CVS

Question 0

What branches come from the LCA?

Answer 0

Anterior interventricular branch
Circumflex branch
Left marginal branch
Lateral branch

Question 1

What branches come from the RCA?

Answer 1

Posterior interventricular branch
Sino-atrial nodal branch
AV nodal branch
Right marginal branch

Question 2

What does the SAnodal branch supply?

Answer 2

Pulmonary trunk, SAN

Question 3

What does the right marginal branch supply?

Answer 3

RV, apex

Question 4

What does the AV nodal branch supply?

Answer 4

AVN

Question 5

What does the posterior interventricular branch supply?

Answer 5

The posterior 1/3 of the IVS, LV and RV

Question 6

What does the anterior interventricular branch supply?

Answer 6

LV, RV and anterior 2/3 of interventricular septum

Question 7

What does the left marginal branch supply?

Answer 7

LV

Question 8

What does the circumflex branch supply?

Answer 8

LA, LV

Question 9

Which coronary arteries anastomose?

Answer 9

The posterior and anterior interventricular branches
The circumflex and the RCA
Both marginal branches with the IV branches

Question 10

What and when is isovolumetric relaxation in the cardiac cycle?

Answer 10

It is when the ventricles are relaxing after systole and both the atrioventricular and outflow valves are closed (as arterial pressure > ventricular pressure > atrial pressure) so the volume of blood in the ventricles stays the same.

Question 11

What and when is isovolumetric contraction?

Answer 11

This is when the ventricles are starting to contract in systole, so pressure is rising. All valves are closed because ventricular pressure is > atrial but < arterial so volume of blood in the ventricles remains constant.

Question 12

Explain the heart sounds.

Answer 12

1st heart sound = LUB
–> occurs due to closing of atrioventricular valves as ventricular pressure > atrial = systole is beginning.

2nd heart sound = DUB
–> occurs due to closing of outflow valves as arterial pressure > ventricular

Question 13

What can a “whoosh” between the two normal heart sounds represent?

Answer 13

Aortic or pulmonary stenosis/incompetence causing turbulent blood flow

Question 14

Describe the inside of the left atrium.

Answer 14

• large smooth wall which 4 pulmonary veins enter

- smaller muscular wall formed from pectinate muscles

Question 15

Describe the inside of the right atrium.

Answer 15

Posterior smooth wall where coronary sinus and vena cava enter.
Anterior wall formed from pectinate muscles.
Fossa ovalis (remnant of the foramen ovalis)

Question 16

What is the function of the right auricle?

Answer 16

It allows the atria to increase its capacity

Question 17

Describe the right ventricle.

Answer 17

Tricuspid valve with 3 cusps.
Smooth wall around area of outflow valve
Other wall is muscular (known as trabeculae carnae)

Question 18

What valve is present in the LV and how many cusps does it have?

Answer 18

The mitral valve with 2 cusps

Question 19

How are the cusps held in the hearts ventricles and how do they work?

Answer 19

Attached to papillary muscles via chordae tendinae. The papillary muscles contract prior to systole to close the cusps and prevent backflow.

Question 20

What are the 4 shunts in foetal circulation and their remnants in an adult?

Answer 20

Ductus arteriosus - between PT and aorta, becomes ligamentum arteriosum

Ductus venosus - bypass of the liver, becomes ligamentum venosum

Foramen ovale - from RA to LA, becomes fossa ovalis

Umbilical vein - from mothers circulation to foetal, becomes ligamentum teres.

Question 21

How does birth rid of foetal shunts?

Answer 21

Placental support removed
High pO2 causes contraction of ductus arteriosus
Ductus venosus simply closes

LA pressure increases as blood starts to flow to lungs upon breathing = LA pressure > RA = septum primum pushed against secundum, causing closure of foramen ovale.

Question 22

How does atrial septation occur?

Answer 22

Septum primum grows down to endocardial cushions with osmium primum inside.
Ostium secundum opens and primum closes
Septum secundum grows, which the foramen ovale in it
= channel for passage formed

Question 23

How does ventricular septation occur?

