ECGs Flashcards
Which leads are the anterior leads?
V1, V2
Which leads are the septal leads?
V3, V4
Which leads are the lateral leads?
I
aVL
V5, V6
Which leads are the inferior leads?
II, III
aVF
Of the praecordial leads, which ones have an isoelectric QRS complex?
V3, V4
Which leads must be looked at to figure out if there is any axis deviation?
I and aVF
(as these are perpendicular)
- What does the PR interval represent?
- What is its normal length?
- PR interval = time taken for excitation to spread from SAN, through atrial muscle, the AVN, down the bundle of His and into ventricular muscle (start of p wave to start of QRS complex)
- normal length of PR interval = 120-220ms (3-5 small squares)
- What does the QRS complex represent?
- What is its normal length?
- duration of the QRS complex shows how long excitation takes to spread through the ventricles
- normal length = 120ms (3 small squares)
- What does the ST segment represent?
- What is its normal length?
- interval between ventricular depolarization and repolarization (end of s wave to start of t wave)
- should be ~ 80ms (but more than length, whether its elevated or depressed tells us more about pathology)
How might you recognise left ventricular hypertrophy (i.e. left axis deviation) on:
a) limb leads
b) praecordial leads
a) I and aVF : if the waves are ‘leaving’ each other
b) V1 and V2 are the isoelectric leads (QRS complex)
How might you recognise right ventricular hypertrophy (i.e. right axis deviation) on:
a) limb leads
b) praecordial leads
a) I and aVF: waves are ‘coming together’
b) V5 and V6 are the isoelectric leads (QRS complex)
Which lead shows the P wave most clearly?
II
or V1
What is 1st degree heart block w.r.t. electrical conduction?
- If each wave of depolarization that originates in SA node is conducted to ventricles
- but there is a delay somewhere along conduction pathway
- –> the PR interval is prolonged
How do you identify 1st degree heart block on an ECG?
PR intervals are lengthened (>220ms)
PR interval = time taken for excitation to spread from SAN, through atrial muscle, the AVN, down the bundle of His and into ventricular muscle
normal length of PR interval = 120-220ms (3-5 small squares)
What is the clinical significance of 1st degree heart block?
Can be a sign of:
- coronary artery disease
- aute rheumatic carditis
- digoxin toxicity
- electrolyte disturbances.
What is the Tx for 1st degree heart block?
No specific action required
What is 2nd degree heart block w.r.t. to electrical conduction?
- excitation completely fails to pass through AV node or the bundle of His
- 2nd degree heart block = this occurs intermittently
What is 2nd degree heart block (Mobtiz type 1) w.r.t. to electrical conduction
- progressive lengthening of PR interval
- –> failure of conduction of an atrial beat
- followed by a conducted beat w a shorter PR interval
- then a repetition of this cycle.
How do you identify 2nd degree heart block (Mobitz type 1/Wenkelback) on an ECG?
see image
What is 2nd degree heart block (Mobtiz type 2) w.r.t. to electrical conduction?
- Most beats are conducted with a constant PR interval*
- but occasionally there is atrial depolarization without a subsequent ventricular depolarization.
How do you identify 2nd degree heart block (Mobitz type 2) on an ECG?
see image
What is the clinical significance of 2nd degree heart block?
- Usually indicates heart disease;
- often seen in acute MI
During heart blocks, how may a p wave present?
as a distortion of a t wave
What is 3rd degree heart block w.r.t. to electrical conduction?
- = complete heart block
- atrial contraction is normal but no beats are conducted to the ventricles
- When this occurs the ventricles are excited by a slow ‘escape mechanism’ from a depolarizing focus within the ventricular muscle
What is the clinical significance of 3rd degree heart block?
always indicates conducting tissue disease
acute phenomenon
- MI (when it is usually transient)
chronic
- fibrosis around the bundle of His.
- block of both bundle branches.
How do you identify 3rd degree heart block on an ECG?
see image
(must look at PR intervals and recognise that there is no consistency)
What is the Tx for 3rd degree heart block?
