates: What are the major organs of the urinary system?
Kidneys – produce urine
Ureters – carries urine from
the kidneys to bladder
Bladder – stores urine
Urethra – releases the urine

23. 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.
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 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. 23

24. Nephron Blood Processing: Filtration:
Will blood cells and proteins be filtered into the nephron?
Blood Processing:
Filtration:
Arteries transport blood to the kidney (nephron)
Urea, water, Glucose, and salts (minerals) are filtered out by diffusion/active transport
No!! Way too Big!!!

25. Nephron Blood Processing: 2) Reabsorption:
Substances still needed by the body are removed from the filtrate and reenter the blood via diffusion/active transport
Ex: glucose, water, minerals (NOT urea)

26. Nephron Blood Processing: Secretion:
Kidneys remove certain substances from the blood and add them to the filtrate.
Ex: Salts, Water

27. Nephron Blood Processing: Excretion:
Urine has been formed! Will be moved to the bladder to be excreted from the body

28. 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 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. 28

29. 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 29

30. 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 30

31. 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 31

32. 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 32

33. 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 33

34. 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 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. 34

35. 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 35

36. Reabsorption Secretion Excretion Nephron tubule Urine To renal vein
Figure 25.7_2
Reabsorption
Secretion
Excretion
Nephron tubule
Urine
To renal vein
Capillary
Figure 25.7_2 Major processes of the urinary system (part 2) 36

37. 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 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. 37

38. 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 38

39. Reabsorption in the proximal and distal tubules removes
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. 39

40. High NaCl concentration in the medulla promotes reabsorption of water.
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. 40

41. 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. 41

42. 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. 42

43. 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. 43

44. 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. 44

45. 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) 45

46. 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 46

47.   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) 47

48. 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. 48