Module 3.2 - Cardiovascular Physiology

Question 1

initiation of heart beat

Answer 1

heart has an intrinsic beat (ability to beat on its own)
=> auto-rhythmicity
- can beat outside body

Question 2

coordination of contraction

Answer 2

of myocardial cells of atria/ventricles through specialised conducting tissue

Question 3

AP of ventricular contractile fibre

Answer 3

• rapid depolarisation as fast as nerve AP due to being Na+ driven
• contraction whenever there is Ca2+ => length of contraction is determined by width of plateau

Question 4

electrocardiogram - Pwave

Answer 4

atrial depolarisation
=> atrial contraction

Question 5

electrocardiogram - QRS complex

Answer 5

• onset of ventricular depolarisation
• atrial repolarisation (but wave is lost within much bigger QRS complex => shape doesn’t represent)
• spread of activation through ventricles
• shape of wave due to direction of spread

Question 6

electrocardiogram - S-T segment

Answer 6

when whole ventricle is depolarised (extended plateau of AP)
=> electrical balance
=> no voltage change
elevation/depression if abnormalities in ventricular wall => chest pain

Question 7

electrocardiogram - Twave

Answer 7

• ventricular repolarisation (not as rapid)
  => relaxation / start of diastole

Question 8

electrocardiogram - T-P segment

Answer 8

when all cardiac myocytes are at RMP

Question 9

chronotrope

Answer 9

something that changes heart beat
- positive chronotrope: increase heart rate

Question 10

inotrope

Answer 10

something that changes in contractility/contraction power
- positive => increase, negative => decrease

Question 11

regulation of heart rate

Answer 11

(autonomic) nervous system regulation of heart rate originates in the cardiovascular centre of medulla oblongata

Question 12

input to cardiovascular centre

Answer 12

from higher brain centres (forebrain) + receptors (proprio, baro, chemo)

Question 13

output to effectors

Answer 13

parasympathetic (vagus) / sympathetic nerves to heart+ vasomotor nerves (sympathetic) to blood vessels for vasoconstriction

Question 14

sympathetic / parasympathetic balance at rest

Answer 14

SA node is dominated by vagal activity at rest (50-70 bpm)

Question 15

regulation of blood pressure

Answer 15

ANS (autonomic nervous system) innervation of heart/baroreceptor complexes that help regulate BP

Question 16

regulation of BP - nerve direction

Answer 16

• baroreceptors -> cardiovascular centre in medulla
• cardiovascular centre ->
  1) SA/AV node - parasympathetic
  2) spinal cord
• cardiac accelerator nerves -> spinal cord (thoracic level) -> sympathetic trunk ganglion -> SA/AV node, ventricular myocardium (sympathetic)

Question 17

BP hormones

Answer 17

circulating hormones
- adrenalin/noradrenalin
- ion concentrations
etc.

Question 18

proprioceptor input

Answer 18

major stimulus that accounts for rapid rise in HR at onset of physical activity

Question 19

hyperthermia

Answer 19

increases HR

Question 20

sympathetic nervous system increases

Answer 20

• HR
• SV
• spontaneous depolarisation of SA/AV nodes
• contractility of ventricles/atria

Question 21

parasympathetic nervous system decreases

Answer 21

• HR
• rate of spontaneous depolarisation of SA/AV nodes

Question 22

dicrotic wave

Answer 22

rebound from aortic valve closing

Question 23

can you have negative blood pressure

Answer 23

yes

Question 24

cardiac output

Answer 24

amount/volume of blood ejected into aorta per minute

Question 25

cardiac output unit

Answer 25

mL/min
L/min

Question 26

average cardiac output

Answer 26

5 L/min
- between 4-7 L/min at rest
- can go up to 5x e.g during exercise
- 40 L/min for athletes

Question 27

cardiac output equation

Answer 27

= HR x SV

Question 28

cardiac reserve

Answer 28

difference between max. cardiac output and cardiac output at rest (rates at which heart pumps blood)
- shows maximum capacity of heart to pump blood

