8/20- Anti-arrhythmics

Question 1

What is an ectopic arrhythmia?

Answer 1

Originates outside normal conduction system

Question 2

What is sinus tachycardia?

Answer 2

Originates from normal AV node

Question 3

Define: paroxysmal

Answer 3

Sudden onset

Question 4

What is normal EDV? SV?

Answer 4

EDV = 140 mL

ESV = 70 mL

SV = 70 mL (normal is 50-65%)

Question 5

Describe the membrane potential changes that occur in cardiac myocytes

Answer 5

0: Rapid depolarization due to Na influx

1: Early repolarization (due to Na closure?)

2: Plateau due to Ca influx with K efflux

3: Repolarization due to K efflux

4: Resting potential maintained by diastolic Na (and Ca) influx

Question 6

What are the different targets for anti-arrhythmic drugs?

Answer 6

• Na channels
• K channels
• Ca channels
• Resting membrane potential (beta blockers)

Question 7

What is If (funny current)?

Answer 7

Mediated by HCN channels (Hyperpolarization-activated Cyclic Nucleotide-gated)

• Non-selective cation channels (Na and K)
• Activated by hyperpolarization of cell as well as increased levels of cAMP
• HCN channels close during depolarization
• Responsible for increasing resting potential in nodal cells (Na influx and K efflux?)

Question 8

Differences between SA node and ventricular myocytes?

Answer 8

Resting membrane potentials:

• SA node: -55 mV
• AV node:-65 mV
• Vent myocytes: -85 mV

Threshold

• Same (as well as the ions responsible for AP)

Big difference:

• Ca current important in SA node depol (why CCBs will reduce heart rate more than contractility)
• Na current is the key depolarizing current in myocytes

Question 9

What is the result of potassium imbalance in regards to depol/rhythm?

Answer 9

Increased tendency to depolarize

Question 10

What is the result of hypoxia in regards to depol/rhythm?

Answer 10

Hypoxia -> higher Ca inside cells -> increased tendency to depolarize from ectopic loci

Question 11

What is an escape beat/what causes it?

Answer 11

SA nodal firing is too slow and latent pacemaker fires an escape beat

• A series of escape beats may -> arrhythmia

Question 12

What is an ectopic beat/what causes it?

Answer 12

Latent pacemaker starts beating faster than SA node

• SA node firing is suppressed by faster-paced latent pacemaker
• Series of ectopic beats -> arrhythmia

Question 13

What increases the possibility of early afterdepolarization?

Answer 13

QT prolongation

Question 14

What is early afterdepolarization?

Answer 14

• Generally occur during repolarizing phase of action potential
• Repetitive can trigger arrhythmia (“torsades de pointes”)
• Increased by QT prolongation

Question 15

Prolonged QT interval leads to what?

Answer 15

Ventricular arrhythmias

• QT interval corresponds to ventricular depol and repol

Question 16

What drugs can convert unidirectional block to bidirectional block?

How is this clinically useful?

Answer 16

Some Class 1 drugs

• Lidocaine

(This prevents conduction through the damaged area and interrupts the reentrant arrhythmias)

Question 17

What does a bypass tract result in?

Prevalence in normal population?

Answer 17

• Bypass tract (bundle of Kent) will depolarize early and -> arrhythmias (WPW)
• 0.1-0.3% in general population (1-3/1000)

Question 18

What are the 4/5 classes of antiarrhythmic drugs?

Answer 18

1. Na channel blockers (class Ia, Ib, Ic)
2. Beta blockers (class II)
3. K channel blockers (class III)
4. Ca channel blockers (class IV)
5. Other mechanisms (class V)

Question 19

What are mechanisms of antiarrhythmics?

Answer 19

1. Alter (lower) resting membrane potential
2. Alter the rate of phase 4 depolarization
3. Alter the threshold potential
4. Alter the duration of AP (refractory period)

Question 20

What is the mechanism behind Lidocaine?

Difference between Ia, Ib, Ic?

Answer 20

Na channel blocker

Rate of drug binding and refractory period in subtypes:

Ia:

• Intermediate binding
• Increases refractory period

Ib:

• Rapid binding
• Decreases refractory period

Ic:

• Slow
• Unchanged refractory period

Note: some Na channels open during diastolic phase (“diastolic sodium current”; these are different from the VG-Na channels)

Question 21

All channels come in at least what 3 conformations?