Permanent/temp. pacemaker
What is the principle of bundle branch block as seen on an ECG?
- If the depolarization wave reaches the interventricular septum normally, interval between the beginning of the P wave and the first deflection in the QRS complex (the PR interval) will be normal.
- However, if there is abnormal conduction through either the right or left bundle branches (‘bundle branch block’) there will be a delay in the depolarization of part of the ventricular muscle.
- The extra time taken for depolarization of the whole of the ventricular muscle –> widening of QRS complex
- conduction within the ventricles must have occurred by an abnormal, and therefore slower, pathway.
Which ECG leads are useful when determining bundle branch block?
Praecordial leads (as they’re in the horizontal plane)
- V1
- V6
What is the similaritiy and difference between depolarisation starting from the ventricles (i.e. an arrythmia), and bundle branch block on an ECG?
similarity
- both have widened QRS complexes
difference
- bundle branch block (sinus rhythm)=
- normal P waves are present
- a constant PR interval
- arrythmia =
*
What is seen on an ECG if both bundle branches are blocked?
has the same effect as block of the His bundle
–> complete (third degree) heart block.
What is RBBB a sign of?
problem w right side of heart
What does RBBB indicate clinically?
possible atrial septal defect
What does a RBBB pattern with a QRS complex of normal duration indicate?
quite common in healthy people
What does LBBB indicate clinically?
-
always an indication of left ventricular disease
- aortic stenosis
- ischaemic disease.
- if presents w recent chest pain:
- acute MI
What is the Tx for LBBB?
asymptomatic:
- none required
if indication of recent acute MI:
- follow MI guidelines
What is the implication on further ECG interpretation if LBBB is present?
LBBB prevents further interpretation of ECGs
What is the implication on further ECG interpretation if RBBB is present?
makes interpretation more difficult
How do you identify LBBB on an ECG?
WilliaM
- V1 - W
- V6 - M
- Sinus rhythm, rate 100/min
- Normal PR interval
- Normal cardiac axis
- Wide QRS complexes (160 ms)
- M pattern in the QRS complexes, best seen in leads I, VL, V5 and V6
- Inverted T waves in leads I, II, VL
How do you identify RBBB on an ECG?
MarroW
- V1 - M
- V6 - W
- Sinus rhythm, rate 60/min
- Normal PR interval
- Normal cardiac axis
- Wide QRS complexes (160 ms)
- RSR1 pattern in lead V1 and deep, wide S waves in lead V6
- Normal ST segments and T waves
What is the clinical significance of
left axis deviation + RBBB?
severe conducting tissue disease
right bundle branch + left anterior fascicle = blocked
(see image)
- no specific Tx required
- Pacemaker required if pt has symptoms suggestive of intermittent complete heart block
- i.e. right bundle branch + both fascicles of left bundle branch = blocked
- –> complete heart block occurs just as if main His bundle had failed to conduct.
What is the meaning of sinus rhythm?
When depolarization begins in the SA node
What is an arrhythmia?
When depolarisation begins anywhere other than the SAN
- the rhythm is named after the place of origin
Broadly speaking, how is an arrhythmia identified?
from the lead in which the P waves can be seen most easily (leads II or V1)
Which part of the heart controls the rate of ventricular contraction?
part of the heart that is depolarizing most frequently (i.e. highest rate of electrical discharge)
- in sinus rhythm, this is the SAN
- What is sinus arrhythmia
- give some examples of sinus arrhythmia
- Sinus rhythm with a beat-to-beat variation in the P-P interval (the time between successive P waves), producing an irregular ventricular rate.
- respiratory sinus arrhthymia
Where can abnormal cardiac rhythms originate?
- atrial muscle
- the region around the atrioventricular (AV) node (this is called ‘nodal’ or, more properly, junctional’)
- ventricular muscle.
What are the supraventricular rhythms?
