**_🫀🫁Cardio & Resp🫀🫁 - Electrocardiography & Rhythm Disorders

Question 1

What can an ECG be used to diagnose?

Answer 1

Conduction abnormalities
Structural abnormalities
Perfusion abnormalities

Question 2

Why are ECGs so popular?

Answer 2

Relatively cheap and easy to undertake
Reproducible between people and centres
Quick turnaround on results/report

Question 3

What is a cardiac vector?

Answer 3

Question 4

What causes a deflection on an ECG?

Answer 4

A deflection on an ECG is generated by the movement of electrical currents through the heart’s muscle tissue
If this is towards the positive electrode, upwards deflection
If this is towards the negative electrode, this will be downwards
If it is towards neither, then it will be isoelectric (may be picked up by another lead however)
This is why an ECG has so many leads, to capture electrical impulses moving in all directions

Question 5

What are the signals in the cardiac cycle?

Answer 5

Question 6

Where in the heart is the electrical impulse pictured here?

Answer 6

Sinoatrial node (SAN)
Autorhythmic myocytes
Atrial depolarisation

Question 7

Where in the heart is the electrical impulse pictured here?

Answer 7

Atrioventricular node (AVN)
AVN depolarisation
Isoelectric ECG
Slow signal transduction
Protective

Question 8

Where in the heart is the electrical impulse pictured here?

Answer 8

Bundle of His
Rapid conduction
Insulated

Question 9

Where in the heart is the electrical impulse pictured here?

Answer 9

Bundle branches
Septal depolarisation

Question 10

Where in the heart is the electrical impulse pictured here?

Answer 10

Purkinje fibres (1)
Ventricular depolarisation

Question 11

Where in the heart is the electrical impulse pictured here?

Answer 11

Purkinje fibres (2)
Late ventricular depolarisation

Question 12

Where in the heart is the electrical impulse pictured here?

Answer 12

Fully depolarised ventricles
Isoelectric ECG

Question 13

Where in the heart is the electrical impulse pictured here?

Answer 13

Repolarisation
Ventricular repolarisation

Question 14

Where is lead 1 placed?

Answer 14

Right arm to left arm
(negative to positive)

Question 15

Where is lead 2 placed?

Answer 15

Right arm to left leg
(negative to positive)

Question 16

Where is lead 3 placed?

Answer 16

Left arm to left leg
(negative to positive)

Question 17

Where is V1 placed?

Answer 17

Question 18

Where is V2 placed?

Answer 18

Question 19

Where is V3 placed?

Answer 19

Question 20

Where is V4 placed?

Answer 20

Question 21

Where is V5 placed?

Answer 21

Question 22

Where is V6 placed?

Answer 22

Question 23

What is the most commonly used single lead?

Answer 23

Lead 2

Question 24

Summarise the 12 lead ECG (unsure of how much is needed to be memorised/recalled)

Answer 24

Question 25

What are all the major timings on an ECG?

Answer 25

Question 26

What are the augmented limb leads?

Answer 26

aVR
aVL
aVF

Question 27

Where is the aVL positioned?

Answer 27

1/2 Lead 2 (RA to LL) to left arm
(negative to positive)

Question 28

Where is the aVR positioned?

Answer 28

1/2 lead 3 (LA to LL) to right arm
(negative to positive)

Question 29

Where is the aVF positioned?

Answer 29

1/2 lead 1 (RA to LA) to left leg
(negative to positive)

Question 30

What angle on the cardiac axis does each lead correspond to?

Answer 30

Lead I: 0° (horizontal, looking at the heart from the left side)
Lead II: +60° (looking from the lower-left diagonal, towards the left ventricle)
Lead III: +120° (lower-right diagonal, looking at the right ventricle)
aVR: -150° (rightward, opposite the normal flow of electrical impulses)
aVL: -30° (upper-left, between the left and right sides)
aVF: +90° (vertical, looking up from the feet)

Question 31

How is the cardiac axis angle of an impulse calculated?

