1. Figure 21-8 An Overview of Cardiovascular Physiology
Cardiac Output
Venous Return
Arterial Blood Pressure
Regulation (Neural and Hormonal)
Venous Pressure
Peripheral Resistance
Capillary Pressure
Capillary exchange
Interstitial fluid 1

2. Pressure and Resistance
Total capillary blood flow
Equals cardiac output
Is determined by
pressure and resistance in the cardiovascular system

3. Pressure and Resistance
An Overview of Cardiovascular Pressures
Systolic pressure
Peak arterial pressure during ventricular systole
Diastolic pressure
Minimum arterial pressure during diastole
Pulse pressure
Difference between systolic pressure and diastolic pressure
Mean arterial pressure (MAP)
MAP = diastolic pressure + 1/3 pulse pressure

4. Vessel diameter Vessel diameter (cm)
Figure 21-10a Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit
Vessel diameter
(cm)
Vessel diameter 4

5. Total cross-sectional area of vessels
Figure 21-10b Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit
Cross- sectional area (cm2)
Total cross-sectional area of vessels 5

6. Average blood pressure
Figure 21-10c Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit
Average blood pressure (mm Hg)
Average blood pressure 6

7. Velocity of blood flow Velocity of blood flow (cm/sec)
Figure 21-10d Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit
Velocity of blood flow (cm/sec)
Velocity of blood flow 7

8. Figure 21-11 Pressures within the Systemic Circuit
Systolic
Pulse pressure
Mean arterial pressure
Diastolic
mm Hg 8

9. Pressure and Resistance
Capillary Pressures and Capillary Exchange
Vital to homeostasis
Moves materials across capillary walls by
Diffusion
Filtration
Reabsorption

10. Pressure and Resistance
Diffusion
Movement of ions or molecules
From high concentration
To lower concentration
Along the concentration gradient

11. Pressure and Resistance
Diffusion Routes
Water, ions, and small molecules such as glucose
Diffuse between adjacent endothelial cells
Or through fenestrated capillaries
Some ions (Na+, K+, Ca2+, Cl-)
Diffuse through channels in plasma membranes

12. Pressure and Resistance
Diffusion Routes
Large, water-soluble compounds
Pass through fenestrated capillaries
Lipids and lipid-soluble materials such as O2 and CO2
Diffuse through endothelial plasma membranes
Plasma proteins
Cross endothelial lining in sinusoids

13. Pressure and Resistance
Filtration
Driven by hydrostatic pressure
Water and small solutes forced through capillary wall
Leaves larger solutes in bloodstream

14. Pressure and Resistance
Reabsorption
The result of osmosis
Blood colloid osmotic pressure
Equals pressure required to prevent osmosis
Caused by suspended blood proteins that are too large to cross capillary walls

15. Figure 21-12 Capillary Filtration
Capillary hydrostatic pressure (CHP)
Amino acid
Blood protein
Glucose
Ions
Interstitial fluid
Small solutes
Hydrogen bond
Water molecule
Endothelial cell 1
Endothelial cell 2 15

16. Pressure and Resistance
Capillary Exchange
At arterial end of capillary
Fluid moves out of capillary
Into interstitial fluid
At venous end of capillary
Fluid moves into capillary
Out of interstitial fluid
Transition point between filtration and reabsorption
Is closer to venous end than arterial end
Capillaries filter more than they reabsorb
Excess fluid enters lymphatic vessels

17. Pressure and Resistance
Interplay between Filtration and Reabsorption
Hydrostatic pressure
Forces water out of solution
Osmotic pressure
Forces water into solution
Both control filtration and reabsorption through capillaries

18. Pressure and Resistance
Net Hydrostatic Pressure
Is the difference between
Capillary hydrostatic pressure (CHP)
And interstitial fluid hydrostatic pressure (IHP)
Pushes water and solutes
Out of capillaries
Into interstitial fluid

19. Pressure and Resistance
Net Colloid Osmotic Pressure
Is the difference between
Blood colloid osmotic pressure (BCOP)
And interstitial fluid colloid osmotic pressure (ICOP)
Pulls water and solutes
Into a capillary
From interstitial fluid

20. Pressure and Resistance
Net Filtration Pressure (NFP)
The difference between
Net hydrostatic pressure
And net osmotic pressure
NFP = (CHP – IHP) – (BCOP – ICOP)

21. Figure 21-13 Forces Acting across Capillary Walls
KEY
CHP (Capillary hydrostatic pressure)
BCOP (Blood colloid osmotic pressure)
Arteriole
NFP (Net filtration pressure)
Venule
Filtration
Reabsorption
No net fluid movement
20.4 L/day
24 L/day
35 mm Hg
25 mm Hg
25 mm Hg
25 mm Hg
18 mm Hg
25 mm Hg
NFP  10 mm Hg
NFP  0
NFP  7 mm Hg
CHP  BCOP Fluid forced
out of capillary
CHP  BCOP No net movement of fluid
BCOP  CHP Fluid moves
into capillary 21

22. Figure 21-14 Short-Term and Long-Term Cardiovascular Responses
Autoregulation
Autoregulation is due
to opening and closing
precapillary sphincters
due to local release of
vasodilator or
vasoconstrictor
chemicals from
the tissue.
HOMEOSTASIS RESTORED
Local decrease in resistance and increase in blood flow
HOMEOSTASIS
Local vasodilators released
Normal blood pressure and volume
Inadequate local blood pressure and blood flow
HOMEOSTASIS DISTURBED
• Physical stress (trauma, high temperature) • Chemical changes (decreased O2 or pH, increased CO2 or prostaglandins) • Increased tissue activity
Start 22

