Lecture 3: Drugs for Cardiac Arrhythmia Flashcards
What are the 3 class 1A antiarrhythmic drugs?
- Quinidine
- Procainamide
- Disopyramide
What are the 2 class 1B antiarrhythmic drugs?
- Lidocaine
- Mexiletine
What are the 2 class 1C antiarrhythmic drugs?
- Flecainide
- Propafenone
What are the two class 2 antiarrhythmic drugs (beta-blockers)?
- Esmolol
- Propranolol
What are the four class 3 antiarrhythmic drugs?
- Amiodarone
- Sotalol
- Dofetilide
- Ibutilide
What are the two class 4 antiarrhythmic drugs?
- Verapamil
- Diltiazem
What is the one miscellaneous agents used as an antiarrhythmic drug?
Adenosine
What are the 3 cell types in the heart that exhibit fast AP?
- Ventricular contractile cardiomyocytes
- Atrial cardiomyocytes
- Purkinje fibers
What are the 2 cell types in the heart that exhibit slow (pacemaker) AP’s?
- SA node cells
- AV node cells
Briefly describe the 5 phases of fast AP in cardiac muscle?
- 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
Describe the ion currents involved in phase 4 of the slow (pacemarker) AP?
- Poorly selective ionic influx (Na+, K+) known as pacemaker current (Funny current, If) - activated by hyperpolarization
- Slow Ca2+ influx [via T-type (transient) channels]
What is responsible for the rapid upstroke of phase 0 and repolarization of phase 3 of the pacemaker AP?
- Phase 0: influx of Ca2+ thru slow L-type (long-acting) Ca2+ channels
- Phase 3: inactivation of Ca2+ channels w/ ↑ K+ efflux
How does a resting potential that is less negative affect the time needed for an AP to reach threshold and affect on firing rate?
- Less time is needed to reach threshold
- Firing rate ↑
What are the 3 states that the Na+ channel found on cardiac myocytes exists in and describe each?
- 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
Which channels are blocked by Class 1A antiarrhythmics?
- Block Na+ channels
- Block K+ channels
Class 1A antiarrhythmics block sodium channels in a state dependent manner, preferentially when in what state?
Cells with what characteristics will be preferentially targeted?
- Preferentially bind to open (activated) Na+ channels
- Ectopic pacemaker cells w/ faster rhythms will be preferentially targeted
What is the effect of Class 1A antiarrhythmics on the the different phases of the AP, QRS and QT intervals?
- Decrease slope of phase 0 (blockade of Na+ channels)
- Prolong AP duration (blockade of K+ channels)
- Prolong QRS and QT intervals of the ECG
What is the clinical use of the class 1A antiarrhythmic, procainamide?
- Tx sustained ventricular tachycardias, may be used in arrhythmias associated w/ MI
- Paroxysmal supraventricular tachycardia (PSVT)
The class 1A antiarrhythmic, procainamide also has blocking effects where?
- Antimuscarinic
- Ganglion blocking
What are 3 cardiac AE’s associated with the class 1A antiarrhythmics, Procainamide and Quinidine?
- QT interval prolongation
- Induction of torsade de pointes arrhythmias and syncope
- Excessive inhibition of conduction
What are some rare extra-cardiac and common AE’s associated with the class 1A antiarrhythmic, Procainamide?
- Drug-induced lupus syndrome w/ arthritis, pleuritis, pulmonary dz, hepatitis
- Agranulocytosis
- Common = N/V, diarrhea, rash, fever, or hypotension
What is the clinical use for the class 1A antiarrhythmic, Quinidine?
- Restoring rhythm in Afib/flutter pt’s w/ normal (but arrhythmic) hearts
- Sustained ventricular arrhythmia
The class 1A antiarrhythmic, Quinidine, also has what other blocking effects?
- Anticholinergic effects
- Beta-blocking effects
What is the triad of Cinchonism and what class 1A antiarrhythmic may cause this as an AE?
- HA, dizziness, and tinnitus
- Quinidine
What are some of the extra-cardiac AE’s associated with the class 1A antiarrhythmic, Quinidine?
- GI effects –> diarrhea + N/V
- Cinchonism
- Thrombocytopenia
- Hepatitis and fever
What is the main clinical implication for the class 1A antiarrhythmic, Disopyramide?
Prevent recurrence of ventricular tachycardia or ventricular fibrillation
Other than antiarrhythmic activity, what other type of effect does Disopyramide have and what are the AE’s associated with this effect?
- Potent antimuscarinic effect
- Dry mouth + blurred vision + constipation + urinary retention + exacerbation of glaucoma
What are the cardiac AE’s of the class 1A antiarrhythmic, Quinidine?
- QT interval prolongation –> induction of torsade de pointes arrhythmia
- Negative inotrope effect - may precipitate HF
Which ion channel(s) are blocked by the class 1B antiarrhythmic?
Na+ channels only
Class 1B antiarrhythmic exhibit state-dependent blocking of Na+ channels in which state?
Preferentially bind cells in what state of membrane potential?
- Inactivated Na+ channels
- Depolarized cells
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?
- Class 1A = dissociate w/ intermediate kinetics = medium blockade
- Class 1B = dissociate w/ fast kinetics = weak blockade
- Class 1C = dissociate w/ slow kinetics = strong blockade
What is the effect of class 1B antiarrhythmics on AP and QT duration?
- May shorten AP
- Since do not block K+ channels, do not prolong AP or QT duration on ECG
Why is the class 1B antiarrhythmic, Lidocaine useful in damaged tissue based on its MOA?
- Blocks inactivated Na+ channels (use-dependence)
- Selectively blocks conduction in depolarized tissue, making damaged tissue “electrically silent.”
Why does the class 1B antiarrhythmic, Lidocaine have no effect on cardiac conductivity in normal tissue?
Rapid kinetics results in recovery from block between AP, exerts greater effects in depolarized (i.e., ischemic) and/or rapidly driven tissues