Cardiovascular System: Blood Flow & Pressure

Question 1

what tissue(s) are present in artery walls; purpose?

Answer 1

• elastic and fibrous
• provides stiffness and flexibility
• act as pressure reservoirs allowing for smooth blood flow
• elastin can act like springs (elastic force stored and passive recoil)

Question 2

how can arteries act like pressure reservoirs

Answer 2

• arteries have low compliance
• large ↑ in pressure won’t lead to large degree of expansion of vessel wall
• ensures smooth flow of blood even when heart is in diastole

Question 3

how can veins act like volume/blood reservoirs

Answer 3

• veins have high compliance
• large ↑ in pressure leads to large ↑ in vessel wall expansion

Question 4

define compliance

Answer 4

measure of how pressure of a vessel will change with a change in volume

Question 5

how are systolic and diastolic blood pressure different

Answer 5

systolic = maximum; diastolic = minimum

Question 6

what causes systolic blood pressure

Answer 6

ejection of blood into aorta

Question 7

what causes diastolic blood pressure

Answer 7

elastic recoil

Question 8

what does diastolic blood pressure refer to

Answer 8

slow decline in pressure to minimum right before the next systole

Question 9

define MAP

Answer 9

• mean arterial pressure
• average pressure in arteries that occurs during one cardiac cycle

Question 10

how do we measure blood pressure

Answer 10

• arterial pressure estimated using brachial artery
• systolic (SP)/diastolic (DP)

Question 11

what does korokoff sound refer to

Answer 11

“vibrations” made from pressure in artery when checking blood pressure

Question 12

how can we determine pulse pressure (PP)

Answer 12

systolic (SP) - diastolic (DP)

Question 13

what is the importance of pulse pressure

Answer 13

high pulse pressure (especially amongst older individuals) can indicate hardening of the arteries (thickened and rigid from plaque) leading to a decrease in stretch

Question 14

how can we find MAP

Answer 14

[SP + (2*DP)] / 3

MAP is weighted mean (single cardiac cycle is at maximum for short amt of time whereas minimum is at twice the amt of time)

Question 15

describe arterioles

Answer 15

• smaller than arteries
• aka resistance vessels
• connectors of arteries to capillaries or metarterioles
• have rings of smooth muscle that regulate radius and resistance

Question 16

how are arterioles and resistance related

Answer 16

• arterioles are best site where resistance to flow can be regulated
• > 60% of total peripheral resistance attributed to arterioles
• largest pressure drop in vasculature occurs along here since they have greatest resistance to blood flow

Question 17

define TPR

Answer 17

• total peripheral resistance
• combined resistances of all blood vessels with the circuit in the systemic system

Question 18

how is resistance in arterioles regulated by

Answer 18

contraction/relaxation of circular smooth muscle

Question 19

what are the main functions of arterioles

Answer 19

• control blood flow to individual capillary beds
• regulate MAP

Question 20

how can arteriole radius change

Answer 20

• dependent on contraction state of smooth muscle in arteriole wall
• arteriolar tone
• vasoconstriction
• vasodilation

Question 21

how does vasodilation affect arteriole radius

Answer 21

↑ radius due to ↓ contraction

Question 22

how does vasoconstriction affect arteriole radius

Answer 22

↓ radius due to ↑ contraction

Question 23

define arteriolar tone

Answer 23

when contraction level (radius) is independent of extrinsic influences

Question 24

describe hyperemia

Answer 24

higher than normal blood flow rate

Question 25

list the ways that intrinsic control of arteriole smooth muscle happens

Answer 25

• changes in metabolic activity
• changes in blood flow
• stretch of smooth muscles in arterioles
• local chemical messengers

Question 26

describe how changes in metabolic activity affect arteriole smooth muscle

Answer 26

• vasodilation generally happens with ↑ metabolic activity
• vasoconstriction generally happens with ↓ metabolic activity
• smooth muscle sensitive to ECF conditions and respond to CO2, K+, H+ concentrations
• EX active hyperemia

Question 27

how does active hyperemia happen

Answer 27

changes from O2 and CO2 in response to metabolic activity change

Question 28

how does reactive hyperemia happen

Answer 28

changes from O2 and CO2 in response to blood flow change

Question 29

arterial blood pressure refers to pressure in

Answer 29

aorta

Question 30

draw out the flow of smooth muscle stretch in arterioles

Answer 30

Increase in perfusion pressure → arteriolar smooth
muscles contract → vasoconstriction → increased
resistance → decreased flow

Question 31

describe myogenic response of smooth muscle in arterioles

Answer 31

• reflex response of afferent arterioles to changes in blood pressure
• some tissues have stretch-sensitive fibres that stretch when BP in arterioles ↑

Question 32

which local chemical messengers are important for intrinsic control of arteriole smooth muscle and why

Answer 32

• nitric oxide and prostacyclin (vasodilation)
• endothelin-I (vasoconstriction)

Question 33

what are some extrinsic factors of arteriole smooth muscle control

Answer 33

• sympathetic nerves
• epinephrine
• vasopressin (ADH)
• angiotensin II

Question 34

how do sympathetic nerves affect arteriole radius, and how does that affect MAP

Answer 34

vasoconstriction; ↑ MAP

Question 35

how does epinephrine affect arteriole radius, and how does that affect MAP

Answer 35

• depends on the receptor
• α adrenergic: vasoconstriction
• β2 adrenergic: vasodilation
• ↑ MAP bc α is dominant

