Atrial Arrhythmia

Question 1

What are the two main types of atrial arrhythmias?

Answer 1

1. Atrial fibrilation
2. Atrial flutter

Question 2

What are some characteristics associated with atrial fibrillation?

Answer 2

Electrical impulses triggered from multiple locations in atria

Electrical activity is chaotic rather than organized

Atrial walls, quiver rather than contract

EF is reduced due to loss of atrial kick (significant for patients with medium and reduced EF)

Question 3

What are some characteristics of atrial flutter?

Answer 3

Electrical activities in atria is coordinated

Atria do contract but at a very rapid rate (250-350 contractions per minute, only 1/2 get across to the AV node)

Question 4

Which of the two atrial arrhythmias is most common?

Answer 4

Atrial fibrillation is more common compared to atrial flutter

Question 5

Is atrial fibrillation on its own life-threatening?

Answer 5

No, but it is associated with significant impairment of life and increases of stroke and LVH (due to loss of atrial kick)

Question 6

What is atrial kick?

Answer 6

This phenomenon relies on the Frank-Starling Laws. In Afib, the atria no longer pump an extra amount of blood into the ventricles during diastole. This results in less stretching of the ventricles, which in turn causes less forceful ejection of blood during systole

Question 7

What happens to the ECG reading of a patient with atrial fibrillation?

Answer 7

Each cycle of ECG waves lasts a different duration

They are the same duration in healthy patients

Question 8

How common is atrial fibrillation?

Answer 8

Fairly rare in in patients under 60 (0.4%)

2-5% in those over the age of 60 (more than 6% in patients over the age of 80)

10-30% of heart failure patients have atrial fibrillation

More common in men

Question 9

What is the main mechanism by which atrial fibrillation can pose risk for significant impairments in functional capacity?

Answer 9

Clots can form in the atria in atrial fibrilation and pieces of these clots can cause thromboemolic events

Question 10

What are some symptoms of atrial fibrillation?

Answer 10

May have all or some of the following symptoms:
- Fatigue
- Palpitations
- Chest pain
- Dyspnea
- Dizziness

Question 11

What is the etiology of atrial fibrillation?

Answer 11

Caused by ectopic foci that generate electrical impulses (multiple smaller pacemakers instead of one strong SA node)

This erratic generation of electrical impulses causes an irregular ventricular rhythm

Question 12

What does the AV node do to signals from the SA node?

Answer 12

It is a damper to the signals. It slows down the frequency of impulses in healthy and atrial fibrillation patients

Question 13

What are the main classifications of atrial fibrillation?

Answer 13

Valvular

Non-valvular

Lone atrial fibrillation

Paroxysmal

Persistant

Longstanding persistent

Permanent

Question 14

What are some causes of atrial fibrillation?

Answer 14

Significant disease/damage/repair to heart valves

Often use warfarin for treatment

Question 15

What are some characteristics of Lone atrial fibrillation?

Answer 15

Absence of clinical or ECG findings:
- Other CVD (including HTN)
- Related pulmonary disease
- Cardiac abnormalities (enlargement of the left atrium)
- Age under 60

Question 16

What are some charcteristics of a paroxysmal atrial fibrillation?

Answer 16

This is atrial fibrillation that lasts longer than 30 sec and self-terminates within 7 days

Patient is usually not in atrial fibrillation

Question 17

What are some characteristics associated with persistent atrial fibrillation?

Answer 17

Continuous atrial fibrillation lasting longer than 7 days, but less than 1 year

Question 18

What are the differences between persistent and longstanding persistent atrial fibrillation?

Answer 18

Continuous atrial fibrillation equal or greater than 1 year despite rhythm control management

Question 19

What are the characteristics of permanent atrial fibrillation?

Answer 19

It is continuous atrial fibrillation for which a therapeutic deision has been made not to pursue sinus rhythm restoration (rate control alone)

Question 20

How should HCPs investigate potential atrial fibrillation?

Answer 20

1. Get history of similar episodes (get info about duration, frequency, and nature of episodes)
2. Determine potential risk factors or triggers (alcohol, physical exertion)
3. Identify any potential reversible causes (acute infection, drug-related) or AF secondary to another disease (acute cardiac pathology)
4. Review family and medical history
5. Examine patient vitals and perform physical exam
6. Perform the following:
   a. 12-lead electrocardiogram
   b. ECG
   c. Laboratory investigations

Question 21

What are the goals of therapy for atrial fibrillation?

Answer 21

• Prevent stroke or systemic thromoembolism
• CV risk reduction
• Improve symptoms, functional capacity and QoL
• Prevent complications (LV dysfuntion and falls)

The above measures should improve survival, and reduce healthcare utilization

Question 22

What is the purpose of determining a stroke risk stratification score?

