Lecture 3: Drugs for Cardiac Arrhythmia

Question 1

What are the 3 class 1A antiarrhythmic drugs?

Answer 1

• Quinidine
• Procainamide
• Disopyramide

Question 2

What are the 2 class 1B antiarrhythmic drugs?

Answer 2

• Lidocaine
• Mexiletine

Question 3

What are the 2 class 1C antiarrhythmic drugs?

Answer 3

• Flecainide
• Propafenone

Question 4

What are the two class 2 antiarrhythmic drugs (beta-blockers)?

Answer 4

• Esmolol
• Propranolol

Question 5

What are the four class 3 antiarrhythmic drugs?

Answer 5

• Amiodarone
• Sotalol
• Dofetilide
• Ibutilide

Question 6

What are the two class 4 antiarrhythmic drugs?

Answer 6

• Verapamil
• Diltiazem

Question 7

What is the one miscellaneous agents used as an antiarrhythmic drug?

Answer 7

Adenosine

Question 8

What are the 3 cell types in the heart that exhibit fast AP?

Answer 8

• Ventricular contractile cardiomyocytes
• Atrial cardiomyocytes
• Purkinje fibers

Question 9

What are the 2 cell types in the heart that exhibit slow (pacemaker) AP’s?

Answer 9

• SA node cells
• AV node cells

Question 10

Briefly describe the 5 phases of fast AP in cardiac muscle?

Answer 10

• Phase 0: depolarization; inward Na+ flux
• Phase 1: partial repolarization K+ efflux, while fast Na+ channels close
• Phase 2: plateau, K+ exiting, offset by Ca^{<strong>2</strong>+} entering thru slow channels
• Phase 3: Ca^{<strong>2</strong>+} channels close and K+ begins to exit rapidly = repolarization
• Phase 4: stable RMP gradually restored by Na+/K+ ATPase and Na+/Ca²⁺ exchanger

Question 11

Describe the ion currents involved in phase 4 of the slow (pacemarker) AP?

Answer 11

• Poorly selective ionic influx (Na+, K+) known as pacemaker current (Funny current, I_f) - activated by hyperpolarization
• Slow Ca²⁺ influx [via T-type (transient) channels]

Question 12

What is responsible for the rapid upstroke of phase 0 and repolarization of phase 3 of the pacemaker AP?

Answer 12

• Phase 0: influx of Ca²⁺ thru slow L-type (long-acting) Ca²⁺ channels
• Phase 3: inactivation of Ca²⁺ channels w/ ↑ K+ efflux

Question 13

How does a resting potential that is less negative affect the time needed for an AP to reach threshold and affect on firing rate?

Answer 13

• Less time is needed to reach threshold
• Firing rate ↑

Question 14

What are the 3 states that the Na+ channel found on cardiac myocytes exists in and describe each?

Answer 14

• Resting: the channel is closed but ready to generate AP
• Activated state: depolarization to threshold opens m-gates greatly ↑ Na+ permeability
• Inactivated state: h-gates are closed, inward Na+ flux is inhibited, the channl is not available for reactivation –> refractory period

Question 15

Which channels are blocked by Class 1A antiarrhythmics?

Answer 15

• Block Na⁺ channels
• Block K+ channels

Question 16

Class 1A antiarrhythmics block sodium channels in a state dependent manner, preferentially when in what state?

Cells with what characteristics will be preferentially targeted?

Answer 16

• Preferentially bind to open (activated) Na⁺ channels
• Ectopic pacemaker cells w/ faster rhythms will be preferentially targeted

Question 17

What is the effect of Class 1A antiarrhythmics on the the different phases of the AP, QRS and QT intervals?

Answer 17

• Decrease slope of phase 0 (blockade of Na+ channels)
• Prolong AP duration (blockade of K+ channels)
• Prolong QRS and QT intervals of the ECG

Question 18

What is the clinical use of the class 1A antiarrhythmic, procainamide?

Answer 18

• Tx sustained ventricular tachycardias, may be used in arrhythmias associated w/ MI
• Paroxysmal supraventricular tachycardia (PSVT)

Question 19

The class 1A antiarrhythmic, procainamide also has blocking effects where?

