PM 719 Pharmacology II - Chapter 14 Antiarrhythmics PDF

Summary

These lecture notes cover the topic of antiarrhythmics, including examples, case studies, and the mechanisms of arrhythmias. The content details normal cardiac rhythm and different types of arrhythmias including atrial flutter, atrial fibrillation, etc. Included is a table of antiarrhythmic drugs and their indications.

Full Transcript

PM 719 Pharmacology II

Chapter 14 Antiarrhythmics
RMRocco, PhD

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 Case Study
69 year old female, 1 month history palpitations, shortness
of breath and fatigue.
History of hypertension, ECG shows atrial fibrillation with
ventricular response of 122 bpm.
Echocardiogram shows left ventricular ejection fraction
38%
Rhythm reverts to normal after 7 days of metoprolol, but
she continues to show paroxysms of atrial fibrillation.
What antiarrhythmic drug to maintain normal sinus
rhythm?
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 Case Study
A drug well tolerated in heart failure
(reduced ejection volume) and which has
ability to convert or prevent atrial
fibrillation would be:
amiodarone or
dofetilide (doe FET il ide)

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 Normal Cardiac Rhythm
(1) Sinoatrial (SA) node, electrical impulse
60-100 beats/min frequency.
(2) Impulse spreads through atria and enters
atrioventricular (AV) node.
(3) Impulse propagates through His-Perkinje
fibers into ventricles.
(4) Ventricles contract.

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Chapter 14 Agents Used in Cardiac Arrhythmias

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© The McGraw-Hill Companies, Inc,
 Cardiac Conduction System
(Electrical System)
SA Node in right atrium (“natural pacemaker”)
starts the electrical impulse that leads to
heart beat
SA node produces 60-100 beats
(electrical impulses) per min
AV Node between atria and ventricles (upper and
lower chambers)
AV node is electrical bridge which passes
currents through to ventricles.

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 Cardiac Conduction System
His-Purkinje System
located in ventricles
signal passes through cells to contract
ventricle
His bundle (start of the system)
Right bundle branch
Left bundle branch
Purkinje fibers (end of the system)
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 Conduction
1
2
0
3
4

Phase 0 Rapid depolarization Class I drugs
Phase 1 Early-fast repolarization Class II
Phase 2 Plateau Class IV
Phase 3 Repolarization Class III
Phase IV Resting potential Class II
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 Cardiac Cell
Ion Intracellular
Extracellular
mM mM

Na+ 5 150
K+ 115 5
Ca++ 0.007 7
Cl- low
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110 9
 Action Potential (AP)
0 mV cardiac cell AP depolarization

- 85 mV

OUT K+ Na+ Ca++

IN Na+ Ca++ K+ Na+

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 His-Perkinje Fibers
Jan Evangelista Purkinje (1787-1869)
Born in Czech Republic
1839 discovers fibers that conduct pacemaker stimulus along inside
walls of the ventricles.
Invents the word plasma to describe cell free portion of the blood.
1823 discovered use of fingerprints
First person to use a microtome for tissue sections.
Wilhelm His Jr (1863-1934)
Swiss cardiologist
1893 bundle of nerves discovered.
Discovers that heartbeat has origin in the heart cells.

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 Major Mechanisms of
Arrhythmias
Abnormal automaticity or abnormal (reentrant)
conduction.
Examples of Arrhythmias
atrial flutter
atrial fibrillation
atrioventricular nodal reentry
premature ventricular beats (PVBs)
ventricular tachycardia
ventricular fibrillation
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 Arrhythmia
Arrhythmia = cardiac depolarization that
deviates from normal due to
(a) Abnormal site of impulse origin
(b) Change from normal in rate or regulatory
control
(c) Change in conduction velocity

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 Arrhythmia
Electrical potential in cardiac cell controlled
by ion flux in/out of the cell through pores
or gates. Ions not directly soluble in the cell
wall membrane.
Each cardiac myocyte channel or gate is ion-
specific.

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 Arrhythmia
Cardiac action potential divided into phases
which are determined by the ions that flow
during that phase.

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 Arrhythmia
Movement of ions controlled by Ohm’s Law
Current = voltage (conductance)
Mechanisms of arrhythmias in relation to ion
conduction.
(a) Disturbance in impulse formation
(b) Disturbance in impulse conduction
(c) Both of the above
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Chapter 14 Agents Used in Cardiac Arrhythmias

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© The McGraw-Hill Companies, Inc,
 Terms
torsade de pointes (twisting of the points, from
ballet):
polymorphic ventricular tachycardia
increased QT interval
Drug induced or genetic
Reentry: cycling of electrical impulse through
conductive tissue that has been recently stimulated.
Tachycardia and arrhythmia (originating usually in
AV node).

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Torsade de pointes

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 Drugs Required
The drugs required for this Chapter 14 are
listed in BOLD on pg 2-5 in the Lecture
Notes for Chapter 14 Cardiac Arrhythmias.

