1. Basic Principles of Animal Form and Function

3. LE 40-2
Tuna
Shark
Penguin
Dolphin
Seal

4. Chemical or Molecular Level (Chapter 2)
Atoms in
combination
Chemical or
Molecular Level
(Chapter 2)
Complex protein
molecule
Figure of 7
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5. Chemical or Molecular Level (Chapter 2) Cellular Level (Chapter 3)
Atoms in
combination
Heart
muscle
cell
Chemical or
Molecular Level
(Chapter 2)
Complex protein
molecule
Protein filaments
Cellular Level
(Chapter 3)
Figure of 7
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6. Tissue Level (Chapter 4) Chemical or Molecular Level (Chapter 2)
Cardiac
muscle
tissue
Atoms in
combination
Tissue Level
(Chapter 4)
Heart
muscle
cell
Chemical or
Molecular Level
(Chapter 2)
Complex protein
molecule
Protein filaments
Cellular Level
(Chapter 3)
Figure of 7
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7. Organ System Level (Chapters 5–20) Organ Level Tissue Level
Cardiovascular
Organ
Level
The
heart
Cardiac
muscle
tissue
Atoms in
combination
Tissue Level
(Chapter 4)
Heart
muscle
cell
Chemical or
Molecular Level
(Chapter 2)
Complex protein
molecule
Protein filaments
Cellular Level
(Chapter 3)
Figure of 7
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

8. Organ System Level (Chapters 5–20) Organ Level Tissue Level
Endocrine
Cardiovascular
Lymphatic
Nervous
Respiratory
Muscular
Digestive
Skeletal
Urinary
Integumentary
Reproductive
Organ
Level
The
heart
Cardiac
muscle
tissue
Atoms in
combination
Tissue Level
(Chapter 4)
Heart
muscle
cell
Complex protein
molecule
Protein filaments
Chemical or
Molecular Level
(Chapter 2)
Cellular Level
(Chapter 3)
Figure of 7
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9. Organ Organism System Level Level (Chapters 5–20) Organ Level
Endocrine
Cardiovascular
Lymphatic
Nervous
Respiratory
Muscular
Digestive
Skeletal
Urinary
Integumentary
Reproductive
Organ
Level
The
heart
Cardiac
muscle
tissue
Atoms in
combination
Tissue Level
(Chapter 4)
Heart
muscle
cell
Complex protein
molecule
Protein filaments
Chemical or
Molecular Level
(Chapter 2)
Cellular Level
(Chapter 3)
Figure of 7
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

10. LE 40-4 External environment CO2 Food O2 Mouth Animal body Respiratory
system
Blood
50 µm
0.5 cm
A microscopic view of the lung reveals that it is much more spongelike than balloonlike. This construction provides an expansive wet surface for gas exchange with the environment (SEM).
Cells
Heart
Nutrients
Circulatory
system
10 µm
Digestive
system
Interstitial
fluid
Excretory
system
The lining of the small intestine, a digestive organ, is elaborated with fingerlike projections that expand the surface area for nutrient absorption (cross-section, SEM).
Anus
Inside a kidney is a mass of microscopic tubules that exchange chemicals with blood flowing through a web of tiny vessels called capillaries (SEM).
Unabsorbed
matter (feces)
Metabolic waste
products (urine)