Question 29

normal heart rate

Answer 29

normal = 60-100 bpm
- controlled by SA node (sympathetic/parasympathetic activity)

Question 30

normal stroke volume

Answer 30

50-100 mL per beat

Question 31

stroke volume equation

Answer 31

= end diastolic volume (EDV) - end systolic volume (ESV)

Question 32

EDV

Answer 32

max. volume (most full)
- 120-140 mL

Question 33

ESV

Answer 33

min. volume
- 50-70 mL

Question 34

frank-starling law of heart

Answer 34

in stable system, venous return (diastole) = cardiac output (systole)
- increased return => heart works harder => stretch of myocytes => energy of ventricular contraction => forcefulness of contraction => SV increases
- greater force of contraction can occur if the heart muscle is stretched first

Question 35

factors determining SV

Answer 35

1) preload
2) contractility
3) afterload

Question 36

preload

Answer 36

force that stretches cardiac muscle prior to contraction
- increased diastolic filling => increase EDV => increased SV

Question 37

factors changing diastolic filling

Answer 37

• ∆venous return
• ∆blood volume (more blood in system => more blood to heart)
• ∆filling time (duration of ventricular diastole)
• ∆respiratory pump (inhaling => negative pressure around lungs and heart shares same space => also affected - decreased diastolic filling)
• ∆compliance (MI - myocardial infarction damage - becoming stiffer, can’t contract as well due to scarred tissue, attack, disease etc.)

Question 38

venous return

Answer 38

amount of blood returning to heart each min from venous system

Question 39

contractility

Answer 39

performance (forcefulness of contraction) of heart (esp left ventricle) at a given preload/afterload
- aka inotropy
- increased contractility => decreased ESV => increased SV

Question 40

factors changing contractility

Answer 40

• autonomic nervous system (increased sympathetic => increased contractility)
• venous return (increased preload => increased contractility)
• [Ca2+] (all factors affecting contractility act by changing [Ca2+])
• drugs (inotropes) - target contractility not longetivity as it doesn’t address underlying conditions
• ion balances
• circulating levels of various hormones

Question 41

afterload

Answer 41

amount of pressure that the heart needs to exert to eject blood during ventricular contraction (what heart works against)
- increased afterload => increased ESV => decreased SV

Question 42

factors affecting afterload

Answer 42

• hypertension - high blood pressure
• valve pathologies
• aortic plaques - constriction in aorta

Question 43

ventricular pressure-volume relationship

Answer 43

A: mitral valve opens
B: mitral valve closes
C: aortic valve opens
D: aortic valve closes

Question 44

ventricular pressure-volume relationship - A-B

Answer 44

ventricular filling
- first: pressure decreased due to suction effects of relaxing muscle
- later: pressure rises passively as volume increases

Question 45

ventricular pressure-volume relationship - B-C

Answer 45

isovolumetric contraction
- pressure increases steeply
- no change in volume as aortic valve closed

Question 46

ventricular pressure-volume relationship - C-D

Answer 46

blood ejection

Question 47

ventricular pressure-volume relationship - D-A

Answer 47

isovolumetric relaxation

Question 48

stroke work

Answer 48

heart’s pumping action is achieved by mechanical work of myocardium
= area of pressure-volume curve of ventricular contraction (total external work carried out by ventricles during one cardiac cycle)

Question 49

stroke work equation

Answer 49

work done = ∆pressure x ∆volume

Question 50

blood volume distribution

Answer 50

1) systemic veins and venules (blood reservoirs) - 64%
2) systemic arteries and arterioles - 13%
3) pulmonary veins - 9%
4) heart - 7%
5) systemic capillaries - 7%

Question 51

blood pressure

Answer 51

pressure of circulating blood against vessel walls which can vary throughout cardiac cycle

Question 52

mean arterial pressure (MAP) equation

Answer 52

cardiac output (CO) x total peripheral resistance (TPR)

Question 53

total peripheral resistance

Answer 53

amount of force affecting resistance of blood flow through circulatory system

Question 54

poiseuille’s law

Answer 54

describes flow is related to factors such as velocity

Question 55

if CO decreases while MAP constant

Answer 55

TPR increases by sympathetic stimulation of smooth muscles => reduce diameter (vasoconstriction) => increase resistance