Question 36

how does vasopressin affect arteriole radius, and how does that affect MAP

Answer 36

vasoconstriction; ↑ MAP

Question 37

how does angiotensin II affect arteriole radius, and how does that affect MAP

Answer 37

vasoconstriction; ↑ MAP

Question 38

how does blood flow regulate in microcirculation

Answer 38

through arterioles, metarterioles, precapillary sphincters

Question 39

define microcirculation

Answer 39

• simplest way to regulate exchange of material across capillary walls
• arterioles to precap sphincter to metarterioles/capillaries to venules

Question 40

describe precapillary sphincter

Answer 40

rings of smooth muscle before capillary bed

Question 41

what are the transport mechanisms of capillary wall material exchange

Answer 41

• simple diffusion
• mediated transport
• transcytosis

Question 42

describe metarterioles

Answer 42

• intermediate structure between arterioles and capillaries
• rings of smooth muscle
• acts like shunts from arterioles to venules

Question 43

why are precapillary sphincters important

Answer 43

• they regulate flow thru capillary bed
• contraction leads to capillary contraction leading to ↓ in flow thru capillary bed

Question 44

when there is high or low resistance to flow in metarterioles, where does blood flow occur

Answer 44

inc in capillary beds; dec in capillary beds

pulsing manner between metarterioles and capillary beds based on conditions

Question 45

what are the transport mechanisms of capillary wall material exchange

Answer 45

• simple diffusion thru membrane cells and pores
• mediated transport
• transcytosis

Question 46

describe bulk flow across capillary walls

Answer 46

• capillary walls are water- and small solute permeable
• fluids are able to move from blood to interstitial fluid (vice versa)

Question 47

what is filtration

Answer 47

blood to interstitial fluid material transport

Question 48

what is absorption

Answer 48

interstitial fluid to blood material transport

Question 49

define edema

Answer 49

shift of fluid from plasma to interstitial fluid (ie swelling)

Question 50

define starling forces; what are some examples

Answer 50

• forces that drive movement of fluid in/out of cell
• capillary hydrostatic pressure (P CAP)
• interstitial fluid hydrostatic pressure (P IF)
• capillary osmotic pressure (π CAP)
• interstitial fluid osmotic pressure (π IF)

Question 51

draw out material exchange b/w plasma and interstitial fluid

Answer 51

…

Question 52

define capillary hydrostatic pressure (P CAP) and its direction of force

Answer 52

hydrostatic pressure exerted by presence of fluid inside the capillary; filtration

Question 53

define interstitial fluid hydrostatic pressure (P IF) and its direction of force

Answer 53

hydrostatic pressure exerted by presence of fluid outside the capillary; absorption

Question 54

define capillary osmotic pressure (π CAP) and its direction of force

Answer 54

osmotic force due to presence of proteins in plasma; absorption

Question 55

define capillary osmotic pressure (π IF) and its direction of force

Answer 55

osmotic force due to presence of proteins in interstitial fluid; filtration

Question 56

define net filtration pressure (NFP) and its direction of force

Answer 56

• difference bw forces for filtration and absorption (eqn = filtration pressure - absorption pressure);

Answer is + then filtration occurs at arteriole end, - then absorption occurs at venule ends

Question 57

why is P cap displayed as a range in values

Answer 57

• pressure varies across capillary beds
• initial value represents venous ends
• end value represents arteriole ends

Question 58

list factors that influence venous pressure and return

Answer 58

• skeletal muscle pump
• respiratory pump (inspiration/exhalation)
• blood volume
• venomotor tone

Question 59

how do skeletal muscle pumps affect venous pressure and return

Answer 59

• skeletal muscles contract (squeezing of veins, blood flows to heart) and relax (blood flows to veins)
• there are one-way valves in peripheral veins, whereas none in central veins

Question 60

describe inspiration

Answer 60

• diaphragm moves down which ↓ pressure in thoracic cavity and ↑ pressure in abdominal cavity
• gradient is made to favour blood movement in TC
• blood moves from abdominal veins to central veins in TC which causes blood to flow towards the heart

Question 61

describe exhalation

Answer 61

reversal of pressure and creates pressure gradient that would favour bkwd movement of blood (but doesn’t happen)

Question 62

why does bkwd movement of blood from exhalation not happen

Answer 62

due to the one-way valves

Question 63

what is the relationship b/w blood volume and venous pressure

Answer 63

directly proportional (inc leads to inc, dec leads to dec)

Question 64

what is venomotor tone

Answer 64

smooth muscle tension in veins

Question 65

what are the effects of increased venomotor control

Answer 65

• constriction of veins ↑ venous pressure which makes blood move towards heart
• ↑ wall tension reduces compliance which ↑ venous pressure and ↑ stroke volume

Question 66

define stroke volume

Answer 66

volume of blood ejected from each ventricle during a single heartbeat

Question 67

describe the flow of oxygenated blood in the heart

Answer 67

• arteries carry oxygenated blood to arterioles then capillary beds
• gas exchange occurs
• blood flows to venules then veins then vena cava then back to heart to be oxygenated again

Question 68

what is the significance of large arteries

Answer 68

have little resistance to flow

Question 69

how is it that the diameter and thickness of the veins is so low

Answer 69

the pressure of blood flowing thru it is much lower, which allows it to withstand the flow

Question 70

what is the importance of valves in veins

Answer 70

prevent back flow since it’s going upward

Question 71

draw out the generic vasculature of blood flow to and away from heart

Answer 71

…

Question 72

what is diastole

Answer 72

small period of time when the heart is not pumping

Question 73

what is the importance of elastin fibres in vessel walls

Answer 73

• act like a spring
• during systole, pressure of left ventricle is greater than pressure in arteries
• this causes blood to flow into arteries which leads to a stretch to compensate for increased volume
• in diastole, valves close and allow walls to passively recoil inwards to help push blood along (result of stored elastic force)

Question 74

define elasticity

Answer 74

resistance to change