Answer 23

Muscular portion grows up towards the endocardial cushions, leaving a small space known as the primary interventricular foramen.
CT derived from the endocardial cushions then grows down to the muscular portion to form the membranous portion.

Question 24

How does conotruncal septation occur?

Answer 24

Endocardial cushions form in the truncus arteriosus, and grow towards each other to form a spiral septum.

Question 25

What do the parts of the heart tube become in the adult?

Answer 25

Bulbis cordis –> trabeculated wall of RV, outflow tracts, great vessels.
Ventricle –> LV
Atrium –> auricles of atria
Sinus venosus –> smooth wall of RA

Question 26

Describe the order of the branches of the aorta.

Answer 26

Brachiocephalic trunk (gives subclavian and common carotid)
Left common carotid (gives external and internal, external gives maxillary and facial arteries)
Left subclavian
Thoracic/descending aorta
Celiac trunk
Supra renal artery
Superior mesenteric artery
Renal arteries
Testicular/ovarian arteries
Inferior mesenteric artery
Common iliac artery (gives internal and external)

Question 27

Describe the order of the veins, R to L in the body.

Answer 27

Superior vena cava
R. Brachiocephalic (gives branch to arm, external then internal jugular)
L. Brachiocephalic
Hepatic veins
Renal veins
Testicular/ovarian veins (the L stems from hepatic vein)
Common iliac vein (gives nterval and external)

Question 28

What are the nuclei like n cardiac muscle?

Answer 28

Single and central

Question 29

What is the function of intercalated discs?

Answer 29

Hold cells together via desmosomes and contain gap junctions which form non selective ion channels = spread of electrical activity.

Question 30

Describe and explain a ventricular action potentials shape.

Answer 30

1) . Upstroke = depolarisation causes v-gated Na+ channels to open and Na+ to influx
2) . This is followed by a sharp drop, as Na+ channels inactivate so no more influxes, and K+ channels open = efflux of K+
3) . Plateau phase occurs where Ca2+ L type (v-gated) channels open, meaning inflow of Ca2+ is balancing out efflux of K+.
4) . Ca2+ channels close and K+ continues to efflux = repolarisation.

From -90mV to 30mV
Upstroke to repolarisation takes ~280ms

Question 31

Describe and explain the shape of an action potential in the SAN.

Answer 31

1) . Funny current slowly increasing, as more HCN channels open as the membrane becomes less negative = influx of Na+
2) . Na+ influx reaches threshold and causes v-gated Ca2+ channels to open = influx and upstroke.
3) . K+ channels open and efflux allows repolarisation.

Funny current takes ~600ms
Upstroke to repolarisation takes ~200ms

Question 32

How does the heart contract?

Answer 32

1). Depolarisation = opens L-type Ca2+ channels
—> Ca2+ influx
2). Ca2+ influx acts upon ryanodine receptors to open calcium induced calcium release channels
= Ca2+ release from SR.
3). Calcium binds to troponin C to cause a conformational change that reveals myosin binding site.
4). Myosin head binds to actin binding site, releasing a Pi that strengthens the bond.
5). ADP released which allows power stroke to occur
6). ATP binds to the head, allowing the head to detach from the actin binding site
7). ATP hydrolysis allows the ATP to re-cock and prepare for next stroke.

Question 33

How does the Ca2+ in the heart return to resting levels?

Answer 33

1) . Pumped into SR by SERCA (high affinity, high capacity) pumping Ca2+ in using ATP
2) . Pumped out of the cell altogether by NCX (low affinity, high capacity) or PMCA (high affinity, low capacity)

Question 34

How does vascular smooth muscle contract?

Answer 34

1) . Actin and myosin are bound to dense bodies in the smooth muscle cells
2) . Ca2+ influx via L type channels and via action of GalphaQ producing IP3
3) . Ca2+ binds to calmodulin to form a complex
4) . Complex acts on MLCK to activate it
5) . MLCK phosphorylates the light chain of the myosin head, so it can now bind to actin.
6) . MLCP deactivates this by dephosphorylating the head

Question 35

Describe the activity of MLCK and MLCP.