23. Figure 21-14 Short-Term and Long-Term Cardiovascular Responses
Central Regulation
Central regulation involves
neuroendocrine mechanisms
that control the total systemic
circulation. This regulation
involves both the
cardiovascular centers
and the vasomotor centers.
Short-term elevation of blood pressure by sympathetic stimulation of the heart and peripheral vasoconstriction
Stimulation of receptors sensitive to changes in systemic blood pressure or chemistry
Activation of cardiovascular centers
Neural mechanisms
Stimulation of endocrine response
Long-term increase in blood volume and blood pressure
Endocrine mechanisms
If autoregulation is ineffective
HOMEOSTASIS RESTORED 23

24. Figure 21-15 Baroreceptor Reflexes of the Carotid and Aortic Sinuses
Cardioinhibitory centers stimulated
Cardioacceleratory centers inhibited
Decreased cardiac output
Responses to Increased Baroreceptor Stimulation
Vasomotor centers inhibited
Baroreceptors stimulated
Vasodilation occurs
HOMEOSTASIS DISTURBED
HOMEOSTASIS RESTORED
Rising blood pressure
Blood pressure declines
Start
HOMEOSTASIS
Normal range of blood pressure 24

25. Figure 21-15 Baroreceptor Reflexes of the Carotid and Aortic Sinuses
HOMEOSTASIS
Normal range of blood pressure
Start
HOMEOSTASIS DISTURBED
HOMEOSTASIS RESTORED
Falling blood pressure
Blood pressure rises
Vasoconstriction occurs
Baroreceptors inhibited
Vasomotor centers stimulated
Increased cardiac output
Responses to Decreased Baroreceptor Stimulation
Cardioacceleratory centers stimulated
Cardioinhibitory centers inhibited 25

26. Figure 21-16 The Chemoreceptor Reflexes
Respiratory centers in the medulla oblongata stimulated
Respiratory Response
Respiratory rate increases
Increasing CO2 levels, decreasing pH and O2 levels
Effects on Cardiovascular Centers
Cardiovascular Responses
Cardioacceleratory centers stimulated
Reflex Response
Increased cardiac output and blood pressure
Chemoreceptors stimulated
Cardioinhibitory centers inhibited
Vasomotor centers stimulated
Vasoconstriction occurs
Start
HOMEOSTASIS DISTURBED
HOMEOSTASIS RESTORED
Elevated CO2 levels, decreased pH and O2 levels in blood and CSF
Decreased CO2 levels, increased pH and O2 levels in blood and CSF
HOMEOSTASIS
Normal pH, O2, and CO2 levels in blood and CSF 26

27. Factors that compensate for decreased blood pressure and volume
Figure 21-17a The Hormonal Regulation of Blood Pressure and Blood Volume
HOMEOSTASIS
Normal blood pressure and volume
HOMEOSTASIS DISTURBED
HOMEOSTASIS RESTORED
Start
Blood pressure and volume fall
Blood pressure and volume rise
Decreasing blood pressure and volume
Short-term
Long-term
Combined Short-Term and Long-Term Effects
Sympathetic activation and release of adrenal hormones E and NE
Increased blood pressure
Increased blood volume
Endocrine Response of Kidneys
Increased cardiac output and peripheral vasoconstriction
Renin release leads to angiotensin II activation
Erythropoietin (EPO) is released
Angiotensin II Effects
Angiotensin II
Antidiuretic hormone released
Aldosterone secreted
Factors that compensate for decreased blood pressure and volume
Thirst stimulated
Increased red blood cell formation 27

28. Factors that compensate for increased blood pressure and volume
Figure 21-17b The Hormonal Regulation of Blood Pressure and Blood Volume
Responses to ANP and BNP
Increased Na loss in urine
Increased water loss in urine
Combined Effects
Reduced thirst
Natriuretic peptides released by the heart
Inhibition of ADH, aldosterone, epinephrine, and norepinephrine release
Reduced blood volume
Peripheral vasodilation
HOMEOSTASIS DISTURBED
HOMEOSTASIS RESTORED
Rising blood pressure and volume
Declining blood pressure and volume
HOMEOSTASIS
Increasing blood pressure and volume
Normal blood pressure and volume
Factors that compensate for increased blood pressure and volume 28

29. Table 21-2 Changes in Blood Distribution during Exercise29

30. 21-4 Cardiovascular Adaptation
Table 21-3
Effects of Training on Cardiovascular Performance
Subject
Heart Weight (g)
Stroke Volume (mL)
Heart Rate (BPM)
Cardiac Output (L/min)
Blood Pressure (systolic/ diastolic)
Nonathlete (rest)
300 60 83
5.0
120/80
Nonathlete (maximum)
104
192
19.9
187/75
Trained athlete (rest)
500
100 53
5.3
Trained athlete (maximum)
167
182
30.4
200/90*
*Diastolic pressures of athletes during maximum activity have not been accurately measured.

31. Figure 21-18 Cardiovascular Responses to Hemorrhaging and Blood Loss
HOMEOSTASIS
Normal blood pressure and volume
HOMEOSTASIS RESTORED
HOMEOSTASIS DISTURBED
Blood pressure and volume rise
Extensive bleeding reduces blood pressure and volume
Falling blood pressure and volume
Responses coordinated by the endocrine system
Elevation of blood volume
Responses directed by the nervous system
Long-Term Hormonal Response
Cardiovascular Responses
ADH, angiotensin II, aldosterone, and EPO released
Peripheral vasoconstriction; mobilization of venous reserve
Increased cardiac output
Stimulation of baroreceptors and chemoreceptors
Pain, stress, anxiety, fear
Higher Centers
Stimulation of cardiovascular centers
General sympathetic activation 31