11. The Integumentary System
Figure 1-2(a)

12. The Skeletal System
Figure 1-2(b)

13. The Muscular System
Figure 1-2(c)

14. The Nervous System
Figure 1-2(d)

15. The Endocrine System
Figure 1-2(e)

16. The Cardiovascular System
Figure 1-2(f)

17. The Lymphatic System
Figure 1-2(g)

18. The Respiratory System
Figure 1-2(h)

19. The Digestive System
Figure 1-2(i)

20. The Urinary System
Figure 1-2(j)

21. Male Reproductive System
Figure 1-2(k)

22. Female Reproductive System
Figure 1-2(l)

23. Homeostatic Regulation
Homeostasis
Maintains stable internal conditions
Temperature
Ionic concentrations
Blood sugar levels, etc.
Utilizes negative and positive feedback mechanisms
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24. Homeostatic Regulation
Regulation depends on:
Receptor
sensitive to a particular stimulus
Effector
that affects the same stimulus
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25. HOMEOSTASIS Normal room temperature
Figure 1-3
2 of 6
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26. Normal condition disturbed STIMULUS: Room temperature rises
RECEPTOR
Normal
condition
disturbed
Thermometer
STIMULUS:
Room temperature
rises
HOMEOSTASIS
Normal
room
temperature
Figure 1-3
3 of 6
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27. Information Normal affects condition disturbed STIMULUS:
RECEPTOR
Information
affects
Normal
condition
disturbed
Thermometer
STIMULUS:
Room temperature
rises
CONTROL CENTER
(Thermostat)
HOMEOSTASIS
Normal
room
temperature
20o
30o
40o
Figure 1-3
4 of 6
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28. Information Normal affects condition disturbed STIMULUS:
RECEPTOR
Information
affects
Normal
condition
disturbed
Thermometer
STIMULUS:
Room temperature
rises
CONTROL CENTER
(Thermostat)
HOMEOSTASIS
Normal
room
temperature
20o
30o
40o
EFFECTOR
Sends
commands to
Air conditioner
turns on
Figure 1-3
5 of 6
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29. Information Normal affects condition disturbed STIMULUS:
RECEPTOR
Information
affects
Normal
condition
disturbed
Thermometer
STIMULUS:
Room temperature
rises
CONTROL CENTER
(Thermostat)
HOMEOSTASIS
Normal
room
temperature
RESPONSE:
Room temperature
drops
20o
30o
40o
Normal
condition
restored
EFFECTOR
Sends
commands to
Air conditioner
turns on
Figure 1-3
6 of 6
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30. Homeostatic Regulation
Negative Feedback:
Variation outside normal limits triggers automatic corrective response
Response negates disturbance
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31. STIMULUS Thermoregulatory center in brain
CONTROL
CENTER
STIMULUS
Body temperature
rises above 37.2oC
(99oF)
Control
mechanism
when body
temperature
rises
Thermoregulatory
center in brain
Figure 1-4
2 of 10
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32. Information affects STIMULUS Thermoregulatory center in brain
RECEPTOR
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
Body temperature
rises above 37.2oC
(99oF)
Control
mechanism
when body
temperature
rises
Thermoregulatory
center in brain
Figure 1-4
3 of 10
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33. Information affects STIMULUS Thermoregulatory center in brain Sends
RECEPTOR
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
Body temperature
rises above 37.2oC
(99oF)
Control
mechanism
when body
temperature
rises
EFFECTOR
Thermoregulatory
center in brain
Blood vessels
and sweat
glands in skin
Sends
commands to
Figure 1-4
4 of 10
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34. Information affects STIMULUS RESPONSE Thermoregulatory center in brain
RECEPTOR
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
Body temperature
rises above 37.2oC
(99oF)
Control
mechanism
when body
temperature
rises
RESPONSE
Increased blood flow
to skin
Increased sweating
Stimulus removed
Homeostasis restored
EFFECTOR
Thermoregulatory
center in brain
Negative
feedback
Blood vessels
and sweat
glands in skin
Sends
commands to
Figure 1-4
5 of 10
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35. STIMULUS Thermoregulatory center in brain
CONTROL
CENTER
STIMULUS
Body temperature
falls below 37.2oC
(99oF)
Control
mechanism
when body
temperature
falls
Thermoregulatory
center in brain
Figure 1-4
6 of 10
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36. Information affects STIMULUS Thermoregulatory center in brain
RECEPTOR
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
Body temperature
falls below 37.2oC
(99oF)
Control
mechanism
when body
temperature
falls
Thermoregulatory
center in brain
Figure 1-4
7 of 10
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

37. Information affects STIMULUS Thermoregulatory center in brain Sends
RECEPTOR
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
Body temperature
falls below 37.2oC
(99oF)
Control
mechanism
when body
temperature
falls
Thermoregulatory
center in brain
EFFECTOR
Sends
commands to
Blood vessels
and sweat glands
in skin
Skeletal muscles
Figure 1-4
8 of 10
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38. Information affects STIMULUS RESPONSE Thermoregulatory center in brain
RECEPTOR
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
Body temperature
falls below 37.2oC
(99oF)
Control
mechanism
when body
temperature
falls
RESPONSE
Decreased blood flow
to skin
Decreased sweating
Shivering
Stimulus removed
Homeostasis restored
Thermoregulatory
center in brain
EFFECTOR
Sends
commands to
Blood vessels
and sweat glands
in skin
Skeletal muscles
Negative
feedback
Figure 1-4
9 of 10
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39. Figure 1-4 1 of 10 Information affects Information affects RECEPTOR
Body’s
temperature
sensors
Body’s
temperature
sensors
CONTROL
CENTER
STIMULUS
STIMULUS
Body temperature
rises above 37.2oC
(99oF)
Body temperature
falls below 37.2oC
(99oF)
Control
mechanism
when body
temperature
rises
Control
mechanism
when body
temperature
falls
RESPONSE
RESPONSE
Decreased blood flow
to skin
Decreased sweating
Shivering
Stimulus removed
Homeostasis restored
Increased blood flow
to skin
Increased sweating
Stimulus removed
Homeostasis restored
Thermoregulatory
center in brain
EFFECTOR
EFFECTOR
Negative
feedback
Blood vessels
and sweat
glands in skin
Sends
commands to
Sends
commands to
Blood vessels
and sweat glands
in skin
Skeletal muscles
Negative
feedback
Figure 1-4
1 of 10
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40. Homeostatic Regulation
Positive Feedback:
Stimulus produces response that reinforces the stimulus
Response rapidly completes critical process
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41. Homeostatic Regulation
Figure 1-5