Answer 21

Ex) Na channel

• Resting Na channel; fully repolarized (closed, ready to open)
• Open Na channel
• Inactivated Na channel (closed; cannot be opened)

Question 22

On what feature of ion channels does drug specificity depend?

Answer 22

Specificity of drugs is due to their higher affinity to open/inactivated conformations

Question 23

To which ion channel states do Na channel blockers have preference?

Answer 23

Drug binding is channel-state dependent

• Open Na channel
• Inactivated Na channel (closed; can’t be open)

Question 24

What are some adverse effects of Na channel blockers?

Answer 24

1. Many also cause arrhythmias

• Class I drugs often used in hospital/under supervision

2. Class 1a: Quinidine (now low dose anti-malarial drug)

• Cinchonism (ringing in ears, photosensitivity)
• SA and AV block or asystole
• Precipitate V fib (prolongs QT interval)
• Increases digoxin levels by interfering with renal clearance

3. Class 1b: Lidocaine

• CNS: drowsiness, slurred speech, paresthesia, agitation, confusion, convulsions

(- “caine” drug is local anesthetic)

4. Class 1c: Flecainide

• Contraindicated in pts with CAD/CHF b/c of its proarrhythmic side effects

Question 25

Qunidine is a class 1a anti-arrhythmic drug. What is true:

A. Blocks Na channels and increases refractory period

B. Blocks ‘funny’ current (HCN channels) and increases refractory period

C. Blocks Na channels and decreases refractory period

D. Blocks Na channels and does not alter refractory period

Answer 25

Qunidine is a class 1a anti-arrhythmic drug. What is true:

A. Blocks Na channels and increases refractory period

B. Blocks ‘funny’ current (HCN channels) and increases refractory period

C. Blocks Na channels and decreases refractory period

D. Blocks Na channels and does not alter refractory period

• Class 1a antiarrhythmic drugs block Na channels and increases refractory period

Question 26

What are class II anti-arrhythics?

Answer 26

Beta blockers

Question 27

Examples of beta blockers? Suffix?

Answer 27

End in “-olol”

• Metaprolol
• Propranolol
• Esmolol

Question 28

How do beta blockers effect pacemaker cell APs?

Answer 28

Antagonize the tonic levels of E/NE and:

1. Decrease slope of phase 4 depolarization (decreases HR) and:
2. Prolongs repolarization (thus prolonged refractory period; especially important at AV node)

Question 29

Side effects/specifics of different beta blockers?

Answer 29

Propranolol- nonspecific; bronchospasm

Metaprolol- most common; extensively metabolized in liver; enters the CNS

Esmolol- very short acting; IV to treat acute arrhythmias in surgery or emergency

Sotalol- both a beta blocker and K channel blocker

Question 30

What are class III anti-arrhythmics? Examples?

How do they work?

Answer 30

Block repolarization K channels (prolongs refractory period and make it more difficult to initiate another depolarization cycle)

• Target mostly cardiac myoctes

Examples)

• Amiodarone (mostly class III, also I, II and IV)
• Sotalol (class II and III)

Question 31

What are class IV anti-arrhythimcs? Examples?

How do they work?

Answer 31

Ca channel blockers

• Slow the AP upstroke in SA and AV nodes
• Arrhythmc impulses less likely to be transmitted via AV node
• Targets mostly SA and AV node (Ca current is important in these)

Examples)

• Verapamil (cardioselective)
• Diltiazem (heart = vasculature)
• Nifedipine (–dipine) = more selective to vascular smooth muscle

Question 32

Amiodarine and Sotalol are what class of antiarrhythmics? Mechanism?

Answer 32

class III

• Block K channels

Question 33

Verapamil and Diltiazem are what class of antiarrhythmics? Mechanism?

Answer 33

class IV

• Block Ca channels

Question 34

Adverse effects of Amiodarone?

Answer 34

• Pulmonary fibrosis
• Hypo/hyperthyroidism
• Ocular and liver toxicity
• Neuropathy
• Optic neuritis
• Blue-gray skin discoloration

Need to monitor lung and thyroid function before starting and during treatment

Question 35

Adverse effects of Beta blockers?