Question 56

blood hydrostatic pressure (BHP)

Answer 56

force exerted by blood confined within vessels
- arterial: ~35 mm Hg
- venous: ~16 mm Hg

Question 57

blood colloid osmotic pressure (BCOP)

Answer 57

• aka oncotic pressure
  form of osmotic pressure induced by proteins in blood
• ~26 mm Hg

Question 58

decreasing BCOP

Answer 58

deficiency/low plasma protein level

Question 59

hemorrhage

Answer 59

release of blood from broken blood vessel

Question 60

interstitial fluid hydrostatic pressure (IFHP)

Answer 60

mechanical pressure exerted on interstitial fluid by elastic recoil of tissues in any region of body
- ~0 mm Hg

Question 61

interstitial fluid osmotic pressure (IFOP)

Answer 61

osmotic force which is the result of differences in water conc. between plasma and interstitial fluid
- ~1 mm Hg

Question 62

capillary exchange

Answer 62

exchange/movement of material between blood and interstitial tissue/fluid across capillary wall

Question 63

ways of capillary exchange

Answer 63

1) diffusion
2) trancytosis
3) bulk flow/filtration

Question 64

diffusion

Answer 64

solute exchange, down conc grad

Question 65

trancytosis

Answer 65

vesicles (contents wrapped in membrane) of large, lipid-soluble (insoluble in H2O/blood)
e.g insulin

Question 66

bulk flow/filtration

Answer 66

• passive movement of flow + substances
• faster than diffusion alone
• net flow is driven by difference between balance of hydrostatic pressure / osmotic pressure gradients (starling’s law of capillaries)

Question 67

net filtration - favours filtration

Answer 67

BHP + IFOP
- arterial: 35 + 1
- venous: 16 + 1

Question 68

net filtration - favours reabsorption

Answer 68

BCOP + IFH
- arterial and venous: 26 + 0

Question 69

pressures

Answer 69

(BHP + IFOP) - (BCOP + IFHP)
- arterial: +10 mm Hg
- venous: -9 mm Hg

Question 70

negative pressure means

Answer 70

favours reabsorption

Question 71

organ without lymph vessels

Answer 71

brain - glymphatic system

Question 72

oedema/edema

Answer 72

accumulation of fluid outside vessels
- common symptom of many conditions
- most obvious in legs due to gravity

Question 73

hypertension =>

Answer 73

arterial BHP increases
- vasoconstriction
- increased arterial tone

Question 74

arterial tone

Answer 74

degree of constriction relative to maximally dilated state

Question 75

kidney disease =>

Answer 75

loss of blood proteins (more in urine) => BCOP decreases => low capillary reabsorption

Question 76

heart failure =>

Answer 76

venous BHP increases

Question 77

long-haul travel =>

Answer 77

venous volume increases as heart tries to hold volume (more filled up) => SV increases
venous BHP increases

Question 78

how does long-haul travel increase BHP

Answer 78

• gravity
• leg swelling => venous compression
  => blood pools in venous sytem
  => BHP increased without changing overall blood volume

Question 79

venous volume increases =>

Answer 79

capillary permeability increases => IFOP increases

Question 80

nervous control effect on TPR

Answer 80

decreased frequency of sympathetic nerve activity => vasodilation in systemic blood vessels => increased radius of vessel lumen => decreased resistance to blood flow => decreased total peripheral resistance

Question 81

effect of blood volume on nerve activity

Answer 81

decreased blood volume
=> decreased EDV => decreased SV
and
=> decreased BP => baroreceptors sense => increase sympathetic activity to heart + decreased parasympathetic / vagal
(reflex neural mechanisms that respond to change in arterial pressure)

Question 82

reason for having parallel structure of circulatory structure

Answer 82

allows same hydrostatic gradient at each organ

Question 83

relationship between bloodflow and total cross-sectional area in different blood vessel types

