Physiology of Circulation

Question 1

key players in circulation

Answer 1

Heart = pump
Arteries = pressure reservoirs and conduits
Arterioles = resistance vessels
Capillaries = sites of exchange
Veins = conduits and blood reservoirs

Question 2

Blood Flow:

Answer 2

• The volume of blood flowing through a vessel, organ, or circulation system in a period of time
• Blood flow remains fairly constant, and it is relatively equivalent to CO

Question 3

Blood Pressure

Answer 3

• The force per unit area exerted on a vessel wall by the contained blood
• Typically measured in the largest arteries near the heart
• The hydrostatic pressure gradient – the difference in blood pressure within the vascular system – provides the driving force to keep blood moving

Question 4

Resistance:

Answer 4

• Opposition to flow, the amount of friction that blood encounters
• Most friction is encountered well away from the heart – total peripheral resistance (TPR)
• Sources of resistance: blood viscosity, vessel length, and vessel diameter

Question 5

Blood Viscosity

Answer 5

internal resistance to flow that exists in all fluids
- Thickness or “stickiness” of the fluid
- Greater viscosity = less movement
- Blood viscosity is fairly constant – exceptions being the anemias and polycythemias

Question 6

Blood Vessel Length

Answer 6

Longer vessel = greater resistance

Question 7

Blood Vessel Diameter

Answer 7

Smaller diameter = greater resistance

Question 8

mechanics of blood flow

Answer 8

flows from high to low pressure against resistance

Question 10

Relationship of Flow, Pressure, and Resistance

Answer 10

• Blood viscosity and vessel length are relatively constant
• Blood vessel diameter changes frequently and significantly alters TPR
• Example: River-Bank Flow
• Resistance varies inversely with the 4th power of the vessel radius
• If the size of the vessel doubles, resistance drops to 1/16th of its original valve
• Smaller-diameter arterioles are the major determinants of TPR
• Turbulence – such as the disrupted flow caused by atherosclerosis – increases resistance

Question 11

flow, pressure, resistance equation

Answer 11

F = delta P / TPR
- TPR is the more important factor influencing blood flow
- TPR is changed by changes in the diameter of the small arterioles

Question 12

Overview of Blood Pressure

Answer 12

• Blood flows through the vessels on a pressure gradient – always from higher to lower pressure!
• The pumping action of the heart generates blood flow – resistance to flow generates pressure
• Systemic pressure is highest in the aorta and steadily declines
• Steepest drop occurs in the arterioles – where resistance is highest
• Pressure in the right atrium is 0mmHg

Question 13

2 factors of arterial blood pressure

Answer 13

1. How much can the elastic arteries close to the heart stretch?
2. What volume of blood is forced into the arteries?
   - Blood pressure is pulsatile – it rises and falls in a regular fashion

Question 14

Systolic Pressure

Answer 14

blood is expelled into the aorta, the walls are stretched, aortic pressure peaks
Average = 120 mmHg

Question 15

Diastolic Pressure:

Answer 15

aortic walls recoil, aortic valve closes, and pressure drops
Average = 80 mmHg

Question 16

how is blood driven further forward

Answer 16

The volume and energy of the blood stored in the elastic arteries during systole is given back during diastole, and blood is driven further forward

Question 17

Pulse Pressure

Answer 17

the difference in systolic and diastolic pressure
- Increased SV and contractility can temporarily increase PP
- Atherosclerosis chronically increases pulse pressure

Question 18

MAP - mean arterial pressure

Answer 18

the pressure that propels blood into the tissues – useful tool for determining tissue perfusion
- Because diastole lasts longer than systole, MAP is NOT simply the halfway point between SBP and DBP
- diastolic pressure + pulse pressure/3
- Both MAP and PP decrease with increasing distance form the heart

Question 19

Pulse

Answer 19

• Typically, the radial or carotid pulse
• Pulse Points = pressure points
• Used to stop blood flow during hemorrhage
• Pulses are monitored to assess the effects of activity, postural changes, and emotions

Question 20

Blood Pressure

Answer 20

• Typically, measured in the left brachial artery
• Auscultatory Method: practitioner uses a sphygmomanometer and a stethoscope to listen to the Sounds of Korotkoff