42. Tissue Structure and Function
Types of Tissue
Epithelial
Connective
Muscle
Nervous

43. LE 40-5_1 Simple Stratified columnar columnar epithelium epithelium
EPITHELIAL TISSUE
Columnar epithelia, which have cells with relatively large cytoplasmic volumes, are often located where secretion or active absorption of substances is an important function.
Simple
columnar
epithelium
Stratified
columnar
epithelium
Pseudostratified
ciliated columnar
epithelium
Cuboidal
epithelia
Stratified
squamous
epithelia
Simple squamous
epithelia
Basement membrane
40 µm

44. LE 40-5_2 Chondrocytes Collagenous fiber Loose connective tissue
120 µm
Chondrocytes
Collagenous
fiber
Loose
connective
tissue
Chondroitin
sulfate
Elastic
fiber
100 µm
Cartilage
Fibrous
connective tissue
Adipose tissue
Fat droplets
Nuclei
150 µm
30 µm
Blood
Central
canal
Red blood cells
Bone
White blood cell
Osteon
Plasma
700 µm
55 µm

45. LE 40-5_3 Multiple nuclei Skeletal muscle Muscle fiber Sarcomere
MUSCLE TISSUE
100 µm
Multiple
nuclei
Skeletal muscle
Muscle fiber
Sarcomere
Cardiac muscle
Nucleus
Intercalated
disk
50 µm
Nucleus
Smooth muscle
Muscle
fibers
25 µm
NERVOUS TISSUE
Neuron
Process
Cell body
Nucleus
50 µm

46. LE 40-6
Lumen of
stomach
Mucosa: an epithelial
layer that lines the
lumen
Submucosa: a matrix of
connective tissue that
contains blood vessels
and nerves
Muscularis: consists
mainly of smooth muscle
tissue
Serosa: a thin layer of
connective and epithelial
tissue external to the muscularis
0.2 mm

47. Bioenergetics Bioenergetics the flow of energy through an animal
Limits:
Behavior
Growth
Reproduction
determines how much food an animal needs

48. LE 40-7 Organic molecules in food External environment Animal body
Digestion and
absorption
Heat
Energy
lost in
feces
Nutrient molecules
in body cells
Energy
lost in
urine
Carbon
skeletons
Cellular
respiration
Heat
ATP
Biosynthesis:
growth,
storage, and
reproduction
Cellular
work
Heat
Heat

49. Quantifying Energy Use
Metabolic rate
the amount of energy an animal uses in a unit of time
Measured by determining
amount of oxygen consumed
Amount of carbon dioxide produced

50. Ectotherms and Endotherms
include most invertebrates, fishes, amphibians, and non-bird reptiles
Lower metabolic rates
Tolerate greater variation in internal temperature
Endotherms
Include birds and mammals
Higher metabolic rates
more energetically expensive

51. River otter (endotherm)
LE 40-12 40
River otter (endotherm) 30
Body temperature (°C) 20
Largemouth bass (ectotherm) 10 10 20 30 40
Ambient (environmental) temperature (°C)

52. LE 40-13
Radiation
Evaporation
Convection
Conduction

53. Balancing Heat Loss and Gain
Five general adaptations help animals thermoregulate:
Insulation
mammals and birds
Examples are skin, feathers, fur, and blubber
Circulatory adaptations
vasodilation, blood flow in the skin increases, facilitating heat loss
vasoconstriction, blood flow in the skin decreases, lowering heat loss
Countercurrent heat exchanger

54. Canada goose Pacific bottlenose dolphin Blood flow Artery Vein Vein
33°
30°
27°
20°
18°
10° 9°

55. Skin Artery Vein Blood Capillary vessels network within in gills
LE 40-16b
Skin
Artery
Vein
Blood
vessels
in gills
Capillary
network within
muscle
Heart
Artery and
vein under
the skin
Dorsal aorta
Great white shark

56. Cooling by evaporative heat loss
Sweat
Panting
Bathing
Behavioral responses
posture
Adjusting metabolic heat production
shivering

58. Adjustment to Changing Temperatures
Hypothalamus –
Temperature control center in mammals
Acclimatization
adjust to a new range of environmental temperatures
period of days or weeks
cellular adjustments
adjustments of insulation
Adjustments of metabolic heat production

59. Torpor and Energy Conservation
activity is low and metabolism decreases
enables animals to save energy while avoiding difficult and dangerous conditions
Hibernation
long-term torpor
adaptation to winter cold and food scarcity
Estivation,
summer torpor
enables animals to survive long periods of high temperatures and scarce water supplies

60. LE 40-22 Additional metabolism that would be
necessary to stay active in winter
200
Actual
metabolism
Metabolic rate
(kcal per day)
100
Arousals 35
Body
temperature 30 25 20
Temperature (°C) 15 10 5 –5
Outside
temperature
Burrow
temperature
–10
–15
June
August
October
December
February
April