Cardio physiology

Question 1

Mechanism of contraction in cardiac myocytes

Answer 1

Myocytes contain myofibrils

Myofibrils are made up of sarcomeres

Sarcomeres contain thin actin filaments and thick myosin filaments

In the absence of calcium –> troponin/tropomyosin complexes block cross-bridging

Calcium binds troponin –> allows cross-bridging and contraction

ATP required to detach myosin and actin

Myocytes have two systems of intracellular
membranes:
■ T-tubules
■ sarcoplasmic reticulum.

Question 2

Cardiac action potential cycle

Answer 2

Phase 0

• Rapid increase in sodium permability
• Rapid depolarisation

Phase I

• Rapid repolarisation
• Rapid decrease in sodium permeability
• Small increase in potassium permability

Phase 2

• Slow repolarisation
• Plateu effect due to influx of Ca2+
• Plateau lasts about 200 ms.

Phase 3

• Rapid repolarisation
• Increase in potassium permability
• Inactivated Ca2+ influx

Phase 4
-Resting membrane potential,
for ventricular muscle -90mV
-SA node and conduction system do not have resting potential, continual rhythmic firing

Question 3

Action potential: Phase 0

Answer 3

Na fast gates open, increase Na permability

Na fast influx

Cell becomes most positive it can be away form resting potential –> depolarisation

Question 4

Action potential: Phase 1

Answer 4

Na permability reduces, fast Na gates closed

Rapid repolarisation begins, electrical potential moves more negatively away from positive Na peak

Small increase in K permeability

Question 5

Action potential: Phase 2

Answer 5

Slow repolarisation – plateau effect due to inward
movement of calcium

Plateau lasts about 200 ms.

Question 6

Action potential: Phase 3

Answer 6

Rapid repolarisation – increase in potassium permeability

Inactivation of slow inward Ca++ channels

Question 7

Action potential: Phase 4

Answer 7

The resting membrane potential of the ventricular

muscle is about −90 mV

Question 8

Location of AV node

Answer 8

Atrioventricular node

Located in atrioventricular fibrous ring on the right side of atrial septum

Question 9

Vagal stimulation to heart

Answer 9

Vagal innervation to the SA node

Increased activity slows firing of SA node

Question 10

Phases of the cardiac cycle

Answer 10

Phase I: Isovolumetric contraction

Phase II: Ejection

Phase III: Diastolic relaxation

Phase IV: Filling phase of diastole

Question 11

Phase I: cardiac cycle

Answer 11

Isovolumetric contraction

Atroventricular valve closes

Aortic and pulmonary valves closed

Volume remains constant but pressure dramatically increases as ventricles contract

Question 12

Phase IIa: cardiac cycle

Answer 12

Ejection

Pressure in ventricles exceeds that in the aorta and pulmonary artery

Aortic and pulmonary valves open, blood ejected from ventricle

Question 13

Phase IIb: cardiac cycle

Answer 13

Ejection - equal pressures

Aortic and pulmonary artery pressures now equal to that of the ventricles - flow reduces

Question 14

Phase III: cardiac cycle

Answer 14

Diastolic relaxation

Isovolumetric relaxation, volume in ventricles remains the same and the resting ventricular pressure forms as pulmonary and aortic valves close

Question 15

Phase IVa: cardiac cycle

Answer 15

Passive filling during diastole

Atrioventricular valve opens

Low atrial pressure due to suction effect of ventricle

Rapid ventricular filling

Question 16

Phase IVb: cardiac cycle

Answer 16

Decline in rate of filling as atrial volume increases

Atria now full, flow rate reduced

85% of final diastolic ventricular volume reached

Question 17

Phase IVc: cardiac cycle

Answer 17

Atrial contraction

SA node depolarises

Atrial muscle contracts

Provides an additional 15% to ventricles (at-rest)
At higher HR and stroke volumes this is significantly more
–> Failure of atrial contraction therefore at higher heart
rates, e.g. fast atrial fibrillation (AF); exercise may be life-threatening.

Question 18

Normal right atrial pressures

Answer 18

0-4 mmHg

Question 19

Normal right ventricular pressure

Answer 19

25 / 0-4 mmHg

Question 20

Normal left atrial pressures

Answer 20

0-10 mmHg

Question 21

Normal left ventricular pressures

Answer 21

120 / 0-10 mmHg

Question 22

Third heart sound

Answer 22

Rapid ventricular filling

Question 23

Fourth heart sound

Answer 23

Atria contracting against a stiff ventricle

LVH or HF

Question 24

a-wave JVP

Answer 24

First peak: Atrial contraction

Absent in AF

Cannon waves in complete HB as atria contract against a closed tricuspid valve

Giant waves in pulmonary hypertension, tricuspid and pulmonary stenosis

Question 25

c-wave JVP

Answer 25

Small peak on approach to x-descent

This is tricuspid valve bulging during isovolumetric contraction of ventricles

Timed with carotid artery pulse wave

Question 26

x-descent JVP

Answer 26

First valley

Due to tricuspid valve moving down during ventricular
systole.