Answer 19

• Antimuscarinic
• Ganglion blocking

Question 20

What are 3 cardiac AE’s associated with the class 1A antiarrhythmics, Procainamide and Quinidine?

Answer 20

• QT interval prolongation
• Induction of torsade de pointes arrhythmias and syncope
• Excessive inhibition of conduction

Question 21

What are some rare extra-cardiac and common AE’s associated with the class 1A antiarrhythmic, Procainamide?

Answer 21

• Drug-induced lupus syndrome w/ arthritis, pleuritis, pulmonary dz, hepatitis
• Agranulocytosis
• Common = N/V, diarrhea, rash, fever, or hypotension

Question 22

What is the clinical use for the class 1A antiarrhythmic, Quinidine?

Answer 22

• Restoring rhythm in Afib/flutter pt’s w/ normal (but arrhythmic) hearts
• Sustained ventricular arrhythmia

Question 23

The class 1A antiarrhythmic, Quinidine, also has what other blocking effects?

Answer 23

• Anticholinergic effects
• Beta-blocking effects

Question 24

What is the triad of Cinchonism and what class 1A antiarrhythmic may cause this as an AE?

Answer 24

• HA, dizziness, and tinnitus
• Quinidine

Question 25

What are some of the extra-cardiac AE’s associated with the class 1A antiarrhythmic, Quinidine?

Answer 25

• GI effects –> diarrhea + N/V
• Cinchonism
• Thrombocytopenia

- Hepatitis and fever

Question 26

What is the main clinical implication for the class 1A antiarrhythmic, Disopyramide?

Answer 26

Prevent recurrence of ventricular tachycardia or ventricular fibrillation

Question 27

Other than antiarrhythmic activity, what other type of effect does Disopyramide have and what are the AE’s associated with this effect?

Answer 27

• Potent antimuscarinic effect
• Dry mouth + blurred vision + constipation + urinary retention + exacerbation of glaucoma

Question 28

What are the cardiac AE’s of the class 1A antiarrhythmic, Quinidine?

Answer 28

• QT interval prolongation –> induction of torsade de pointes arrhythmia
• Negative inotrope effect - may precipitate HF

Question 29

Which ion channel(s) are blocked by the class 1B antiarrhythmic?

Answer 29

Na⁺ channels only

Question 30

Class 1B antiarrhythmic exhibit state-dependent blocking of Na⁺ channels in which state?

Preferentially bind cells in what state of membrane potential?

Answer 30

• Inactivated Na⁺ channels
• Depolarized cells

Question 31

What is the kinetics of dissociation from the Na+ channel like for the class 1A, 1B, and 1C antiarrhythmics and how does this correlate with their strength of blockade?

Answer 31

• Class 1A = dissociate w/ intermediate kinetics = medium blockade
• Class 1B = dissociate w/ fast kinetics = weak blockade
• Class 1C = dissociate w/ slow kinetics = strong blockade

Question 32

What is the effect of class 1B antiarrhythmics on AP and QT duration?

Answer 32

• May shorten AP
• Since do not block K+ channels, do not prolong AP or QT duration on ECG

Question 33

Why is the class 1B antiarrhythmic, Lidocaine useful in damaged tissue based on its MOA?

Answer 33

• Blocks inactivated Na⁺ channels (use-dependence)
• Selectively blocks conduction in depolarized tissue, making damaged tissue “electrically silent.”

Question 34

Why does the class 1B antiarrhythmic, Lidocaine have no effect on cardiac conductivity in normal tissue?

Answer 34

Rapid kinetics results in recovery from block between AP, exerts greater effects in depolarized (i.e., ischemic) and/or rapidly driven tissues

Question 35

What are the 2 clinical indications for the use of the class 1B antiarrhythmic, Lidocaine?

Answer 35

• In mono- and polymorphic ventricular tachycardias
• Very efficient in arrhythmias assoc. w/ acute MI

Question 36

What is the pharmacokinetics of the class 1B antiarrhythmic, Lidocaine like and needs to be given via which route?

