ECG 2: Signs of Abnormality

Question 1

What are the three signs on an ECG of WPW syndrome with a Wide complex QRS?

Why is this

Answer 1

Short PR
Wide QRS
Delta wave

Because its going don the slower conduction pathway

Question 2

WPW and “Narrow complex Tachycardia”

Answer 2

Narrow QRS, and a re-entrant SVT

Question 3

WPW syndrome is?

Answer 3

pre-excitation syndrome, which the ventricles of the heart are electrically activated earlier then normal through an ‘accessory pathway’ called the “Bundle of Kent”.

Abnormal electrical pathway that doesn’t have the delaying properties of the AV node

Question 4

How can a ventricular Tachyarrhythmia occur?

Answer 4

Re-entry from atria to the ventricles.

-Rapid atrial rhythm where AV node cannot protect ventricles

Question 5

How does WPW present?

Answer 5

• Most sufferers will remain asymptomatic throughout their entire lives
• episodes of unexplained syncope or palpitations
• small risk of sudden death

Question 6

Treatment of WPW

Answer 6

Drugs

removal of Bundle of Kent

Question 7

Long QT Syndrome

Answer 7

Heart disease in with an abnormally long delay between ventricular depol -repolarization (delayed repolarisation). This reflects AP duration

Question 8

Most common types of LQTS are?

Answer 8

Drug Induced: usually a result of anti-arrhythmic drugs like “amiodarone”

Genetic: due to mutation usually in ion channels. Usually prolong the Ventricular AP (APD)

Question 9

Most Common type of Genetic LQTS?

Answer 9

Gene conducting slowed component of the K+ channel is mutated. This leads to an iKs abnormality as cells can’t repolarise properly

Question 10

How does Long QT Syndrome work?

Answer 10

Long QT > abnormal ventricular repolarisation > differences in the “refractoriness of myocytes > abnormal activation of the ventricles and thus arrhythmia

Question 11

Complications of LQTS

Answer 11

Associated with Syncope and sudden death due to ventricular arrhythmias

Question 12

Early after-depolarisations (EADs) can result in

Answer 12

• Continuously varying
• Torsade de Pointes - twisting of the points

May resolve spontaneously or progress to VF

Question 13

During myocardial ischaemia what are some AP changes

Answer 13

All these changes are VARIABLE. All shorten ATP

• Na+/K+ ATPase reduced
• Transmemebrane K+ gradient reduced
• INa reduced
• Hyperkalemia(lots of K+ in the extracellular fluid) shortens AP duration (Increased [K+]o increases IKr)
• Activation of IKATP channels

Question 14

Myocardial Infarction leads to a characteristic (though variable) and progressive ECG changes. These are

Answer 14

T wave changes
ST segment changes
QRS changes

Question 15

T wave changes

Answer 15

1)Tall peaked T-waves due to K+ leaking from myocytes (same as hyperkalaemia)

• Not specific to MI
• Earliest signs of acute MI (so usually missed as you don’t ECG till later)
• Localised to the leads facing area of injury
• 5-30mins post-onset

2) Symmetrically inverted T-waves
- later (days)
- unknown mechanism

Question 16

ST elevation

Answer 16

Usually earliest recognised sign of acute MI
Ischaemia; lowers resting membrane potential, shortens AP and changes AP plateu.

Leads to a voltage gradient between normal and ischaemic zones

• Injury current
• this is reflected by ST changes

2 theories: diastolic and systolic current of injury.

Question 17

Diastolic Current of Injury

Answer 17

As the ischaemic zone has a partially depolarised resting potential, so the there is CURRENT FLOW at resting potential.
So instead of being at baseline (0) the ECG reads higher. Still reach the same plateau (baseline). So what APPEARS as ST elevation is actually still just reaching baseline

Apparent ST shift

Question 18

Systolic Current of Injury

Answer 18

Injury occurs during AP plateau. Current flows during plateu when it should be isoelectric. True ST shift

Question 19

“injury Current”

Answer 19

abnormal current flow either to/from normal to injured tissue

Question 20

Loss of R wave height and pathological Q waves. (QRS changes)

Answer 20

As infarcted tissue is electrically inactive

• Wavefronts coming towards electrodes diminished or absent
• Wavefronts moving away from overlying electrode emphasized

Question 21

Reciprocal changes

Answer 21

in leads ‘opposite’ those facing the infarct see inverse changes

• ST segment depression instead of elevation
• Tall T waves not inverted

Question 22

How can we localise damage to areas of the heart

Answer 22

ECG changes only seen in areas overlying damage area.

Can also identify coronary arteries involved.

Question 23

How does defibrillation work??

Answer 23

Evenly spreads the depolarisation, due to laminar structure this can occur

Question 24

Hyperkalaemia

Answer 24

Some channels conduct faster when [K+] outside increases. Leads to faster repolarisation

-Tall peaked Twaves

Question 25

Hypokalaemia

Answer 25

Flat T waves

Question 26

Hypercalcaemia

Answer 26

increase [Ca2+] outside leads to increased inside.

• Leads to inactivation of L-type Ca2+ channels
• reduces duration of Ca current during plateau
• Reduced APD, shorter QT interval

Question 27

Hypocalcaemia

Answer 27

prolonged QT interval