Answer 83

velocity is inversely proportional to cross-sectional area (of all of that type of blood vessel)

Question 84

to increase blood flow

Answer 84

1) increase cardiac output (increase HR and/or SV)
2) redirect existing cardiac output/blood flow to organs that need it (vasoconstriction)

Question 85

what control direction of bloodflow

Answer 85

precapillary sphincters

Question 86

coping with haemorrhage - challenge to homeostasis

Answer 86

• vasoconstriction
• increase HR (need CO to maintain blood)
• clotting to stop bleeding (+ maintain BP)
• redirection
• increase SV by increasing contractility (not much by venous return as blood is being lost

Question 87

baroreceptors

Answer 87

• respond to ‘stretch’ in arterial wall
• signals connect up to brain via cranial nerves

Question 88

baroreceptors and tonicity

Answer 88

tonically active
- can respond to increases/decreases in BP (not on/off)

Question 89

baroreceptor location

Answer 89

• carotid sinus
• aortic arch

Question 90

carotid sinuses

Answer 90

sits above bifurcation of carotid artery (into two other arteries) along with carotid body
- one of smallest organs

Question 91

vascular tone - increased electrical signals from neuron =>

Answer 91

norepinephrine release onto receptors increases => vasoconstriction / increased HR => increased BP

Question 92

vascular tone and blood vessel size

Answer 92

effect of hormones in response to electrical signals is esp prominent in small arteries/arterioles due to ratio of muscle
- bigger change is required for bigger arteries to cause change

Question 93

total spinal anesthesia

Answer 93

block transmission across neurons in spinal cord from a specific point (below level of heart) down

Question 94

muscle activity in veins and BP

Answer 94

there is smooth muscle in veins but this has a smaller effect on BP due to low pressure, instead affects venous return

Question 95

what increases BP

Answer 95

increased:
- HR
- TPR
- VR (venous return)

Question 96

possible stimuli of change in BP

Answer 96

• haemorrhage
• drinks (1L of water/energy drink)
• standing up quickly
• temperature (hot day => peripheral vasodilation)

Question 97

resistance and radius

Answer 97

resistance is inversely proportional to radius^4

Question 98

redundant physiology

Answer 98

multiple systems that overlap in different ways to affect same variable

Question 99

slow response to increased blood volume

Answer 99

blood volume homeostasis (decreasing) via compensation by kidneys
- need to solve fundamental issue

Question 100

angiotensin II

Answer 100

vasoconstrictor peptide
- increased as a result of low BP (not affected by cardiac sympathetic activity)

Question 101

glossopharyngeal nerves

Answer 101

from carotid sinus -> cardiovascular centre

Question 102

vascular resistance is

Answer 102

1) size of lumen
- inversely proportional to radius^4
2) viscosity
- directly proportional
3) (total) length of blood vessel
- directly proportional

Question 103

alpha receptors

Answer 103

• skeletal muscle
• smooth muscle (blood vessels - arteries/arterioles)

Question 104

beta receptors

Answer 104

• cardiac muscle (myocardium): ventricular muscles, SA/AV nodes

Question 105

Starling’s Law of the Capillaries

Answer 105

the volume of fluid reabsorbed at the venous end of a capillary is nearly equal to the volume of fluid filtered out at the arterial end

Question 106

vagus nerve

Answer 106

only affects heart rate
- NOT contractility/inotropy or vasomotor

Question 107

right subclavian vein

Answer 107

behind collar bone

Question 108

superior sagittal sinus

Answer 108

runs above longitudinal fissure

Question 109

long haul flights

Answer 109

decreased skeletal muscle action => decreased venous return (preload => SV => CO) => increased venous volume => increased venous BHP => stretched pores => increased capillary permeability (large solutes exit vessel) => IFOP increases => NFP increased => interstitial fluid increased => oedema (lymphatic can drain)

Question 110

lactic acid

Answer 110

• causes vasodilation => decrease in BP
• NOT produced when standing still

Question 111

proprioceptive input

Answer 111

does NOT affect HR
- only sends info about location/orientation of joints etc.