Answer 22

• Estimate risk of stroke in patients with atrial fibrilation
• Used to determine degree of antithrombotic therapy required based on an individuals patient’s risk of developing stroke
• Estimate bleeding risk

Question 23

What is CHADS2?

Answer 23

It is a score that helps determine risk of atrial fibrilation

The following variables help generate risk assessment:

1. Recent CHF
2. Hypertension
3. Age over 75
4. Diabetes
5. History of Stroke

Question 24

What is the risk reduction of warfarin in stroke?

Answer 24

Compared to placebo, warfarin reduces the risk of stroke by 66%

Question 25

What is the benefit of DOACs in stroke vs. Warfarin?

Answer 25

10% fewer mortality over all vs. warfarin

20% more reduction in stokes

50% reduction in bleeding in the head

Question 26

What populations see the greatest improvement in thromboembolic event rates following anticoagulant use?

Answer 26

Older patients (especially after the age of 85)

Question 27

What are some obesity adjusted anticoagulant therapy choices?

Answer 27

Use any DOAC under BMI of 40

Use apixaban & edoxaban with caution in patients with BMI between 40 to 49

Only use warfarin in patients with BMI over 50 (usually refer to cardiologist)

Question 28

What are some renal function adjusted doses for Dabigatran?

Answer 28

CrCl over 50mL/min (use 150mg BID)

CrCl between 30-49mL/min (Consider 110mg BID)

CrCl under 29mL/min (No RCT Data)

Question 29

What are some renal function adjusted doses for Rivaroxaban?

Answer 29

CrCl over 50mL/min (use 20mg daily)

CrCl between 30-49mL/min (15mg daily)

CrCl under 29mL/min (No RCT Data)

Question 30

What are some renal function adjusted doses for Apixaban?

Answer 30

CrCl over 50mL/min (use 5mg BID)

CrCl between 30-49mL/min :
- Use 5mg in patients under 80, weigh more than 60kg, and SCr under 133mmol/L
- Use 2.5mg if one of the above do not apply

CrCl under 29mL/min (No RCT Data)

Question 31

What are some renal function adjusted doses for Edoxaban?

Answer 31

CrCl over 50mL/min (use 60mg daily)

CrCl between 30-49mL/min (30mg daily)

CrCl under 29mL/min (No RCT Data)

Question 32

What is an antidote for dabigatran?

Answer 32

Idarucizumab (draws free dabigatran from the body)

Question 33

What are some contraindications for DOAC therapy?

Answer 33

• Patients with mechanical heart valves
• 3A4 and P-gp drug interactions
• Pregnancy and lactations
• Use caution in very underweight or obese
• In combination with DAPT (drop ASA if using DOAC with Clopidrigrel following a MI)

Question 34

How is anticoagulant therapy monitored?

Answer 34

• Adherance
• Frequency of adverse effects
• Signs and symptoms of bleeding and bleeding risk factors
• Regular SCr, CrCl, HgB

Question 35

Is there a significant difference in CV outcomes for rate or rhythm control in arrhythmia?

Answer 35

No, there is no significant difference in CV outcomes between the two

Question 36

What is the general goal for rate control in arrhythmia treatment?

Answer 36

Reduction in HR greater than 20% with control of symptoms

Target:
- resting HR under 100bpm

Use beta-blocker or non-DHP CCB as first line

Question 37

Can cardioversion be attempted in atrial fibrillation patients immediately?

Answer 37

No, need to use anticoagulants for 3 weeks before attempting cardioversion (patient has been in atrial fibrillation for longer than 24-48 hours) OR perform imaging to determine if there is atrial clotting

Question 38

What is the benefit of rhythm control in arrhythmia treatment?

Answer 38

• Relief of symptoms such as palpitations
• Improve CO and exercise tolerance
• Prevention of tachycardia-induced myocardial remodelling and heart failure

Question 39

What patient groups should be put on on rhythm control for arrhythmia?

Answer 39

• Stable and healthy patients with recent-onset atrial fibrilation
• Heart failure
• Angina
• Hypotension

Question 40

Is electrical cardioversion more effective compared to pharmacological cardioversion?

Answer 40

Yes, electrically-induced cardioversion is more effective

Question 41

Can digoxin be used to pharmalogically cardioconvert irregular sinus rhythm?

Answer 41

No, it is only used for rate control, not rhythm control

Question 42

Can beta-blockers be used to pharmalogically cardioconvert irregular sinus rhythm?

Answer 42

No, it is only used for rate control, not rhythm control

Question 43

Can CCBs be used to pharmalogically cardioconvert irregular sinus rhythm?

Answer 43

No, it is only used for rate control, not rhythm control

Question 44

What drugs are used to perform pharmalogical cardioconversion?