Answer 36

Extensive first-pass metabolism; must give IV

Question 37

What is the least toxic of all class 1 antiarrhythmics?

Answer 37

Lidocaine (class 1B)

Question 38

What are some of the CV and neurological AE’s associated with the class 1B antiarrhythmic, Lidocaine?

Answer 38

• CV = may cause hypotension in pt’s w/ HF by inhibiting contractility
• Neuro = paresthesias, tremor, slurred speech, and convulsions

Question 39

Which class 1B antiarrhythmic is a lidocaine analog modified to reduce first-pass metabolism and permit chronic oral therapy?

Answer 39

Mexiletine

Question 40

The electrophysiological and antiarrhythmic effects of the class 1B antiarrhythmic, Mexiletine are similar to what?

Answer 40

Lidocaine (since is a modified analog)

Question 41

What are the 2 clinical uses for the class 1B antiarrhythmic, Mexiletine?

Answer 41

• Ventricular arrhythmias
• Relieve chronic pain, especially pain due to diabetic neuropathy and nerve injury

Question 42

What are 4 AE’s associated with the class 1B antiarrhythmic, Mexiletine?

Answer 42

• Tremor
• Blurred vision
• Nausea
• Lethargy

Question 43

Which ion channel(s) are blocked by class 1C antiarrhythmics?

Answer 43

• Block Na⁺ channels
• Block certain K+ channels

Question 44

What is the strength of the Na⁺ channel block associated with class 1C antiarrhythmics and preferentially block channels in which state?

Answer 44

• Strong/long-lasting block due to slow dissociation from channel
• Preferentially bind Na⁺ channel in open (activated) state

Question 45

Which interval is prolonged by the class 1C antiarrhythmics due to blockage of certain K+ channels?

Answer 45

• Prolong QRS interval
• NO effect on AP or QT duration

Question 46

What is the clinical use of the class 1C antiarrhythmic, Flecainide?

Patients with which cardiac status specifically?

Answer 46

• In pts with normal hearts
• Tx of supraventricular arrhythmias including atrial fibrillation, paroxysmal SVT (AV nodal reentrant tachy, AV reentrate tachy)
• Life-threatening ventricular arrhythmias, such as sustained V-Tach

Question 47

The class 1C antiarrhythmic, Flecainide may be very effective in suppressing premature ventricular contractions, but pt’s with what cardiac status are at risk for AE’s and what are these effects?

Answer 47

• May cause severe exacerbation of ventricular arrhythmias if given to:
• Pts w/ preexisting ventricular tachyarrhythmias, a previous MI, or those w/ ventricular ectopic rhythms

Question 48

Which class 1C antiarrhythmic also possesses weak β-blocking activity?

Answer 48

Propafenone (kind of sounds like propranolol)

Question 49

What are the 2 clinical uses of the class 1C antiarrhythmic, Propafenone?

Specifically pt’s with what cardiac status?

Answer 49

• Pt’s WITHOUT structural disease
• Prevent paroxysmal atrial fibrillation and SVT
• Used in sustained ventricular arrhythmias

Question 50

The class 1C antiarrhythmic, Propafenone, should not be combined with inhibitors of what 2 enzymes as the risk of proarrhythmia may be increased?

Answer 50

CYP2D6 and CYP3A4 inhibitors

Question 51

What are 3 AE’s associated with the class 1C antiarrhythmic, Propafenone?

Answer 51

• Exacerbation of ventricular arrhytmias
• Metallic taste
• Constipation

Question 52

What is the effect of the sympathetic NS on the I_f, T-type and L-type Ca²⁺ channels involved in pacemaker action potentials?

Answer 52

• ↑ slope of phase 4 due to effects on I_f and T-type Ca²⁺ channels
• Effect on L-type Ca²⁺ channels = lowers the threshold

Question 53

What is the effect of the class 2 antiarrhythmic (beta-blockers) at the SA and AV node?

Effect on which 2 intervals?

