Physiology - cardiology

Question 1

Cardiac muscle is not striated (T/F)?

Answer 1

False - the striation is caused by regular arrangement of contractile protein

Question 2

How does electrical excitation of cardiac muscle occur?

Answer 2

Cardiac muscle does not have neuromuscular junctions but the myocytes are electrically coupled by gap junctions. Gap junctions are protein channels which form low resistance electrical communication pathways between neighbouring myocytes

Question 3

What separates cardiac myocytes?

Answer 3

Intercalated discs joined by gap junctions

Question 4

What structure in the intercalated discs provides mechanical adhesion between adjacent cardiac cells?

Answer 4

Desmosomes - they ensure that the tension developed by one cell is transmitted to the next

Question 5

Each muscle fibre contains many _____ which are the contractile units of muscle

Answer 5

Myofibrils

Question 6

Myofibrils have alternating bands of thick and thin protein filaments, what are these called?

Answer 6

Actin = thin filaments, causes the lighter appearance in myofibrils
Myosin = thick filaments, causes the darker appearance

Question 7

What is the collective name for the arrangement of actin and myosin?

Answer 7

Sarcomere

Question 8

How is muscle tension produced?

Answer 8

By sliding of actin filaments on myosin filaments - this force generation is ATP dependent

Question 9

What ion is required to switch on cross bridge formation?

Answer 9

Calcium

Question 10

Where is calcium released from and what is its release dependent on?

Answer 10

Released from the sarcoplasmic reticulum and is dependent on the presence of extra-cellular calcium

Question 11

What happens to the AP after systole?

Answer 11

The AP has passed so Ca influx ceases and Ca is re-sequestered in the SR by Ca-ATPase, heart muscle relaxes

Question 12

Why is the long refractory period so important to normal cardiac function?

Answer 12

Prevents generation of tetanic contraction

Question 13

In which parts of the AP does the long refractory period occur?

Answer 13

During the plateau phase of ventricular action potential the Na channels are in the depolarised closed state i.e. not available for opening
During the descending phase of AP the K channels are open and the membrane cannot be depolarised

Question 14

What is the stroke volume?

Answer 14

The volume of blood ejected by each ventricle per heart beat

SV = EDV - ESV

Question 15

What is the EDV and what does it determine?

Answer 15

EDV = end diastolic volume

Determines the cardiac preload and is determined by the venous return to the heart

Question 16

What is Starling’s law?

Answer 16

The more the right ventricle is filled with blood during diastole (EDV) the greater the volume of ejected blood will be during the resulting systolic contraction (SV) and thus the venous return to the LA from pulmonary veins increases (EDV) and therefore increases the SV into the aorta

Question 17

What is afterload?

Answer 17

The resistance into which the heart is pumping

Question 18

How does Frank-Starling mechanism correct increased afterload?

Answer 18

If afterload increases, at first the heart is unable to eject entire SV, which increases the EDV. Force of contraction then rises

Question 19

What happens if afterload is persistently increased?

Answer 19

Eventually the ventricular muscle mass increases to overcome resistance e.g. untreated hypertension -> ventricular hypertrophy

Question 20

What type of nerve fibres and neurotransmitters supply the ventricular muscle of the heart?

Answer 20

Sympathetic nerve fibres and noradrenaline (NA) is the neurotransmitter

Question 21

What does positive inotropic effect mean and how is it caused?

Answer 21

Stimulation of sympathetic nerves increases the force of contraction = positive inotropic effect

Question 22

What else (other than a positive inotropic effect) does sympathetic stimulation cause in the heart?

Answer 22

Positive chronotropic effect i.e. increases the heart rate

Question 23

What effect does sympathetic stimulation have on ventricular contraction in terms of the AP?

Answer 23

Force of contraction increases (activation of Ca channels - greater Ca influx)
Peak ventricular pressure rises - contractility of heart at a given EDV rises (Frank-Starling curve shifted to the left)
Rate of ventricular relaxation increases (increased rate of Ca pumping)
This reduces the duration of diastole

Question 24

What is the effect of parasympathetic stimulation of ventricular contraction?

Answer 24

Vagal stimulation has major influence on rate, not force, of contraction

Question 25

What effect do adrenaline and NA have on the heart?

Answer 25

Released from adrenal medullar and have an inotropic and chronotropic effect

Question 26

What is cardiac output?

Answer 26

Volume of blood pumped by each ventricle per minute

CO = SV x HR

Question 27

What is atrial fibrillation?

