Mechanism of arrhythmogenesis

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Mechanism of arrhythmogenesis

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Title: Mechanism of arrhythmogenesis

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Mechanism of arrhythmogenesis

Abnormal automaticity
Triggered activity and afterdepolarization
Reentrant mechanism

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Automaticity Alterations in impulse
initiation
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Abnormal Automaticity

Causes
Parasympathetic nervous system activation slows
the rate of rise of phase 4 depolarization and
vice versa
Ischemia, infarction, hypokalemia, beta agonists
enhance phase 4 depolarization
Significance
Atrial tachycardia, accelerated idioventricular
rhythms, ventricular tachycardia

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Afterdepolarizations and Triggered activity
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Afterdepolarizations and Triggered activity

EAD (Early AD)
Due to increase in cytosolic Ca2
Causes - hypokalemia, hypomagnesemia, hypoxia,
acidosis, bradycardia, class IA and III
antiarrhythmics, antihistaminics, phenothiazines
Significance - torsades de pointes
DAD (Delayed AD)
Due to increased Ca2
Causes- catecholamines, quinidine, caffiene
Significance - idioventricular rhythms, digitalis
toxicity

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Reentrant Mechanism
?
?
?
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Reentrant arrhythmias

Circulation of an activation wave around an
inexcitable obstacle
Most common arrhythmia mechanism
Property of a network of myocytes
Presence of excitable gap
In the absence of excitable gap wavefront
propagates through partially refractory tissue
with no anatomic obstacle- leading to circle
re-entry( functional re entry)

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Classification of arrhythmias

By heart rate
Bradyarrhythmias
Tachyarrhythmias
Conduction blocks
By anatomic origin
Supraventricular
Junctional
Ventricular
By type of disorder
Disorders of impulse formation
Disorders of impulse conduction

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Disorders of impulse formation

Sinus rhythms
Sinus bradycardia
Sinus tachycardia
Sinus arrhythmia
Atrial rhythms
Premature atrial complexes
Atrial flutter
Atrial fibrillation
PSVT
Junctional rhythms
Ventricular rhythms
Ventricular premature beats
Ventricular tachycardia
Ventricular fibrillation

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Disorders of impulse conduction

Conduction blocks
Sino atrial blocks
Atrioventricular blocks
First degree AV block
Mobitz type I block
Mobitz type II block
Third degree AV block
Intraventricular blocks
Hemiblocks
LBBB
RBBB

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Sinus Bradycardia
Heart rate lt50 bpm with chronic ßblocker
therapy
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Sinus Bradycardia (contd.)

Causes Vagal stimulation, increased intracranial
pressure, hyperkalemia, digoxin, beta blocker,
hypothyroidism, sedation, obstructive jaundice,
glaucoma.
Normal phenomenon in athletes and during sleep

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Sinus Bradycardia Management

Atropine
First drug of choice for symptomatic bradycardia
Dose - 0.5 mg IV bolus repeated every 3-5 min up
to a total dose of 0.04 mg/kg or 3mg
Other drugs
Dopamine 2-10 µg/kg/min infusion
Epinephrine 2-10 µg/min infusion
Ephedrine 5-25 mg IV bolus
Isoproterenol 2-10 µg/min infusion
Transcutaneous/transvenous pacing
Symptomatic bradycardia with signs of poor
perfusion

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SinusTachycardia
QRS complex- normal May be associated with ST
segment depression
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Sinus Tachycardia (contd.)

Causes
Pain, inadequate anaesthesia, hypovolemia, fever,
hypoxia, hypercapnia, cardiac failure, anaemia,
thyrotoxicosis, drug effects
Significance
Prolonged tachycardia increased myocardial
work, decreased myocardial O2 supply ?can ppt MI
or CHF in patients with heart disease
Treatment
Treat the underlying cause
Beta blockers and calcium channel blockers

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Sinus Arrhythmia

Alternate periods of slower and faster rates
Rate increases with inspiration and decreases
with expiration
Common in children and young adults
Accentuated by vagotonic procedures and
abolished by vagolytic procedures
No treatment required

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Atrial Premature Complexes

Rhythm- irregular with incomplete compensatory
pause QRS complex- usually normal unless
ventricular aberration present
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Atrial Premature Complexes