Answer 53

• SA node = ↓ HR (increase RR interval)
• AV node = ↓ AV conductance (increase PR interval)

Question 54

What is the effect of the class 2 antiarrhythmic (beta-blockers) on the slop of phase 4 and the threshold of the pacemarker AP?

Answer 54

• Decreased slope due to effects on I_f and T-type Ca²⁺ channels
• Increased threshold due to effect on L-type Ca²⁺ channels

*Net effect = slow AP + ↓ HR + ↓ AV conductance

Question 55

What are the 4 clinical indications for the use of the class 2 antiarrhythmic, Propranolol for arrhythmias?

Decrease mortaility from arrhythmias in which pt’s?

Answer 55

• Arrhythmias associated w/ STRESS (i.e., catecholamines)
• Re-entrant arrhythmias that involve AV node –> AVNRT and AVRT
• Afib and flutter
• Arrhythmias associated w/ MI –> ↓ mortality in pt’s with acute MI

Question 56

Which class of antiarrhythmics is reserved for use in pt’s with a structually normal heart?

Answer 56

Class 1C = Flecainide and Propafenone

Question 57

Which class 2 antiarrhythmic is a short-acting (t_1/2 5-10 min) SELECTIVE β1-blocker?

Answer 57

Esmolol

Question 58

Due to it’s short half-life how is Esmolol administered clinically as an antiarrhythmic?

Answer 58

Continous IV infusion when rapid adrenergic blockade is desired

Question 59

What are the 3 clinical uses for the class II antiarrhythmic, Esmolol?

Answer 59

• Supraventricular arrhythmias
• Arrhythmias association with thyrotoxicosis, myocardial ischemia/infarction
• As an adjunct drug in general anesthesia to control arrhythmias in perioperative period

Question 60

List some of the AE’s associated with the class 2 antiarrhythmic, beta-blockers.

Answer 60

• Bradycardia + Bronchoconstriction
• Impaired liver glucose mobilization
• Worsens blood lipid profile
• Sedation + depression + fatigure
• Rapid withdrawl –> rebound HTN

Question 61

What are 6 contraindications for the the class 2 antiarrhythmic, beta-blockers?

Answer 61

• Asthma
• Peripheral vascular disease
• Raynaud’s
• Type 1 DM on insulin
• Bradyarrhythmias, AV conduction problems
• Severe depression of cardiac function

Question 62

Which K+ channels in the heart are open in the resting state?

Answer 62

Inward rectifying K+ channels

Question 63

Class 3 antiarrhytmics block which ion channel and in which state?

Answer 63

Bind K+ channels in the resting state = reverse use dependence

Question 64

What is the effect of class 3 antiarrhytmics on the AP, QT interval and refractory period?

Answer 64

• Prolong AP duration
• Prolong QT interval
• Prolong refractory period

Question 65

K+ channels in the heart are responsible regulating which parts of the membrane potential?

Answer 65

• Regulation of resting potential via inward rectifying K+ channels which are open in resting state
• Regulation of AP via voltage-gate K+ channels which repolarize and limit the frequence of AP’s (regulate duration of the refractory period)

Question 66

Which class 3 antiarrhytmic prolongs QT interval and APD uniformly over a wide range of heart rates and in all cardiac tissues?

Answer 66

Amiodarone

Question 67

What are the 2 clinical uses for the class 3 antiarrhytmic, Amiodarone?

Answer 67

• Tx of ventricular arrhythmias
• Atrial fibrillation

Question 68

What is unique about the pharmacokinetics of the class 3 antiarrhytmic, Amiodarone, including t_1/2, elimination, and interactions?

Answer 68

• Major metabolite has t_1/2 = ~ 50 days
• Effects maintainied for 1-3 months after discontinuation and metabolites may be found in tissues 1 year later (highly lipophilic)
• Inhibits many CYP enzymes so can affect metabolism of other drugs

Question 69

Which class 3 antiarrhythmic has a lower incidence of torsade de pointes as an AE compard to others in the class?

Answer 69

Amiodarone

Question 70

What are 5 of the extra-cardiac AE’s associated with the class 3 antiarrhytmic, Amiodarone?