Answer 35

• Contraindicated in pts with asthma
• Conduction problems

Question 36

What classes of drugs are used for supraventricular arrhythmias?

Answer 36

• Beta blockers (class II)
• CCBs (class IV)

Question 37

What classes of drugs are used for ventricular tachycardia, V fib and SCD survivors?

Answer 37

• Amiodarone (mostly class III)

Question 38

What classes of drugs are used to prevent SCD?

Answer 38

• Amiodarone (class III)
• Beta blockers (class II)

Question 39

When do we use class I drugs?

Answer 39

Rarely

Question 40

When is adenosine used? Mechanism?

Answer 40

Conversion of paroxysmal supraventricular tachycardia to normal sinus rhythm

• Very short half life (under 10s); administered via IV
• Hyperpolarizes the AV node (works in 90%)

Question 41

A 66 yo man has a Hx of myocardial infarction. Which one of the following would be appropriate prophylactic antiarrhythmic therapy?

A. Lidocaine

B. Metaprolol

C. Flecainide

D. Quinidine

E. Verapamil

Answer 41

A 66 yo man has a Hx of myocardial infarction. Which one of the following would be appropriate prophylactic antiarrhythmic therapy?

A. Lidocaine

B. Metaprolol

C. Flecainide

D. Quinidine

E. Verapamil

• Want to use a beta blocker

Question 42

A 58 yo woman is being treated for chronic suppression of a ventricular arrhythmia. After 2 mo of therapy, complains of being tired. Exam reveals low heart rate and cool/clammy skin. Lab test results show thyroxin and high TSH levels. Which of the following anti-arrhythmic drugs is the likely cause of these signs and Sx?

A. Amiodarone

B. Flecainide

C. Propranolol

D. Quinidine

E. Verapamil

Answer 42

A 58 yo woman is being treated for chronic suppression of a ventricular arrhythmia. After 2 mo of therapy, complains of being tired. Exam reveals low heart rate and cool/clammy skin. Lab test results show thyroxin and high TSH levels. Which of the following anti-arrhythmic drugs is the likely cause of these signs and Sx?

A. Amiodarone

B. Flecainide

C. Propranolol

D. Quinidine

E. Verapamil

Question 43

Class III anti-arrhythmic drugs work by:

A. Inhibiting Na current

B. Inhibiting Ca current

C. Antagonizing E/NE

D. Inhibiting/repolarizing K current

E. Inhibiting hyperpolarizing Cl current

Answer 43

Class III anti-arrhythmic drugs work by:

A. Inhibiting Na current

B. Inhibiting Ca current

C. Antagonizing E/NE

D. Inhibiting/repolarizing K current

E. Inhibiting hyperpolarizing Cl current

Question 44

Which of the following arrhythmias can be treated effectively by IV adenosine?

A. Paroxysmal supraventricular tachycardia

B. Atrial fibrillation

C. Atrial flutter

D. Ventricular tachycardia

E. Ventricular fibrillation

Answer 44

Which of the following arrhythmias can be treated effectively by IV adenosine?

A. Paroxysmal supraventricular tachycardia

B. Atrial fibrillation

C. Atrial flutter

D. Ventricular tachycardia

E. Ventricular fibrillation

• IV adenosine can be used to convert paroxysmal supraventricular tachycardia to normal sinus rhythm

Question 45

Most commonly used beta blocker to treat atrial flutter or atrial fibrillation is:

A. Sotalol

B. Carvedilol

C. Propranolol

D. Esmolol

E. Metoprolol

Answer 45

Most commonly used beta blocker to treat atrial flutter or atrial fibrillation is:

A. Sotalol

B. Carvedilol

C. Propranolol

D. Esmolol

E. Metoprolol

• Metoprolol is beta-1 specific and is most commonly used beta blocker to treat arrhythmias that are atrial in origin

Question 46

Which one of the following is NOT an adverse effect associated with use amiodarone?

A. Cinchonism

B. Hypothyroidism

C. Hyperthyroidism

D. Pulmonary fibrosis

E. Blue skin discoloration

F. Optic neuritis

Answer 46

Which one of the following is NOT an adverse effect associated with use amiodarone?

A. Cinchonism

B. Hypothyroidism

C. Hyperthyroidism

D. Pulmonary fibrosis

E. Blue skin discoloration

F. Optic neuritis

• Cinchonism is for quinidine