PACs are of 3 types
Premature P wave with normal QRS
Ectopic focus with different morphology from
sinus P wave
Premature P wave with no QRS
P waves occur very early
AV node in refractory period
Premature P wave with aberrant ventricular
conduction
Impulse reaches the bundle branch when only
one has fully recovered

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Atrial Premature Complexes

Increased incidence with age
More common in patients with chronic rheumatic
valvular disease, coronary artery disease, CHF,
hyperthyroidism
Little clinical significance
Frequent APCs may trigger more serious
supraventriculr arrhythmias e.g. atrial
fibrillation, flutter, PSVT
Treatment rarely necessary

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Atrial Flutter

Heart rate - atrial rate 250 to 350 bpm,
ventricular rate 150 bpm
Rhythm - atrial rhythm regular
P wave- saw toothed appearance (F waves),
F waves best seen in leads II, V1 and
oesophageal leads
P/QRS- usually 21 (may vary between 21 and
81)
QRS complex- normal, T waves - lost in f waves

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Atrial Flutter (contd.)

Mechanism
Re entrant atrial activity (most common)
Focal discharge
Significance
Can be seen in patients with CAD, mitral
valve disease, pulmonary embolism,
hyperthyroidism, cardiac trauma, cancer of heart,
myocarditis

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Atrial Flutter - Management

Initial treatment - Control of ventricular
response rate
ß-blockers - esmolol 1 mg/kg
Calcium channel blockers - verapamil 5-10 mg or
diltiazem
Excessively rapid ventricular response/
haemodynamic instability/ both
DC cardioversion starting at 100J and increasing
to 360J
Ibutilide 1 mg in 10 ml saline/5 D over 10 min
4-8 hrs monitoring after treatment
Procainamide 5-10 mg/kg, no faster than 0.5
mg/kg/min
Amiodarone 150 mg over 10 min ? 1 mg/min for 6
h ? 0.5 mg/min for 18 hrs

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Atrial Fibrillation

Heart rate- atrial rate 350 to 500 bpm.
Ventricular rate 60 to 170 bpm
Rhythm - irregularly irregular
P wave - absent, f waves or no obvious atrial
activity
P/QRS- no p waves
QRS complex- normal

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Atrial Fibrillation (contd.)

Most common postoperative arrhythmia with
significant consequences on patients health
Associated with old age, thyrotoxicosis, HTN,
CAD, CHF, RHD, congenital heart disease
Best seen in leads V1-2 and inferior leads
Caused by numerous wavefronts of depolarization
spreading throughout the atria simultaneously
leading to absence of coordinated atrial
contraction

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Atrial Fibrillation (contd.)

Hemodynamic effects
Loss of mechanical AV synchrony? impairs
ventricular filling? decreases cardiac output
Thromboembolism
After 24-48 hrs
Atrial thrombi usually arising from left atrial
appendage
Increased incidence of stroke(most feared
consequence)

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Atrial Fibrillation (contd.)

Risk Factors for development of thromboembolism

Mild risk factors Moderate risk factors High risk factors
Female gender gt75 yrs Previous stroke, TIA
65-75 yrs Hypertension, DM Prosthetic valves
CAD CHF Mitral stenosis
thyrotoxicosis EFlt35 Previous embolism
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Atrial Fibrillation Management

Control of ventricular rate

Phases Recommended therapy
Acute phase iv diltiazem, metoprolol, esmolol, verapamil
Chronic phase Oral beta blockers digoxin Catheter ablation
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Atrial Fibrillation Management

Antithrombotic therapy

Risk factors Recommended therapy
No risk factor Aspirin, 81325 mg daily
1 moderate risk factor Aspirin, 81325 mg daily, or warfarin (INR 2.03.0)
gt1 mod risk factor/any high risk factor Warfarin (INR 2.03.0)
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Atrial Fibrillation Management

Cardioversion

DC approach DC approach DC approach Antiarrhythmic agents Antiarrhythmic agents
lt48 hrs gt48 hrs gt48 hrs 1week Long duration
DC without prior anti- coagulation Oral warfarin(INR 2-3)f/b cardioversion f/b continous warfarin therapy TEE and heparin f/b cardioversion f/b oral warfarin oral flecainide, dofetilide, propafenone, iv ibutilide dofetilide
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Atrial Fibrillation Management

Post operative atrial fibrillation
Routine use of beta blockers throughout the
periop period
Anticoagulation
Maintenance of sinus rhythm
In the absence of structural heart disease-
flecainide, propafenone
In the presence of significant structural heart
disease- sotalol, amiodarone