Answer 70

• Pulmonary fibrosis (can be fatal)
• Hepatitis
• Hyperthyroidism or hypothyroidism
• Corneal micro-deposits
• Bluish discoloration of the skin

Question 71

What are the 2 MOA’s of the class 3 antiarrythmic, Sotalol?

Answer 71

• Non-selective β-AR antagonist (class 2)
• Blocks inward-rectifier K+ channels (class 3) = prolongs ADP

Question 72

What are the 2 clinical uses of the class 3 antiarrhythmic, Sotalol?

Answer 72

• Tx of life-threatening ventricular tachyarrhythmias
• Maintenance of sinus rhythm in pt’s w/ atrial fibrillation

Question 73

What are the 2 major AE’s associated with the class 3 antiarrhytmic, Sotalol?

Answer 73

• Depression of cardiac function (same as β-blockers)
• Provokes torsade de pointes

Question 74

What is the specific MOA of the class 3 antiarrhythmic, Dofetilide?

Effect of drug is most pronounced at which HR’s?

Answer 74

• Potent and “pure” IKr (inward K+ rectifier) blocker
• More pronounced effect at lower HR’s

Question 75

Why does the class 3 antiarrhythmic, Dofetilide have a narrow therapeutic window?

Answer 75

Majority is excreted by kidneys; must adjust dose based on Cr clearance

Question 76

What are the major AE’s of the class 3 antiarrhythmic, Dofetilide?

Answer 76

• Torsades de pointe

- QT interval prolongation and ↑ risk of ventricular arrhythmias

Question 77

What is the clinical use for the class 3 antiarrhytmic, Dofetilide?

Answer 77

Maintenance of normal sinus rhythm in pt’s with chronic atrial fibrillation/atrial flutter AFTER cardioconversion

Question 78

What is the specific MOA of the class 3 antiarrhytmic, Ibutilide?

Answer 78

Similar to dofetilide, slows cardiac repolarization as a I_Kr blocker

Question 79

How is the the class 3 antiarrhytmic, Ibutilide adminstered and it’s clinical use?

Answer 79

Via rapid IV infusion for immediate conversions of acute atrial fibrillation or flutter —> sinus rhythm

Question 80

What are the AE’s associated with the class 3 antiarrhytmic, Ibutilide?

Due to AE’s pt’s require what?

Answer 80

• Torsades de pointes, requires immediate cardioconversion
• Must monitor EKG continously unti QT_c returns to baseline
• Incrased risk of other arrhytmias

Question 81

Which specific channels and in which state do the class 4 antiarrhytmics (verapamil and diltiazem) block?

Answer 81

Both activated and inactivated L-type Ca²⁺ channels

Question 82

What is the effect of the class 4 antiarrhytmics on the slope of phase 0, threshold potential at the SA node, and refractory period?

Answer 82

• Decrease the slope of phase 0
• ↑ L-type Ca²⁺ threshold potential in SA node = slows depolarization –> bradycardia
• Prolongs refractory period in AV node = prolongs APD and conduction time

Question 83

What are the 2 clinical uses for the class 4 antiarrhythmics?

Answer 83

• Prevention of paroxysmal SVT
• Rate control in atrial fibrillation and atrial flutter

Question 84

What are the cardiac and extracardiac AE’s of the class 4 antiarrhythmics?

Answer 84

• CHF (negative inotropy)
• AV block
• SA node arrest
• Bradyarrhythmias
• Hypotension
• Constipation

Question 85

What is the MOA of adenosine in the heart (ie., receptors and effect)?

Answer 85

• Activates K+ current and inhibits Ca²⁺ and Funny current
• Causes marked hyperpolarization and suppression of AP’s in SLOW cells
• Inhibits AV conduction and increases nodal refractory period

Question 86

What is the clinical use of Adenosine for arrhythmias?

Answer 86

Conversion to sinus rhythm in paroxysmal SVT

Question 87

What are 5 AE’s associated with Adenosine?

Answer 87

• SOB
• Bronchoconstriction (both A₁ and A_2B adenosine receptors)
• Chest burning/fullness
• AV block
• Hypotension