- sinus (SAN origin)
- atrial rhythm
- junctional rhythm
How do you identify atrial escape on an ECG?
abnormal p wave (II or V1)
How do you identify junctional escape on an ECG?
absence of p waves (V1, V2 - septal leads)
How do you identify ventricular escape on an ECG?
wide abnormal QRS complex, not following a p wave
How would you identify atrial tachycardia on an ECG?
p waves are superimposed on preceding t waves
atrial rate > 150/min
What is the physiological basis surrounding atrial flutter?
re-entry rhythm, atrial depolarisation (continuous loop) overrides the SAN
How do you identify atrial flutter on an ECG?
- atrial rate >250/min
- no flat baseline between the P waves:
- p waves > 350 bpm = ‘sawtooth waves’
- seen best on inferior leads (II, III, aVF) + aVR
How do you identify junctional tachycardia on an ECG?
no p waves in any lead
QRS complexes are of normal shape (normal route of depolarisation)
QRS complexes - rate = high
- If the area around AVN depolarizes frequently, P waves may be seen very close to the QRS complexes OR may not be seen at all
How do you recognise ventricular tachycardia on an ECG?
- broad QRS complexes
- tachycardia
- no identifiable t waves
How do you recognise atrial fibrillation on an ECG?
best seen on inferior leads (II, III, aVF)
How do you recognise ventricular fibrillation on an ECG?
ECG is totally disorganised in every lead
patient will be unconscious (cardiac arrest)
How do you identify WPW syndrome on an ECG?
-
Slurred upstroke of the QRS complex, best seen in leads V3 and V4.
- Wide QRS complex due to this ‘delta’ wave
- Dominant R wave in lead V1
- Short PR interval
What is the clinical significance of WPW syndrome?
it can cause paroxysmal tachycardia
- Depolarization can spread down the His bundle and back up the accessory pathway, and so reactivate the atrium.
- A ‘re-entry’ circuit is thus set up, and a sustained tachycardia occurs
How do you recognise left atrial hypertrophy on an ECG?
- broad P wave +
- bifid P wave
How do you recognise right atrial hypertrophy on an ECG?
peaked P waves
How do you recognise right ventricular hypertrophy on an ECG?
- best seen on anterior leads (e.g. V1)
- height of R wave > depth of S wave
- lead V6
- deep S wave
usually accompanied by:
- right axis deviation
- right atrial hypertrophy i.e. peaked p wave
How do you recognise left ventricular hypertrophy on an ECG?
lateral leads: (V5 or V6)
- tall R wave (greater than 25 mm)
anterior leads: (V1 or V2)
- deep S wave
Describe an abnormal q wave
q wave > 1 small square in width (representing 40 ms)
q wave > 2 mm in depth
when seen in any leads other than V5 or V6
_(_see image - q waves seen earlt in V4 in pt 2)
What is the electrical basis for seeing abnormal q waves?
If an MI causes complete death of muscle from inside surface to outside surface of heart
- –> an electrical ‘window’ is created
- and an electrode looking at the heart over that window will record a cavity potential i.e. a Q wave.
(in the image, if the electrode was slightly superior or inferior, a flast line would be seen)
How is a posterior MI identified on an ECG?
lead V1: dominant R wave
What 2 abnormalities of the ST segment may be seen?
- elevation
- depression
What does horizontal depression of the ST segment, associated with an upright T wave indicate?
ischaemia (as opposed to infarction)
- t waves will still be flattened
- when the ECG at rest is normal, ST segment depression may appear during exercise, particularly when effort induces angina*
How is a low potassium level identified on an ECG?
- T wave flattening/inversion (in severe cases) +
- ‘U’ wave
- appearance of a hump on the end of the T wave
- ‘biphasic t wave’
How is a high potassium level identified on an ECG?
- peaked T waves
- ‘tall tented t waves’
- disappearance of ST segment
- ~ QRS complex widened.
What is torsades de pointes?
specific form of polymorphic ventricular tachycardia occurring in the
- context of QT prolongation;
- characteristic morphology in which the QRS complexes “twist” around the isoelectric line
can occur secondary to hypokalaemia