Question 21

Capillary Blood Pressure

Answer 21

• Blood pressure entering a capillary bed is ~35 mmHg
• Blood pressure exiting a capillary bed is ~17 mmHg
• Secondary to the fragility of the capillary bed, low pressures are essential
• Capillaries are so permeable that even low pressure can adequately force filtrate out of the blood stream

Question 22

Venous Blood Pressure

Answer 22

• Venous pressure is far less pulsatile – pressure gradients are less steep
• Low venous pressure results from TPR – energy has been dissipated out
• Despite valves, venous pressure is too low for adequate venous return

Question 23

Three Functional Adaptations of venous blood pressure

Answer 23

1. muscular pump
2. respiratory pump
3. sympathetic vasoconstriction

Question 24

muscular pump

Answer 24

activity of the skeletal muscles surrounding the deep veins squeezes the veins and propels blood towards the heart

Question 25

respiratory pump

Answer 25

during breathing, pressure changes in the ventral body cavity propel blood towards the heart

Question 26

Sympathetic Vasoconstriction

Answer 26

during SNS firing, veins constrict, venous volume is reduced, and blood is pushed towards the heart

Question 27

venous blood pressure flow

Answer 27

increased venous return > increased stroke volume > increased cardiac output

Question 28

3 key variables in regulation of blood pressure

Answer 28

1. Cardiac Output
2. Total Peripheral Resistance
3. Blood Volume

Question 29

regulation of blood pressure

Answer 29

• Blood Pressure (BP) varies directly with CO and TPR
• Anything that increases CO or TPR will increase BP
• Anything that increases HR or SV will increase BP
• Any change that threatens BP homeostasis will be compensated for

Question 30

Short Term Regulation: Neural Controls

Answer 30

Neural controls can alter both CO and TPR
Two Main Goals:
1. Maintain adequate MAP by altering blood vessel diameter – small changes in vessel diameter can cause substantial changes in TPR - and therefore BP
*Example: perfusion of the heart and brain during low blood volume
2. Alter blood distribution to respond to specific demands
*Example: during exercise, blood is shunted to the skeletal muscles

Question 31

baroreceptors

Answer 31

• pressure-sensitive mechanoreceptors that respond to changes in arterial pressure and stretch
• most neural controls operate via reflex arcs involving these
• Inputs from baroreceptors are integrated into the Cardiovascular Center of the medulla oblongata
• Outputs travel via autonomic fibers to the heart and the vascular smooth muscle

Question 32

Neural Controls: 
Role of the Cardiovascular Center

Answer 32

The cardiovascular center contains cardioacceleratory, cardioinhibitory, and vasomotor centers

Question 33

vasomotor center

Answer 33

transmits impulses along sympathetic efferent fibers called vasomotor fibers

Question 34

vasomotor fibers

Answer 34

exit the spinal cord (T1-L2) and innervate the smooth muscle of the blood vessels - mainly arterioles

Question 35

vasomotor tone

Answer 35

a result of the arterioles almost always moderately constricting

Question 36

sympathetic activity and vasoconstriction

Answer 36

Increased sympathetic activity will increase vasoconstriction and raise BP; decreased sympathetic activity will decrease vasoconstriction and lower BP

Question 37

Neural Controls: Baroreceptor Reflexes

Answer 37

Rising arterial BP activates baroreceptors in the carotid sinuses (dilations within the internal carotid arteries), the aortic arch, and the walls of nearly every large artery of the head/neck
- Baroreceptors send impulses to the cardiovascular center –cardioinhibitory center is stimulated; vasomotor and cardioacceleratory centers are inhibited

Question 38

Net Result

Answer 38

decreased blood pressure
* Via vasodilation and decreased cardiac output
- Rapid-responding baroreceptors protect against short-term changes in BP
* Ex: Orthostatic Hypotension – a failure of the baroreceptor reflex

Question 39

Chemoreceptors

Answer 39

receptors that respond to changes in levels of CO2, H+, and O2 in the blood
- stimulate the cardioacceleratory center to increase CO and the vasomotor center to increase vasoconstriction when:
* CO2 level rises
* pH level falls
* O2 level falls
- Located close to the baroreceptors, the most prominent chemoreceptors are the carotid bodies and the aortic bodies
- play a larger role in regulating respiratory rate

