1. Slides 1 to 73
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2. Introduction All living organisms share the following characteristics:
Responsiveness
Growth
Reproduction
Movement
Metabolism
This is a sample first topic page.
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

3. Anatomy & Physiology Sciences
Anatomists study:
Internal and external structure
Physical relationships among body parts
Physiologists study:
How organisms perform vital functions
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4. Anatomy & Physiology Sciences
Gross anatomy
“Naked eye” anatomy
Surface anatomy
Regional anatomy
Sectional anatomy
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

5. Anatomy & Physiology Sciences
Microscopic anatomy
Cytology: study of individual cells
Histology: study of tissues
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

6. Anatomy & Physiology Sciences
Human physiology:
Study of human body function
Cell physiology
Special physiology
System physiology
Pathological physiology
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7. Levels of Organization
Life is built on successive levels of increasing complexity:
Chemical (or Molecular)
Cellular
Tissue
Organ
Organ System
Organism
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8. 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
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9. 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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10. 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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11. 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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12. 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

13. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

14. 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

15. Overview of Organ Systems
The human body is arranged in 11 organ systems:
Integumentary
Skeletal
Muscular
Nervous
Endocrine
Cardiovascular
Lymphatic
Respiratory
Digestive
Urinary
Reproductive
PLAY
Organ Systems
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16. The Integumentary System
Figure 1-2(a)

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

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

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

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

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

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

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

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

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

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

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

28. Introduction to Organ Systems
Key Note
The body can be divided into 11 organ systems, but all work together and the boundaries between them aren’t absolute.
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29. Homeostatic Regulation
Homeostasis
Maintains stable internal conditions
Temperature
Ionic concentrations
Blood sugar levels, etc.
Utilizes negative feedback mechanisms
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30. Homeostatic Regulation
Regulation depends on:
Receptor sensitive to a particular stimulus
Effector that affects the same stimulus
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31. 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
1 of 6
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32. HOMEOSTASIS Normal room temperature
Figure 1-3
2 of 6
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33. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

34. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

35. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

36. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

37. Homeostatic Regulation
Negative Feedback:
Variation outside normal limits triggers automatic corrective response
Response negates disturbance
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

38. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

39. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

40. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

41. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

42. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

43. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

44. 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

45. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

46. 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
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

47. Figure 1-4 10 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
10 of 10
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

48. Homeostatic Regulation
Positive Feedback:
Stimulus produces response that reinforces the stimulus
Response rapidly completes critical process
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49. Homeostatic Regulation
Figure 1-5

50. Homeostatic Regulation
Homeostasis and Disease
Failure of homeostatic regulation
Symptoms appear
Organ system malfunction
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51. Homeostatic Regulation
Key Note
Physiological systems work together to maintain a stable internal environment. They monitor and adjust internal conditions.
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

52. The Language of Anatomy
Surface Anatomy
Anatomical Position
Hands at side
Palms forward
Feet together
Supine: Face up
Prone: Face down
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53. The Language of Anatomy
Figure 1-6(a)

54. The Language of Anatomy
Figure 1-6(b)

55. The Language of Anatomy
Anatomical Regions
Two methods to map abdominal and pelvic regions
Four abdominopelvic quadrants
Nine abdominopelvic regions
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56. The Language of Anatomy
Figure 1-7(a)

57. The Language of Anatomy
Figure 1-7(b)

58. The Language of Anatomy
Figure 1-7(c)

59. The Language of Anatomy
A few anatomical directions:
Anterior (= ventral)
Posterior (= dorsal)
Superior
Inferior
Lateral
Medial
Proximal
Distal
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60. The Language of Anatomy
Figure 1-8

61. The Language of Anatomy
Sectional Anatomy: Planes and Sections
Transverse plane
Transverse section
Frontal plane
Frontal section
Sagittal plane
Sagittal section
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62. The Language of Anatomy
Figure 1-9

63. The Language of Anatomy
Ventral body cavity
Protects delicate organs
Permits organ growth and movement
Surrounds:
Respiratory
Cardiovascular
Digestive
Urinary
Reproductive organs
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

64. The Language of Anatomy
Diaphragm subdivides ventral cavity:
Thoracic cavity
Pleural cavities (R and L)
Pericardial cavity
Abdominopelvic cavity
Abdominal cavity
Pelvic cavity
Peritoneal membrane
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65. The Language of Anatomy
Key Note
Anatomical descriptions refer to an individual in the anatomical position: standing, with the hands at the sides,
palms facing forward, and feet together.
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings

66. The Language of Anatomy
Figure 1-10(a)

67. The Language of Anatomy
Radiological Procedures
X-rays
CT Scans
MRIs
Ultrasound
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68. X-Rays
Missing figure 1-11
Figure 1-11(a)

69. X-Rays
Missing figure 1-11
Figure 1-11(b)

70. Common Scanning Techniques
Figure 1-12(a)

71. Common Scanning Techniques
Figure 1-12(b)

72. Common Scanning Techniques
Figure 1-12(c)

73. Common Scanning Techniques
Figure 1-12(d)