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 Table 1. Antiarrhythmic Drugs
Drug Class Drugs Indications
Class 1A quinidine AF, PVCs
procainamide
disopyramide
Class 1B lidocaine PVCs
mexiletin
Class 1C flecainide severe vent arrhythmias
Class 2 esmolol AF, atrial flutter, PVCs
propranolol
Class 3 amiodarone AF, severe vent
sotalol arrhythmias
Class 4 verapamil AF, atrial fibrillation
diltiazem

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 Antiarrhythmic Drugs
General Mechanisms of action:
Block sodium channels
Block sympathetic autonomic effects
Prolongation of refractory period
Block calcium channels

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 Classes of Drugs Used to Treat
Arrhythmias
Class I Sodium channel blockers
Local anesthetics, differ in their
binding affinity to sodium
channels
Ia Prolong action potential duration
(APD), intermediate acting
Ib Shorten effect on APD, bind rapidly
Ic Minimal to no effect on APD,
slow binding
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 Classes of Drugs Used to Treat
Arrhythmias
Class IIBeta Blockers
reduce beta adrenergic activity in
heart
Class III Prolong APD
Block potassium currents
Class IV Block calcium currents

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 Antiarrhythmic Drugs
Most drugs in the four classes have all four
actions but each drug has a dominant
action which is how it is put into a specific
class (I - IV).

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 Antiarrhythmic Drugs
Class Ia procainamide
quinidine
disopyramide
Class Ib lidocaine
mexiletine

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 Antiarrhythmic Drugs
Class Ic flecainide
Class IIBeta Blockers
propranolol
esmolol

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 Antiarrhythmic Drugs
Class III Potassium channel blockers
amiodarone
dofetilide
ibutilide
sotalol

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 Antiarrthymic Drugs
Class IV Calcium Channel Blockers
diltiazem
verapamil

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 Antiarrthymic Drugs
Misc Additional Drugs that do not fall neatly
into the I- IV classification

adenosine
magnesium

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 Mechanisms
All Class I drugs
slow or block conduction
slow or abolish abnormal pacemakers if Na +
channels involved
block Na+ channels in abnormal tissues
more effectively than in normal
tissue
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 Mechanisms
Class IA Drugs
used for both atrial and ventricular
arrhythmias
drugs block Na+ flux and slow
conduction
Class IB Drugs
act mostly on Purkinje and ventricular tissue
reduce action potential (AP) duration
little effect on EKG
phenytoin used to reverse digixon induced
arrhythmias.
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 Mechanisms
Ic Drugs
depress Na+ currents but no effect on
ventricular AP duration or
QT interval
drugs cause increase in QRS duration
on EKG

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 Class Ia Drugs
Class Ia Drugs used for all types of arrhythmias
Procainamide hypotension and lupus
erythematous (L. wolf) joint inflammation, pain,
fever, skin rash, pleurisy. Fast and slow acetylators
(NAPA metabolite) 1/3 of all patients.
Quinidine may cause cinchonism (headache,
vertigo, tinnitus) Digoxin displaced from receptor
by quinidine and Cp of digoxin rises to lethal levels
(digoxin TI 1.2 - 2.0 ng/mL)
All Class Ia drugs may cause arrhythmias.
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Quinidine
Quinidine
Class Ia sodium channel
blocker
QRS duration in EKG is
prolonged
Major cardiac effects:
QT interval prolongation,
induction of Torsade de
Pointes arrhythmia and
syncope.
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Quinidine
Extraction of quinine from
cinchona bark was costly
and time consuming. Drug
had a high price.
In 1865 more easily
extracted drugs from
cinchona bark were tested
for antimalarial effects:
quinidine discovered.

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Quinidine Ad 1961

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 Class Ib Drugs
Used in acute ventricular arrhythmias
caused by ischemia following MI.
(lidocaine iv only, high first pass effect, 95
% of po dose lost to first pass, acts
exclusively at sodium channels)
All Class Ib may cause arrhythmias

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 Class Ic Drugs
Used for both atrial and ventricular
arrhythmias
All Class Ic cause greater mortality
compared to placebo but used when all
other antiarrhythmics fail.

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 Class II Drugs
Beta blockers reduce sodium and calcium
currents and suppress abnormal pacemakers
Esmolol used iv only for acute arrhythmias
Propranolol, metoprolol and timolol used
as prophylactic drug treatment in patients
following MI.

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 Class III Drugs
Hallmark of this class is prolongation of the
AP duration. Block of potassium channels =
repolarization of the AP. On EKG the QT
interval is increased.
Clinical uses include post MI arrhythmias
and recurrent ventricular fibrillation.
Sotalol may precipitate torsade de pointes
arrhythmia.

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 Amiodarone
A special case
used in most arrhythmias, broad
spectrum
drug blocks sodium, potassium and
calcium channels
drug blocks beta receptors
High toxicity, used when all others fail
deposits in cornea and skin
causes thyroid dysfunction

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 Class IV Drugs
Used for arrhythmias that traverse calcium
dependent cardiac tissues (ex AV node)
Used to convert AV nodal reentry (called
nodal tachycardia) to normal sinus rhythm
Most important toxicity (verapamil),
constipation, nausea, flushing, dizziness.
May cause heart failure.

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Adenosine
Adenosine (endogenous)
but also used in high doses
( 6- 12 mg) iv with t1/2 of
15 seconds.
Drug slows or blocks
conduction in AV node
and blocks AV nodal
arrhythmias.
Both potassium and
calcium channels blocked.

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 Principles in the Clinical Use of
Antiarrhythmic Agents
Eliminate the cause: electrolyte disturbances,
drugs etc
Make a firm diagnosis: arrhythmia must be
confirmed before the start of therapy
Determine the baseline condition: few
antiarrhythmic drugs are safe in patients with CHF
and other underlining cardiac disease.
Question the need for therapy: not all arrhythmia
requires drug treatment.

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