The Electrocardiogram

Question 1

What does the P wave represent?

Why is it a small upward depolarisation?

Answer 1

Atrial depolarisation

Due to: smaller muscle mass and depolarisation moving towards the electrode

Question 2

What does the QRS complex represent?

Answer 2

Ventricular contraction

Question 3

What does Q represent?

Answer 3

Septal depolarisation spreading to ventricles

Question 4

What does R represent?

Answer 4

Main ventricular depolarisation

Question 5

What does S represent?

Answer 5

End of ventricular depolarisation

Question 6

When does atrial repolarisation take place?

Answer 6

During the same time as ventricular depolarisation

– during QRS complex

Question 7

What does the T wave represent?

Answer 7

Ventricular repolarisation

Question 8

Describe the T wave shape

Answer 8

Upward signal as repolarisation is away from electrode

Medium sized as timing in the different cells is dispersed

Question 9

What does the PR interval measure?

Answer 9

Time taken for impulse to reach ventricles from the SA node

Question 10

What is a normal time for a PR interval?

Answer 10

0.12 to 0.2 seconds

3-5 small squares

Question 11

What does a short PR interval indicate?

Answer 11

Atria have been depolarised close to the AV node or the is an abnormality of conduction from the atria to the ventricles.

Question 12

What does the duration of the QRS complex represent?

Answer 12

How long excitation takes to spread through the ventricles

Question 13

What is the normal duration of a QRS complex?

Answer 13

0.12 seconds or less

Question 14

What does a widened QRS complex represent?

Answer 14

An abnormality of conduction through the ventricles

E.g. Bundle branch block

Question 15

What are the V leads?

Answer 15

Six chest leads
Made from 6 positions overlying the 4th and 5th rib spaces
– look in horizontal plane from the front and from the left

Question 16

What do V1 and V2 show?

Answer 16

Right ventricle

Question 17

What do V3 and V4 show?

Answer 17

Septum and anterior wall of left ventricle

Question 18

What do V5 and V6 show?

Answer 18

Anterior and lateral walls of left ventricle

Question 19

What is the cardiac axis?

Answer 19

The average direction of spread of the depolarisation wave from the front

Question 20

Where can you deduct the cardiac axis?

What is the normal shape?

Answer 20

From leads I, II and III

Defects signal upwards as depolarisation is spreading towards the three leads

Question 21

When does right axis deviation occur?

What is it associated with?

Answer 21

When the right ventricle becomes hypertrophied.

Usually associated with pulmonary condition putting a strain on the right side of the heart as well as congenital heart defects.

Question 22

What do you see form the leads in right axis deviation?

Answer 22

Deflection in I becomes negative
Deflection in III becomes positive

– axis swings towards the right

Question 23

When does left axis deviation occur?

What is it usually due to?

Answer 23

When the left ventricle becomes hypertrophied

Usually due to a conduction defect
– unlikely to be due to increased bulk of left ventricle

Question 24

What do you usually see from the leads in left axis deviation?

Answer 24

QRS complex become negative in III

Only is significant when QRS deflection is predominantly negative in lead II

Question 25

What is first degree heart block?

Answer 25

Prolonged PR interval

Question 26

What is first degree heart block a sign of?

Answer 26

Coronary artery disease
Acute rheumatic carditis
Digitalis toxicity
Electrolyte disturbances

Question 27

What is second degree heart block?

Answer 27

Erratic PR interval

Excitations fails to pass through the AV node or the bundle of His

Question 28

What are the causes of second degree heart block?

Answer 28

Same as first degree heart block: 
Coronary artery disease
Acute rheumatic carditis
Digitalis toxicity
Electrolyte disturbances

Question 29

What is third degree heart block?

Answer 29

Complete atrioventricular block

• • atrial contraction is normal but no beats are conducted to the ventricles
• • the two are disconnected electrically

Question 30

How are the ventricles excited in third degree heart block?

Answer 30

By a slow escape mechanism

Question 31

How can you recognise third degree heart block?

Answer 31

P wave rate is normal (90)
QRS rate is low (36)
No relationship between P and QRS
Abnormal shaped QRS complexes due to abnormal spread of depolarisation from ventricular focus

Question 32

What can cause third degree heart block?

Answer 32

Acutely – transient heart attack

Chronically – fibrosis around bundle of His

Question 33

When can a right bundle brach block be normal?