Answer 35

MLCK - activated

MLCP - constituently active

Question 36

What does lateral folding of the embryo achieve?

Answer 36

It brings the cardiogenic fields and blood islands together to form the heart tube

Question 37

What order are the parts of the embryonic heart tube?

Answer 37

Aortic roots
Truncus arteriosus
Bulbus cordis
Ventricle
Atrium
Sinus venosus

Question 38

Why does looping occur?

Answer 38

To allow further growth of the heart into the pericardial cavity

Question 39

What occurs in folding?

Answer 39

The cephalic portion moves caudally, ventrally and right.

The caudal portion moves cranially, dorsally and left.

Question 40

What does looping achieve?

Answer 40

• it places the outflow section ventral to the inflow by placing atrium dorsal to bulbis cordis.
• primordium of right ventricle closest to outflow
• primordium of left ventricle closest to inflow

Question 41

How does the transverse sinus form?

Answer 41

By looping, when the bulbis cordis is placed ventral to the atrium
= veins in behind arteries

Question 42

How does the sinus venosus develop?

Answer 42

Initially, R and L are equal sizes.
Venous return shifts to R so L recedes
R enlarges further but is engulfed by enlarging RA

Question 43

What does the RA develop from?

Answer 43

Sinus venosus

Most of primitive atrium

Question 44

What does LA develop from?

Answer 44

Absorption of proximal parts of 4 pulmonary veins

Small part of the primitive atrium

Question 45

What does the oblique sinus form from?

Answer 45

The absorption of proximal pulmonary veins by the enlarging LA.

Question 46

What are the aortic arches?

Answer 46

Early arterial system of symmetrical arched vessels.

Question 47

What does the 4th aortic arch remodel into?

Answer 47

Left - arch of aorta

Right - Right subclavian

Question 48

What does the 6th aortic arch remodel into?

Answer 48

Left - left pulmonary artery and ductus arteriosus

Right - right pulmonary artery

Question 49

What do the recurrent laryngeal nerves innervate?

Answer 49

Intrinsic muscles of the larynx

Question 50

How far do the recurrent laryngeal nerves descend?

Answer 50

Left T4/5

Right T1/2

Question 51

What influences the course of the recurrent laryngeal nerves and how?

Answer 51

1). Caudal shift of the developing heart and expansion of the developing neck region

2) . Need for ductus arteriosus
- left nerve hooks around this when heart is descending = gets “trapped” and must turn back on itself.

Question 52

What is flow? (Definition)

Answer 52

The volume of fluid that passes a certain point per unit of time.

Question 53

What is flow? (2 equations)

Answer 53

Flow = pressure gradient / resistance

Flow = area x velocity

Question 54

What is velocity?

Answer 54

Velocity is the rate of movements fluid along a tube.

Question 55

If cross sectional area of a tube increases, how does this affect velocity and why?

Answer 55

Velocity decreases.

To counter the change and maintain the flow at the same rate along the vessel.

Question 56

Name and describe the 2 types of flow?

Answer 56

1) . Laminar - the usual one where velocity and cell content is highest in the centre, as plasma on edges forms H bonds with vessel walls.
2) . Turbulent - often caused by exceeding the critical velocity n a laminar vessel, where liquid tumbles over itself = resistance and sound.

Question 57

What ultimately determines flow?

Answer 57

1) . Viscosity - the extent to which fluid layers resist sliding over each other
2) . Tube radius - wider it is, the faster the middle layers can move.

Question 58

How is resistance of vessels calculated in series?

Answer 58

Resistance of the vessels are added together.

Question 59

How is resistance of vessels on parallel calculated?

Answer 59

1/Rof1 + 1/Rof2

Question 60

What is the pressure of arteries like and why?

Answer 60

High to force blood from them into the much narrower arterioles.

Question 61

What is the resistance of capillaries like?

Answer 61

Individually high, but they are in parallel, so altogether much lower due to high cross sectional area.

Question 62

What is pressure like in circulation?

