Anti-Arrhythmic Drugs PDF

Summary

This document provides a comprehensive overview of anti-arrhythmic drugs, explaining their mechanism of action and classification. It discusses various types of cardiac arrhythmias and the role of different types of drugs in managing them. The document uses diagrams to illustrate the underlying processes.

Full Transcript

Cardiac Conduction System
Starts w/ the S.A. node
○ We have a group of cells that get depolarized and these nerve cells are activated
by the autonomic nervous system
○ If there are activated by the autonomic nervous system, we have the beta-1
receptors (cause acceleration of the heart), muscarinic receptors
Inter-nodal pathways
A.V. node
○ The one that sends the message from the atrium to the ventricle
○ Also has beta-1 and muscarinic
○ Corresponding muscle: ventricular myocardium; mainly has beta-1 receptors and
very little muscarinic bc if there was more muscarinic, we would not have a
proper ejection fraction system
Bundle of His and branches
Purkinje fibers

 ○ P wave: depolarization of atria in response to SA node triggering
○ PR segment: delayed passage from sinus node to AV node to allow filling of
ventricles
○ QRS complex: involves the depolarization of ventricular muscle that causes
contractility, triggers main pumping contractions
○ ST segment: beginning of ventricular repolarization, should be flat
○ T: when the ventricular is repolarized
○ U wave: Residual polarization but in some patients, not all
3 types of supraventricular tachycardia: (Atro-tachycardia) - most common ones
○ Paroximal tachycardia (related to ectopic activation from atrium)
○ Atrial flutter
○ A-fib
Is tachycardia and arrhythmia the same thing?
○ Tachycardia is increased heart rate and if it is out of rhythm, it may be
pathological
Sinus tachycardia is tachycardia w/o arrhythmia
○ But it can lead to arrhythmia if it is too high
Ventricular tachycardia

Pacemaker Cells Action Potential (this allows to have contractility)
Slope of action potential determines HR
SA node cells, normal depolarization rate 60-100 PM
AV node cells, normal depolarization rate 40-60 PM
SA node is the primary pacemaker since it has a higher depolarization rate
3 phases
○ Phase 4 (orange)
SA node cells and AV nodes cells
Gradient depolarization (prepotential)
Slow influx of Na+ ions through
Membrane potential changes from -60 mV to reach the threshold potential
of -40 mV
○ Phase 0 (red)
Phase of depolarization (action potential)
Starts when the membrane potential reaches -40 mV
Opening of voltage-gated Ca2+ channels causing the influx of Ca2+ ion
Results in an upstroke in membrane potential from -40 mV +10 mV
○ Phase 3 (light blue)
Phase of depolarization
Involves the closing of Ca2+ channels, blocking the inflow of Ca2+ ions
Voltage-gated K+ channels open, allowing for efflux of K+ ions
Contributes to a rapid decrease of membrane potential from +10 mV to
-60 mV because of the outflux of K+ repolarization
○ Phases 1 & 2 are not present in pacemaker cells***
 ○

Myocytes Action Potential (this involves
5 phases
○ Phase 0 is the phase of depolarization
○ Phase 1-3, phases during which depolarization occurs
○ Phase 4 is the resting phase w/ no spontaneous depolarization
Phase 0
○ Rapid depolarization
○ Voltage-gated Na+ channels open, resulting in a rapid influx of Na+ ions
○ Membrane potential changes from -85 mV to +20 mV w/ steep upstroke
Phase 1
○ Inactivation of opened voltage-gated Na+ channels
○ Activation of transient outward potassium current
○ Slight drop in the membrane electrochemical potential which results in the
initiation of phase 2
Phase 2 (Plateau Phase)
○ Ca2+ influx occurs through an opening of voltage-gated L-type Ca2+ channel
○ Calcium influx balances the K+ efflux, creating a plateau
Phase 3
○ Repolarization
○ L-type Ca2+ channel close, K+ channels remain open
○ This allows more types of K+ channels (rapid delayed rectifier channels) to open
and the membrane to depolarize to its resting membrane potential (phase 4)

Arrhythmia:
An abnormality in:
○ Heart rhythm - extrasystoles (PAC, PVC)
Ectopic pacemakers or disturbance in conduction
○ Heart rate
High rate = tachycardia
Low rate = bradycardia
Sinus tachycardia and sinus bradycardia
They regular rhythm: this is NOT arrhythmia
Very high or low regular rhythm could predispose arrhythmia
Origin of Tachycardia Arrhythmia
Altered automaticity
Altered conduction
○ Ectopic atrial conduction
○ AVNRT (Atrioventricular nodal re-entry tachycardia)
○ AVRT (Atrioventricular re-entry tachycardia)
SVT

Cardiac conduction

Ectopic atrial conduction

Group of nerve cells that are not supposed to be activated AV node which leads to an
extra beat and causes an acceleration in heartbeat
See these in paraxosomal tachycardia: suggestive of all of sudden; causing arrhythmic
tachycardia

AVNRT: When our sinus nodes sends a message to AV nodes, some nerve fibers that send
signals to ventricles and others that go back to AV nodes which leads to acceleration/arrhythmia

AVRT: Orthodromic (will stimulate normally coming from SA node to AV node but once it gets
back to the ventricle, it will send a signal back to AV node which is not supposed to happen)
Antidromic (both normal path and also takes an altered different path going directly to
the ventricles and from those, the stimulation from the ventricle goes right up to the AV node)

AVRT-Wolff-Párkinson White (WPW)****************
Has a specific abnormal path that is called Bundle of Can’t
Does not go to AV; goes to ventricles and then goes back AV node and goes to bundle of
Can’t (local re-entry)