Answer 44

Procainamide IV
Flecainide IV and PO
Propafenone PO
Sodium Channel Blockers
amiodarone IV and PO

Question 45

What is the sequence of conduction events?

Answer 45

SA node –> AV node –> Bundle of His –> Bundle branches –> Purkinje fibers

Question 46

Why does the AV node delay conduction?

Answer 46

Allows for the filling of atria and ventricles

Question 47

What ion is responsible for initial depolarization in non-pacemaker cells?

Answer 47

Na+ influx causes rapid depolarization

Question 48

What ion is responsible for initial repolarization?

Answer 48

K+ efflux begins initial repolarization

Question 49

What ion causes initial repolarization to slow down?

Answer 49

Ca2+ influx balances the flow of K+, which effectively causes slower repolarization

Question 50

What ion causes full repolarization to occur?

Answer 50

K+ efflux continues, resulting in full repolarization

Question 51

What ion is involved in pacemaker cell depolarization?

Answer 51

Calcium gated channels open and cause an influx of Ca2+

Question 52

What are the two types of refractory periods?

Answer 52

• Absolute Refractory Period
• Relative Refractory Period

Question 53

What is the absolute refractory period?

Answer 53

This is the time following a depolarization event in which the cell cannot be re-excited

Question 54

What is the relative refractory period?

Answer 54

This is the time immediately after the absolute refractory period, when the cell can be re-excited but requires a higher voltage than the usual threshold

Question 55

Review slide 86 for ECG wave

Question 56

What event does the P-wave represent?

Answer 56

Atrial depolarization

Question 57

What event does the QRS complex represent?

Answer 57

Ventricular depolarization

Question 58

What event does the T wave represent?

Answer 58

Ventricular repolarization

Question 59

Why does atrial repolarization not have a separate wave on an ECG?

Answer 59

It is obscured within the large QRS complex (ventricular depolarization)

Question 60

What is automaticity?

Answer 60

It is the spontaneous impulse generation in latent pacemaker cells

Cells beyond the SA node are generating depolarization

ex. sinus tachycardia

Question 61

What is re-entrant arrhythmias?

Answer 61

It is the indefinite propagation of the impulse and continued activation of previously refractory cells (can result in impulses that move backwards)

Question 62

What are three requirements for re-entry arrhythmia?

Answer 62

1. Two pathways for impulse conduction
2. An area of unidirectional block (prolonged refractoriness)
3. Slow conduction in the other pathway

Question 63

How do anti-arrythmia drugs work?

Answer 63

They work by blocking ion channels by binding to a site on the ion channel proteins (significant impact action potential, and by extention conduction of electricity in the heart)

Question 64

What are the main drug classes involved in antiarrhythmia drugs?

Answer 64

(Class Ia, Ib, Ic) are Na+ channel blockers

Class II are beta-blockers

Class III are K+ channel blockers

Class IV are CCBs

Question 65

What are the Class Ia antiarrhythmia drugs and what is their specific impact on the ECG?

Answer 65

Quinidine

Procainamide

They increase QRS and QT duration by blocking on Na+ channels

Question 66

What are the Class Ib antiarrhythmia drugs and what is their specific impact on ECG readings?

Answer 66

Lidocaine

Mexilitene

They reduce QT duration by shortening repolarization phase

Question 67

What are the Class Ic antiarrhythmia drugs and what is their specific impact on ECG readings?

Answer 67

Propafenone

Flecanide

They significantly increase QRS (more potent Na+ channel blockers than Class Ia). They do this by prolonging depolarization

Question 68

What is the benefit of beta-blockers in anti-arrhythmia therapy?

Answer 68

Anti-adrenergic action
- Slows down conduction velocity
- Longer refractoriness
- Reduced automaticity

Question 69

What are some examples of Class III anti-arrhythmia drugs?

Answer 69

Amiodarone, sotalol, dofetilide, dronedarone, ibutilide

K+ channel blockers (prolong refractory period)

Question 70

What antiarrhythmia drug is the most effective?

Answer 70

Amiodarone
- Na+ blockade
- Beta blockade
- K+ blockade
- Ca2+ channel blockade

Due to broad action, amiodarone also has lots of side effects

Question 71

What are some examples of Class IV anti-arrhythmia drugs?

Answer 71

Verapamil

Diltiazem

• Slow conduction
• Prolong refractoriness
• Decrease automaticity of Ca2+ dependent cells in the SA and AV nodes

Question 72

What is the use of digoxin in anti-arrhythmia therapy?

Answer 72

Inhibitor of Na+/K+/ATPase

Increases vagal tone (reduced conduction velocity)

Increases AV node refractoriness

Question 73

What are the four classifications of arrhythmias?