Question 40

Neural Controls: Higher Brain Centers

Answer 40

• Reflexes regulating blood pressure are integrated into the medulla oblongata of the brain stem – the cerebral cortex and hypothalamus are not involved in routine regulation of BP
• Higher brain centers can modify arterial pressure via relays to the brain stem
• Examples: fight or flight response, redistribution of blood flow by the hypothalamus

Question 41

Adrenal Medulla Hormones: Epinephrine and Norepinephrine

Answer 41

• Released in response to stress
• Enhance sympathetic response by increasing CO and promoting vasoconstriction

Question 42

Angiotensin II

Answer 42

• Renin is released by the kidneys when blood pressure or volume are low
• Renin generates Angiotensin II
• Promotes intense vasoconstriction to rapidly increase blood pressure
• Stimulates release of ADH and Aldosterone – both participate in longer term BP regulation

Question 43

Atrial Natriuretic Peptide (ANP)

Answer 43

• Produced by the atria of the heart to reduce blood volume and pressure
• Antagonizes aldosterone, promotes vasodilation, stimulates excretion of sodium and water

Question 44

Antidiuretic Hormone (ADH)

Answer 44

• Also called vasopressin, produced by the hypothalamus
• Stimulates the kidneys to conserve water and widespread vasoconstriction

Question 45

Long Term Regulation: Renal Mechanisms

Answer 45

Longer term blood pressure controls regulate blood volume
- Increased BV = Increased BP and vice versa
- The kidneys are a key player in long term regulation

Question 46

Direct Renal Mechanism

Answer 46

• When BV or BP rise, fluid is filtered from the bloodstream to the kidneys more rapidly -> increased urine -> decreased BV and BP
• The opposite also occurs

Question 47

Indirect Renal Mechanism

Answer 47

• When BP declines, the kidneys release the enzyme renin into the blood
• Renin splits the plasma protein angiotensinogen to make angiotensin I
• Angiotensin I is converted to angiotensin II by angiotensin converting enzyme (ACE)
• ACE is found in the capillary endothelium of various body tissues – especially the lungs

Question 48

The Four Actions of Angiotensin II

Answer 48

1. Stimulates the adrenal cortex to secrete aldosterone
2. Stimulates the posterior pituitary gland to secrete ADH
3. Triggers the sensation of thirst
4. Vasoconstriction to increase TPR

Question 49

Homeostatic Imbalances

Answer 49

Hypertension (HTN): chronically elevated blood pressure
SBP > 130 mmHg; DBP > 80 mmHg
30% of adults over 50 are hypertensive
HTN strains the heart and damages the blood vessels
Prolonged HTN is a major cause of heart failure, vascular disease, renal failure, and CVA

Question 50

Primary (or Essential) HTN

Answer 50

Hypertension without a specific, underlying cause
- Environmental, contributing factors:
* Heredity, Diet, Obesity, Age, Diabetes Mellitus, Stress, Smoking
- Primary HTN can be controlled with improved diet, increased exercise, stopping smoking, managing stress, and taking anti-HTN medications
- Commonly used anti-HTN medications: diuretics, beta-blockers, calcium-channel blockers, ACE inhibitors, and angiotensin II receptor blockers

Question 51

Secondary HTN

Answer 51

10% of HTN cases
Secondary HTN as an identifiable cause:
- Obstructed renal arteries
- Kidney disease
- Endocrine disorders – hyperthyroidism or Cushing’s Disease

Question 52

Hypotension

Answer 52

Blood Pressure < 90/60 mmHg
- Often hypotension is harmless – or even healthy!
- Chronic hypotension can be a sign of a serious underlying condition
* Addison’s Disease: inadequate function of the adrenal cortex
* Hypothyroidism
* Severe malnutrition
- Hypotension is problematic when it results in inadequate tissue perfusion

Question 53

Circulatory Shock

Answer 53

blood vessels are inadequately filled; blood cannot circulate normally – body tissues are not adequately perfused

Question 54

Hypovolemic Shock

Answer 54

blood volume is too low
- Results from large scale blood or fluid loss
- HR will increase in response to a dramatic drop in blood volume
- Intense vasoconstriction will shift blood out of reservoirs
- Treatment: replace fluid volume ASAP

Question 55

Vascular Shock:

Answer 55

blood volume is normal; poor circulation because of extreme vasodilation and lost TPR
- Anaphylactic: lost vasomotor tone in response to an allergic reaction
- Neurogenic: failure of the autonomic nervous system
- Septic: severe systemic bacterial infection