Goal of treatment for anti-arrhythmic drugs
Restore normal rhythm, conduction and rate
Effect:
○ Accelerate or reduce velocity of conduction
○ Alter the excitability of cardiac cells
○ Suppress abnormal automaticity
○ They act on the action potential of cardiac myocytes* this is the reason we use
the classified drugs

Antiarrhythmic Drugs Classification
Class I
○ Na+ channel blockers (membrane stabilizing drugs)
○ Drugs that block the rapid inflow of Na+ ions
○ Alters the slope amplitude of depolarization
○ Variable effect on ERP and AP depending on the subclass
○
○ Class 1A:
Quinidine
Isomer of quinine
Effects on myocytes:
○ Membrane stabilizing effect
○ Block potassium channels leading to prolongation of action
potential duration > prolongation of atrial and ventricular
refractory period
○ Depress cardiac contractility
ECG changes:
○ Prolongation of P-R and Q-T interval
can be an issue in some patients like patients w/ …
syndrome
○ Widens QRS complex

○
Used for almost all types of arrhythmias
Common uses: atrial flutter and fibrillation
Can be used for ventricular tachycardia
Maintaining sinus rhythm after direct current cardio version
Adverse effects:
 ○ GIT: anorexia, nausea, vomiting, diarrhea
○ Cardiac:
Episodes of fainting
May terminate spontaneously or lead to fatal
ventricular fibrillation
○ Anticholinergic adverse effects
○ Cinchonism: visual disturbances, tinnitus, HA and
dizziness
○ Hypotension
Drug interactions:
○ Increase concentration of digoxin: displacement from
plasma proteins and inhibitiono of digoxin renal clearance
GIVEN ORALLY- rarely given IV because of toxicity and
hypotension due to alpha-blocking effect
Procainamide
Less toxic on the heart, can be given IV
More effective in ventricular than in atrial arrhythmias
Less depression of contractility
No anticholinergic or alpha-blocking actions
Effective against most atrial and ventricular arrhythmias
Second choice after lidocaine in ventricular arrhythmias after
acute myocardial infarction
Adverse effect:
○ in long term tx: causes reversible lupus erythematosus-like
syndrome in 5-15% of patients
○ Hypotension
○ Torsades de pointes
○ Hallucination and psychosis
○ Class IB
Lidocaine
Treatment of ventricular arrhythmias in emergency (e.g., cardiac
surgery, acute myocardial infarction)
○ Given IV bolus or slow infusion
NOT effective in atrial arrhythmias (only ventricular)
NOT effective orally (3% bioavailability)
Adverse effects
○ Hypotension
○ Like other anesthetic, neurological adverse effects:
Paraesthesia
Tremor
Dysarthria (slurred speech)
Hearing disturbances
Confusion
Convulsions
 Mexiletine
Effective orally
Adverse effects
○ Nausea, vomiting
○ Tremor, drowsiness, diplopia
○ Arrhythmias and hypotension
○ Class IC
Flecainide
Used in supraventricular arrhythmias in patients w/ normal hearts
Wolff-Párkinson-White Syndrome
Very effective in ventricular arrhythmias, but very high risk of
pro-arrhythmia
Should be reserved for resistant arrhythmias
Adverse effects:
○ CNS: dizziness, tremor, blurred vision, abnormal taste
sensations, paraesthesia
○ Arrhythmias
○ Heart failure due to decreased ventricular(e) inotropic
effect
Propafenone
Used bid
Chemical structure similar to propranolol
Has weak beta-blocking action
Causes metallic taste and constipation
Class II
○ Beta-adrenoceptor blocker
○ Pharmacological actions:
Block beta-1 receptors in the heart -> reduce the sympathetic effect on
the heart causing:
Decrease automaticity of SA node and ectopic pacemakers
Prolong refractory period (slow conduction) of the AV node, this
helps prevent re-entry arrhythmias
○ Clinical uses:
Atrial arrhythmias w/ emotion, exercise, and thyrotoxicosis
WPW
Digitalis-induced arrhythmias
(Propranolol or atenolol reduce the incidence of sudden arrhythmic death
after myocardial infarction, because of its ability to prevent ventricular
arrhythmias )
Class III
○ Drugs that prolong action potential duration & refractory period
○ Prolong phase 3
○ Amiodarone
 Main effect is to prolong action Al potential duration and therefore prolong
refractory period (useful in re-entry arrhythmias)
Additional Class 1A, 2, and 4 effects
Vasodilating effects (due to its alpha adrenoreceptor blocking effects and
its calcium channel blocking effects)
Use: serious resistant ventricular arrhytmias, very effective in many types
of arrhythmias
Maintenance of sinus rhythm after D.C. cardio version of atrial flutter and
fibrillation
Resistant supraventricular arrhythmias (e.g. WPW)
Adverse effects
Bradycardia, heart block, heart failure
Pulmonary fibrosis
Hyper- or hypothyroidism
Photodermatitis (in 25%) and skin deposits
May cause bluish discoloration of the skin
Tremor, HA, ataxia, paraesthesia
Constipation
Corneal micro deposits (swirl)
Hepatocellular necrosis
Peripheral neuropathy
○ Ibutilide
Pure class III and are given by a rapid IV infusion
Used for the acute conversion of atrial flutter or atrial fibrillation to normal
sinus rhythm
Causes qt interval prolongation, so it may precipitate torsades de pointes
Class IV
○ Calcium channel blockers
○ Main site of action* is SA and AV nodes (slow conduction and prolong effective
refractory period)
○ Uses
Atrial arrhythmias
Re-entry supraventricular arrhythmias (WPW)
Not effective in ventricular arrhythmias