Answer 73

Bradyarrhythmia

Tachyarrhythmia

Supraventricular (above the ventricles)

Ventricular (occurring within the ventricles)

Question 74

What are some characteristics of bradyarrhythmia?

Answer 74

Usually patients won’t have symptoms unless heart rate is dropping below 50bpm

Caused by a conduction delay or block in an area of the AV conduction system (due to myocarditis, b-blockers, CCBs, acute MI, congenital disease)

Question 75

What are the different degrees of AV block?

Answer 75

• First degree (least prolonged PR interval)
• Second degree
• Third degree (most severe due to absense of AV conduction)

Question 76

What are some symptoms of bradyarrhythmia?

Answer 76

Symptoms include the following:
- Fatigue
- Lightheadedness
- Palpitations
- Syncope

Question 77

What is the treatment option for bradyarrhythmia?

Answer 77

Pacemaker

Question 78

What is sick sinus syndrome?

Answer 78

It is a type of bradyarrhythmia

• Pauses or dropped beats due to SA node dysfunction
• Usually caused by degenerate changes due to age
• Leave it alone, unless symptomatic, then pacemakers

Question 79

What are some characteristics of supraventricular tachycardia?

Answer 79

Heart rates are greater than 100bpm

Usually caused by re-entry mechanisms

Question 80

What are some symptoms associated with supraventricular tachycardia?

Answer 80

• Palpitations
• Fatigue
• Lightheadedness
• Neck fullness
• Chest pain

Question 81

What are some treatment options for supraventricular tachycardia (tachyarrhythmia)?

Answer 81

For narrow QRS complex:
- First line (vagal maneuvers)
- Second line (adenosine, IV beta-blocker, CCB)

Question 82

What are some classfications of supraventricular tachycardia (tachyarrhythmia)?

Answer 82

• Atrial fibrilation/flutter
• Multifocal Atrial Tachycardia (MAT)
• AV Nodal Re-entrant Tachycardia (AVNRT)
• AV re-entrant tachycardia (AVRT)

Question 83

What are some types of ventricular tachyarrhythmia?

Answer 83

Premature Ventricular Complexes (PVCs)
- benign, common

Ventricular tachycardia (VT)
- Potentially fatal. life-threatening

Ventricular fibrillation (VF)
- Fatal, medical emergency

Question 84

What are some characteristics associated with pre-mature ventricular complexes?

Answer 84

Often asymptomatic, can occur in healthy individuals

Usually don’t require any treatment (can use beta-blockers if patient is affected significantly)

Question 85

What are some characteristics of ventricular tachyarrhythmia?

Answer 85

Can be acutely caused by metabolic abnormality, ischemia, or drug toxicity, or can be chronic and recur in paroxysmal form

Question 86

What are some treatment options for ventricular tachyarrhythmias

Answer 86

Sustained VT, unstable patient
- direct current cardioversion

Stable patient:
- IV procainamide, amiodarone, lidocaine

Question 87

What is the most effective maintenance therapy to prevent VT recurrence?

Answer 87

Amiodarone is most effective as maintenance therapy to prevent VT recurrence

Sotalol is also a potential drug maintenance therapy

Ablation can be considered if medication therapy fails

Question 88

What is torsade de pointes?

Answer 88

Life threatening form of VT

Associated with long QT interval on ECG

Treatment: Magnesium sulfate 2g IV, DC cardioversion

Question 89

What is an implantable cardioverter defibrillator?

Answer 89

It is an option for secondary prevention of spontaneous coronary death secondary to life threatening ventricular arrhythmia

But beta-blockers are often used to prevent future ventricular arrhythmia

Question 90

What are some adverse effects associated with amiodarone use?

Answer 90

QT prolongation

Hyper/hypothyroidism

Blue-gray discolouration

Liver enzyme elevation

Optic neuropathy

Question 91

What are some events associated with the QT wave?

Answer 91

Ventriular depolarization and atrial repolarization

When it is prolonged, there is a delay in repolarization

Can lead to torsade de pointes

Question 92

What is the risk of QT prolongation with anti-arrhythmic medications?

Answer 92

Higher due to potassium channel blocking properties

Sotalol risk of torsade de pointes is 4% (Extremely high compared to other drugs like antibiotics)

Question 93

What is QTc?

Answer 93

It is corrected QT interval

This helps better determine if patients are at risk for QT prolongation.

Need to be worried if QTc exceeds 500ms

Question 94

What scale is used to assess risk for Torsade de Pointes?

Answer 94

Tisdale score helps dentify individual patient risk score

• Age over 68
• Female sex
• Loop diuretic (hypokalemia)
• QTc interval beyond 450ms
• HFrEF
• Many more