Answer 62

Heart --> Arteries 100
Arteries --> Arterioles 100
Arterioles --> Capillaries 35
Capillaries --> Venules 10
Venules --> Veins 8
Veins --> Heart 3

Question 63

How can blood flow become turbulent?

Answer 63

If a vessel narrows (e.g. Atherosclerosis) the velocity will increase and may exceed critical level = turbulence.

Question 64

What occurs if pressure increases in a distensible vessel and why?

Answer 64

It increases the lumen of the vessel (distensibility) and as a result, area increases and resistance falls, maintaining flow.

More blood is flowing in than out of the vessel = storing blood = capacitance.

Question 65

What happens if pressure falls in a distensible vessel?

Answer 65

Before pressure reaches 0, the vessel will collapse because pressure outside the tube will be greater than that inside.

Question 66

What is capacitance and its purpose?

Answer 66

It is the ability of a vessel to store blood and allows us t change the blood flow in the body.

Question 67

What is cardiac output?

Answer 67

Stroke volume x heart rate

Question 68

What is the resistance of the vessels in circulation?

Answer 68

All are low except arterioles

Capillaries are low together, individually high

Question 69

When is pulsatile flow at its min and max?

Answer 69

Max in systole

Min in diastole

Question 70

What affects systolic pressure?

Answer 70

How hard the heart pumps
How hard it is to push the blood into the aorta (TPR)
Stretchiness of arteries

Question 71

What pulse pressure?

Answer 71

Difference between diastolic and systolic.

Question 72

What is average pressure?

Answer 72

Diastolic + 1/3 of the pulse pressure

Question 73

How is blood distribution controlled?

Answer 73

Via action of sphincters in arterioles increasing and decreasing TPR.

Question 74

What is vasomotor tone produced and antagonised by?

Answer 74

Produced by sympathetic action on the vessels.

Antagonised by vasodilator metabolites.

Question 75

How does reactive hyperaemia occur?

Answer 75

When blood flow is cut off, vasodilating metabolites are produced by respiring tissues (K+, adenosine, H+).
When flow is returning these act to relax smooth muscle = increased flow to provide what’s needed until metabolites are washed away.

Question 76

What does reactive hyperaemia allow for?

Answer 76

Autoregulation - tissues can signal via metabolites to arterioles if it needs more blood flow
= change in blood supply pressure causes a change in flow (lower pressure, lowers flow)
= change in metabolite levels
= change in arterioles resistance

Question 77

What is pressure of veins determined by and what is that determined by?

Answer 77

The volume of blood stored in them rather than the pressure of that pushing through.
The volume of blood stored is determined by the volume of blood being returned to the vein from the body, and the volume being taken out via the heart.

Question 78

What does central venous pressure depend on?

Answer 78

Return of blood from the body (by gravity and muscle pumping)
Pumping of the heart.

Question 79

What do tissues rely on to take the blood they need, and what organ is the exception to this?

Answer 79

They rely on pressure remaining within set limits.

The brain is an exception as it is already affected by gravity, so pressure is lower. This decreases the brains capacity for autoregulation as pressure fall results in fall in flow.

Question 80

What are the main factors in ensuring tissues receive the supply they need?

Answer 80

Arterial pressure high enough to push into arterioles
Total peripheral resistance altering with need
Central venous pressure high enough to fill heart

Question 81

What is arterial pressure determined by?

Answer 81

CO

TPR

Question 82

What is venous pressure determined by?

Answer 82

Rate the blood enters them

Rate the heart pumps

Question 83

What is stroke volume?

Answer 83

The difference between the end systolic volume and end diastolic volume of the heart.

Question 84

How is intraventricular pressure created?

Answer 84

Stretching of the ventricular walls due to filling in diastole

Question 85

What rule does the ventricular compliance curve follow?

Answer 85

The more the heart fills, the greater the intraventricular pressure.

Question 86

Why does the ventricular compliance curve not increase much at the start?

Answer 86

Because pressure doesn’t increase too much until the heart fills enough that it expands and is pushing against the pericardium, which is when the pressure begins to shoot up.