Answer 27

Disorganised electrical activity of the atria resulting in an irregular heartbeat

Question 28

What is the underlying mechanism of AF?

Answer 28

Ectopic foci in muscle sleeves in the ostia of the pulmonary veins

Question 29

How is AF terminated?

Answer 29

Pharmacologic cardioversion (30% effective) with anti-arrhythmic drugs e.g. flecainide, sotalol, amiodarone
Electrical cardioversion (90% effective) by direct current (DCCV)
Spontaneous reversion to sinus rhythm

Question 30

What are the different types of AF?

Answer 30

Paroxysmal - lasting less than 48 hours, often recurrent
Persistent - lasting >48 hours and can still be cardioverted to NSR, unlikely to spontaneously resolve to NSR
Permanent - inability of drugs or other methods to restore NSR

Question 31

What are some diseases associated with AF?

Answer 31

Hypertension, congestive HF, sick sinus syndrome, coronary heart disease, obesity, alcohol abuse, congenital heart disease, COPD, pneumonia

Question 32

What is lone (idiopathic) AF?

Answer 32

Absence of any heart disease and no evidence of ventricular dysfunction
Diagnosis of exclusion

Question 33

What are some of the symptoms of AF?

Answer 33

Palpitations, dizziness, syncope, chest pain, dyspnoea, sweatiness, fatigue

Question 34

What are the features of AF on ECG?

Answer 34

Atrial rate >300bpm
Rhythm is irregularly irregular
Absent P waves
Presence of f waves

Question 35

What can happen in patients with WPWS and AF?

Answer 35

AF in patients with pre-excitation (WPWS) can result in VF and sudden cardiac death

Question 36

How is AF managed?

Answer 36

Rhythm control or rate control

Anti-coagulation for both approaches if high risk of thromboembolism

Question 37

What are some examples of rate controlling drugs used in AF?

Answer 37

Digoxin, beta-blockers, verapamil and diltiazem

Question 38

What are some methods of rhythm control used in AF?

Answer 38

Pharmacological cardioversion - anti-arrhythmic drugs e.g. amiodarone
Direct current cardioversion (DCCV)
Maintenance of NSR - anti-arrhythmic drugs, catheter ablation, surgery

Question 39

What ion channel do class I anti-arrhythmic drugs block and what is their main use?

Answer 39

Na channels - act on phase 0 of the AP e.g. lignocaine, quinidine, flecainide
Rhythm control

Question 40

What ion channel do class II anti-arrhythmic drugs block and what is their main use?

Answer 40

Beta receptors - act on phase 4 of the AP e.g. propanolol

Rate control

Question 41

What ion channel do class III anti-arrhythmic drugs block and what is their main use?

Answer 41

K channels - act on phase 3 of the AP e.g. amiodarone, sotalol, dronedarone
Rhythm control

Question 42

What ion channel do class IV anti-arrhythmic drugs block and what is their main use?

Answer 42

Ca channels - act on phase 2 of the AP e.g. verapamil

Rate control

Question 43

When is anti-coagulation recommended in patients with AF?

Answer 43

Thyrooxicosis, HOCM, valvular AF (warfarin only) or >2 risk factors; age>75, hypertension, HF, previous stroke/thromboembolism, DM

Question 44

What is the risk scoring system used in AF?

Answer 44

CHA2DS2VASc 
Congestive HF
Hypertension
Age>75
Diabetes mellitus
Stroke
Vascular disease
Age 65-74
Sex (female)

Question 45

Why is radiofrequency ablation used in AF?

Answer 45

To maintain sinus rhythm by ablating AF focus (usually in pulmonary veins)
For rate control - ablation of the AVN to stop fast conduction to the ventricles

Question 46

Why is left atrial catheter ablation used in AF?

Answer 46

Isolate triggers in the pulmonary veins by pulmonary in LA vein isolation

Question 47

What is atrial flutter?

Answer 47

Rapid and regular form of atrical tachycardia

Usually paroxysmal

Question 48

What are the features of atrial flutter on ECG?

Answer 48

Atrial rate >300bpm, ventricular rate usually 150bpm
Saw tooth wave
Regular rhythm

Question 49

How is atrial flutter treated?

Answer 49

Radiofrequency ablation
Pharmacological therapy - slow the ventricular rate, restore sinus rhythm and maintain SR
Cardioversion
Warfarin for prevention of thromboemboli