Answer 33

When the duration of the QRS complex is normal

Question 34

What do bundle branch blocks indicate?

Answer 34

RBBB indicates problems with the R side of the heart

LBBB always indicates heart disease, usually on the L side

Question 35

What changes occur in the ECG during right bundle brach block?

Answer 35

V1 lead – normal R wave, second R wave due to failure of conduction pathway
V6 lead – smaller Q wave, normal R wave, wide deep S wave

Question 36

What changes occur in the ECG during left bundle brach block?

Answer 36

V1 lead – small Q, R wave (inspire of smaller mule mass), S wave (late depolarisation of LV)
V6 lead – R wave, S wave (appears as a notch), second R wave (due to late depolarisation of LV)

Question 37

Where is right bundle brach block most easily seen?

Answer 37

In V1, where there is an RSR pattern

Question 38

Where is left bundle brach block best seen?

Answer 38

In V6 where there is a “rabbit ears” pattern

Question 39

Describe the branching of the bundle of His

Answer 39

From the AV node, two branches arise. The right bundle branch and the left bundle branch.
The right bundle branch has no main divisions.
The left bundle branch has two main divisions – anterior and posterior fascicles

Question 40

Which pacemaker cells have priority?

Answer 40

SAN pacemaker cells. They pre-empt other pacemakers due to a faster firing rate.

Question 41

What can you use in order to determine the cardiac axis?

Answer 41

The lead with the smallest possible R wave which will be the lead at 90 degrees to the cardiac axis.

Question 42

When analysing an ECG what do you look for?

Answer 42

Rate
Rhythm
Axis 
P wave
P-R segment
QRS complex
Q-T interval 
T wave

Question 43

When is the P wave absent?

Answer 43

In atrial fibrillation

Question 44

What are abnormalities that can be seen in the P-R interval?

Answer 44

First degree heart block = prolonged P-R interval
Second degree heart block = erratic P-R interval
Third degree heart block = no relationship between P and QRS complex

Question 45

What is sinus rhythm?

Answer 45

Pacemaker cells in the SAN are controlling the heart rate

– normal depolarisation

Question 46

What are the features of myocardial infarction?

Answer 46

ST elevation
Pathological Q waves – greater than one small square across
Inverted T waves

Question 47

What changes from the MI are permanent?

Answer 47

Pathological Q waves are permament
– present in full thickness MI
– due to scar tissue forming which effectively blocks the circuit
Inverted T waves

Question 48

What do broader QRS complexes represent?

Answer 48

Escape rhythm

– ventricle is taking over as the pacemaker

Question 49

Where can you see an inferior MI?

Which coronary artery is likely to be responsible?

Answer 49

Leads II, III and aVf

Right coronary artery

Question 50

Where can you see an anteroseptal MI?

Which coronary artery is likely to be responsible?

Answer 50

V1 and V2

Left anterior descending coronary artery

Question 51

Where can you see an anteroapical MI?

Which coronary artery is likely to be responsible?

Answer 51

V3 and V4

Distal left anterior descending coronary artery

Question 52

Where can you see an anterolateral MI?

Which coronary artery is likely to be responsible?

Answer 52

V5, V6, I, aVL

Circumflex coronary artery

Question 53

Where can you see an extensive anterior MI?

Which coronary artery is likely to be responsible?

Answer 53

V1 - V6, I, aVL

Proximal left coronary artery

Question 54

Where can you see a posterior MI?

Which coronary artery is likely to be responsible?

Wat are you likely to see in this case?

Answer 54

V1 and V2

Right coronary artery

ST depression in anterior leads or as tall R waves

Question 55

Where is the MI if there are changes in leads II, III and aVf?

Answer 55

Inferior

Question 56

Where is the MI if there are changes in leads V1 and V2?

Answer 56

Anteroseptal

Question 57

Where is the MI if there are changes in leads V3 and V4?

Answer 57

Anteroapical

Question 58

Where is the MI if there are changes in leads V5, V6, I and aVL?

Answer 58

Anterolateral

Question 59

Where is the MI if there are changes in leads V1 - V6, I and aVL?

Answer 59

Extensive anterior

Question 60

Where is the MI if there are tall R waves in V1 and V2?

Answer 60

Posterior aspect