Question 87

When does the heart stop filling in diastole?

Answer 87

When ventricular pressure reaches venous pressure.

Question 88

What is starlings law?

Answer 88

Rise in stroke volume increases venous pressure until the point where the heart can expand no further.
At this point, if the heart fills more it begins to compress its own arteries and its contractility decreases.

Question 89

What is the curve on a starlings law graph representitative of and when is it reduced or increased?

Answer 89

Contractility of the ventricles

Reduced in heart failure and increased in periods of sympathetic activity.

Question 90

What is ventricular emptying dependant on?

Answer 90

Force of contraction of the heart (therefore ejection)

TPR

Question 91

How are falls in arterial pressure dealt with?

Answer 91

Receptors in the carotid sinus detect this.
Send signals to medulla of brain.
Increases sympathetic activity of the heart = increased HR and force of contraction.

Question 92

How are rises in venous pressure dealt with?

Answer 92

Brain bridge reflex.

Detected by baroreceptors in the RA and vena cava.
Sends info to medulla of brain
Reduced parasympathetic activity to vessels = increased HR

Question 93

What occurs if the heart rate changes with no increase in demand for blood and when may this happen?

Answer 93

CO rises
Arterial pressure increases
Venous pressure falls
Stroke volume falls
Heart fills less 
CO falls

Post op in those with pacemakers

Question 94

What would occur if exercise was begun with no change in HR?

Answer 94

Enormous increase in demand.
Venous pressure would increase greatly as muscle pumping drives a greater volume of blood from its fibres’ capillaries to the heart.
Arterial pressure would therefore fall.

Question 95

Why is a rise in venous pressure dangerous?

Answer 95

It can overfill the heart, pushing it to the flat part of the contractility slope =
Blood would arrive at the RH faster than at the LH.
Therefore RH must pump faster to deal with increasing venous pressure.
LH doesn’t keep up and therefore they uncouple
Blood therefore accumulates in lungs = pulmonary oedema

Question 96

Why would the RH and LH uncouple if exercise was not met with an increase in HR beforehand?

Answer 96

Because the venous pressure increases greatly so the right heart is pushed off of starlings curve
= usually only stay coupled due to reliance on starlings curve effect, which gives them a shared stroke volume. The starlings curve is no longer functional so the stroke volumes now can differ = uncoupling.

Question 97

How is uncoupling of the left and right heart in exercise prevented?

Answer 97

HR increases before exercise so when venous pressure increases, the heart can cope with the increase in cardiac output.

Question 98

Why is standing a problem for circulation?

Answer 98

Upon standing, blood pools in superficial veins of the legs = CVP falls greatly.
Arterial pressure remains high initially but then begins to fall (fall in venous pressure decreases cardiac output, decreasing arterial pressure)
= VENOUS AND ARTERIAL PRESSURE NO LONGER OPPOSE

Question 99

How is the challenge of standing overcome by the circulation?

Answer 99

Baroreceptors detect fall in arterial pressure and increase sympathetic activity to increase HR

TPR increased to increase and maintain arterial pressure

Question 100

Why is haemorrhage dangerous to the circulation?

Answer 100

70% blood is kept in veins so haemorrhage = massive decrease in venous pressure.

This decreases input to the heart and as a result, CO also falls.

This causes arterial pressure to fall, so the TPR and HR is increased BUT this worsens venous pressure as it is very low to start with.

Question 101

How does the body respond to haemorrhage?

Answer 101

Venoconstriction to try and increase venous pressure.

Autotransfusion (water moves from the tissues into circulation to increase pressure due to a fall in hydrostatic pressure)

Question 102

Why is an increase in long term blood dangerous?

Answer 102

Because it increases venous pressure and therefore diastolic filling and CO.
This increases arterial pressure as TPR is unchanged.

The body doesn’t need this extra blood so TPR increases to restrict it
= increased arterial pressure
= hypertension

Question 103

How can a long term increase in blood volume be dealt with?

Answer 103

Loop diuretics if caught early.