Answer 31

Question 32

What are the steps of the ECG reporting procedure?

Answer 32

Question 33

What is a sinus rhythm?

Answer 33

Normal hearth rhythm
Each P-wave is followed by a QRS wave (1:1)
Rate is regular (even R-R intervals) and normal (83 bpm in this example)

Question 34

What is sinus bradycardia?

Answer 34

Each P-wave is followed by a QRS wave (1:1)
Rate is regular (even R-R intervals) and slow (e.g. 56 bpm)
Can be healthy, caused by medication or vagal stimulation

Question 35

What is sinus tachycardia?

Answer 35

Each P-wave is followed by a QRS wave (1:1)
Rate is regular (even R-R intervals) and fast (e.g. 107 bpm)
Often a physiological response (i.e. secondary)

Question 36

What is sinus arrythmia?

Answer 36

Each P-wave is followed by a QRS wave (1:1)
Rate is irregular (variable R-R intervals) and usually normal (65-100bpm)
R-R interval varies with breathing cycle

Question 37

Give an example of how sinus arrhythmia may appear on an ECG

Answer 37

Question 38

What is atrial fibrillation?

Answer 38

Oscillating baseline - atria contracting asynchronously
Rhythm can be irregular and rate my be slow
Turbulent flow pattern increases clot risk
Atria not essential for cardiac cycle - patient wont present with acute heart failure

Question 39

What is atrial flutter?

Answer 39

Regular saw-tooth pattern in baseline (II, III, aVF)
Atrial to ventricular beats at a 2:1, 3:1 or higher ratio
Saw tooth not always visible in all leads

Question 40

What is first degree heart block?

Answer 40

Prolonged PR segment/interval caused by slower AV conduction
Regular rhythm - 1:1 ratio of P-waves to QRS complexes
Most benign heart block, but a progressive disease of ageing

Question 41

What is second degree heart block (Mobitz I)?

Answer 41

Gradual prolongation of the PR interval until beat skipped
Most P-waves followed by QRS; but some P-waves are not
Regularly irregular: caused by a diseased AV node
Also called Wenckebach

Question 42

What is second degree heart block (Mobitz II)?

Answer 42

P-waves are regular, but only some are followed by QRS
No P-R prolongation
Regularly irregular: successes to failures (e.g. 2:1) or random
Can rapidly deteriorate into third degree heart block

Question 43

What is third degree heart block?

Answer 43

Complete heart block
P-waves are regular, QRS are regular, but no relationship
P waves can be hidden within bigger vectors (such as a QRS complex)
A truly non-sinus rhythm – back-up pacemaker in action

Question 44

What is ventricular tachycardia?

Answer 44

P-waves hidden – dissociated atrial rhythm
Rate is regular and fast (100-200 bpm)
At high risk of deteriorating into fibrillation (cardiac arrest)
Shockable rhythm – defibrillators widely available

Question 45

What is ventricular fibrillation?

Answer 45

Cardiac arrest
Heart rate irregular and 250+bpm
Heart unable to generate an output
Shockable rhythm - defibrillators widely available

Question 46

What is ST elevation?

Answer 46

P waves visible and always followed by QRS (1:1)
Rhythm is regular and rate is normal (85 bpm)
ST-segment is elevated >2mm above the isoelectric line
Caused by infarction (tissue death caused by hypoperfusion)

Question 47

What is ST depression?

Answer 47

P waves visible and always followed by QRS
Rhythm is regular and rate is normal (95 bpm)
ST-segment is depressed >2mm below the isoelectric line
Caused by myocardial ischaemia (coronary insufficiency)

Question 48

What is the difference between ischaemia and infarction?

Answer 48

Ischaemia is reduced blood flow, resulting in oxygen deprivation and cell injury
Infarction is cell death due to prolonged ischaemia