Question 27

v-waveJVP

Answer 27

Second peak

Rise in atrial pressure as atria fills prior to opening of tricuspid valve

Question 28

y-descent JVP

Answer 28

Second valley

Tricuspid valve opens and blood enters ventricle causing pressure in atria to drop

Question 29

JVP waveforms

Answer 29

ACX VY

At
CX

Vascular

Yunit

Question 30

Coronary flow is lowest…

Answer 30

During isovolumetric contraction - Phase I

Compression of the intramyocardial arteries

Conditions resulting in low diastolic BP or increased
intramyocardial tension during diastole (e.g. an
increased end diastolic pressure) may compromise
coronary blood flow

Question 31

Tissue with least coronary flow

Answer 31

Subendocardial muscle where the tension is highest

Question 32

Coronary flow is highest…

Answer 32

Diastole when there is an adequate diastolic BP

Increased when there is adequate time between beats - i.e. at slower HRs

Question 33

Factors increasing afterload

Answer 33

Raised aortic pressure

Aortic valve stenosis

Ventricular cavity size, great volume, requires greater tension to achieve same pressure (Laplace’s law)

Question 34

Techniques to measure cardiac output

Answer 34

Thermodilution

Dye test

Doppler USS

Question 35

Definition of MAP

Answer 35

= diastolic blood pressure + 1/3 of pulse pressure

Question 36

Factors increasing diastolic blood pressure

Answer 36

Total peripheral resistance

Arterial compliance (distensibility - stores elastic energy that means diastolic BP higher)

Heart rate

Question 37

Factors increasing the systolic blood pressure

Answer 37

Stroke volume

Ejection velocity (without an increase in stroke volume)

Diastolic pressure of the preceding pulse

Arterial rigidity (arteriosclerosis)

Question 38

Definition of systematic vascular resistance

Answer 38

SVR = MAP - mean right atrial pressure / CO

Resistance to flow of blood through arterioles.

By constricting and dilating, arterioles control the
blood flow to capillaries according to local needs.

Question 39

PAOP

Answer 39

~ Left atrial pressure
Normally 6-12 mmHg

> 15 –> pulmonary oedema

Flotation balloon catheter is passed through the
right heart into the pulmonary artery

The major advantage of the catheter is that it can
be used to measure CO

Question 40

Adrenaline

Answer 40

Alpha + Beta

Inotrope
Chronotrope
Vasopressor

β2-effect at low doses causes vasodilatation in
skeletal muscle, lowering SVR.

α-vasoconstrictor effect at higher doses increases SVR and myocardial oxygen demands, with adverse
effect on cardiac output

Question 41

Noradrenaline

Answer 41

α-effect.

Vasopressor

Indicated in septic shock when hypotension due to
peripheral vasodilatation persists despite adequate
volume replacement

Question 42

Isoprenaline

Answer 42

Exclusively β-effect

Ionotrope
Chronotrope

Vasodilatation in skeletal muscle; therefore reduces
SVR

Tachycardia limits clinical use

Used to increase rate in heart block while awaiting pacing

Question 43

Dopamine

Answer 43

Low dose causes vessel dilataion of:
Renal
Cerebral
Coronary 
Splanchnic 

via D1 and D2 receptors and β1 receptors, resulting in increased cardiac contractility and heart rate

High dose stimulates α-receptors, causing vasoconstriction

Question 44

Dobutamine

Answer 44

β1 β2

Inotrope
Vasodilator

β1 effect increases heart rate and force of contraction

Mild β2 effect causes vasodilatation

First choice inotrope in cardiogenic shock due to
left ventricular dysfunction.

Dobutamine and low-dose dopamine in conjunction
used in cardiogenic shock to increase BP via increased cardiac contractility and urinary output (UO; via increased renal perfusion)

Question 45

Dopexamine

Answer 45

β2 and D receptors.

Inotrope, chronotrope.

Peripheral vasodilatation, increased splanchnic blood flow and increased renal perfusion (increased UO)

Question 46

Vasodilator therapies

Answer 46

Nitrates
-Vendilatation reducing pre-load

Nitroprusside

• Arterial vasodilator with short t1/2-
• Infusion

Hydralazine

• Arterial vasodilator
• Reduces afterload

Question 47

Phosphodiesterase inhibitors

Answer 47

Prevent breakdown of cyclic AMP by phosphodiesterase III

Inotropic and vasodilator
-little chronotropic

Increased myocardial contractility (increased CO)
with reduced PAOP and SVR

No significant rise in heart rate or myocardial oxygen
consumption