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Paroxysmal Supraventricular Tachycardia
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Paroxysmal Supraventricular Tachycardia

Rapid regular rhythm with narrow QRS complex and
lacking the normal p wave
ECG characteristics
Rate 130-270/min
Rhythm regular
P/QRS 1 1 (p wave may be hidden in QRS complex
or T wave)
QRS complex generally normal

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PSVT - Significance

Seen in 5 normal young adults
Accounts for 2.5 of arrhythmias in anaesthetized
patients
Not a/w intrinsic heart disease or systemic
illness
Precipitated under anaesthesia by changes in
autonomic nervous system tone, drug effects,
intravascular volume shifts
Can produce severe hemodynamic deterioration

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PSVT Management

Vagal maneouvres applied only to one side
DOC-iv Adenosine 6mg rapid bolus, 2nd 3rd doses
of 12 and 18 mg if no response
Verapamil 2.5-10 mg iv - terminates AVNRT
successfully, provides long term relief
Amiodarone 150 mg infusion over 10 min - recent
addition
Esmolol 1 mg/kg bolus ? 50-200 mg/kg/min
Phenylephrine 100 µg- if associated hypotension

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PSVT Management (Contd.)

Edrophonium or neostigmine iv
Intravenous digitalization ouabain 0.25-0.5 mg
iv or digoxin 0.5 -1.0 mg iv
Rapid overdrive pacing
Synchronized cardioversion
Electrode catheter ablation with radiofrequency
energy

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Junctional Rhythm

AV node and sites above and below it act as
pacemaker
Heart rate- variable, 40 to 180 bpm
Rhythm- regular
P/QRS- 11
QRS complex- usually normal

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Junctional Rhythm (contd.)

Types
High nodal rhythm- impulse reaches atrium before
ventricles, P precedes QRS, short PR interval
Mid nodal rhythm- impulse reaches atrium and
ventricle at the same time, P lost in QRS
Low nodal rhythm- impulse reaches ventricles
before atrium, P follows QRS
Common in patients under anaesthesia(20)
especially with halogenated anaesthetic agents

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Junctional Rhythm (contd.)

Treatment
Usually reverts spontaneously, no treatment
required
If associated with hypotension poor perfusion
t/t with atropine/ ephedrine/ isoproterenol
Dual chamber electrical pacing

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Ventricular Premature Beats

VPB s arise from ectopic pacemaker activity
arising in the ventricles
Heart rate variable, Rhythm irregular,
Compensatory pause seen
P/QRS- no P wave associated with VPB
QRS complex- Wide, bizarre, gt0.12 s
QRS and T wave point in opposite direction

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VPB - Types

Early in the cycle - R on T phenomenon,
dangerous in acute ischaemic situation because
ventricles are prone to VT and VF
After T wave
Late in the cycle fusing with next QRS - fusion
beats

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VPB (contd.)

Unifocal, multifocal
Causes hypoxia, electrolyte imbalance, blood gas
abnormality, digitalis toxicity, CHF, MI
Common during anaesthesia(15) especially in
patients with pre existing cardiac disease

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VPB - Significance

May progress to VT or VF in following situations
Coronary artery insufficiency, MI
Digitalis toxicity with hypokalemia
Hypoxemia
Multiple, multifocal or bigeminal VPB
R on T phenomenon

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VPB Management

Maintain adequate depth of anaesthesia
Oxygenation and ventilation are the initial
treatment for all kinds of ectopics
Correct underlying abnormalities
Treat if hemodynamic impairment or harbinger of
worse arrhythmias
Lidocaine(TOC) 1.5 mg/kg initial bolus f/b
infusion_at_1-4 mg/min
Other drugs beta blockers, procainamide ,
calcium channel blockers, atropine, disopyramide,
quinidine

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Ventricular Tachycardia

Definition
3 or more VPB s in a row
Types(depending on morphology)
Monomorphic- all QRS complexes have same
morphology
Polymorphic- more than 1 morphology
Torsades de pointes Polymorphic VT with long
QTc
Types(depending on duration)
Non sustained- upto 30s
Sustained- gt30s

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Ventricular Tachycardia

Heart rate -100 to 200 bpm
P/QRS- no fixed relationship due to AV
dissociation
QRS complex- wide and bizarre, gt0.12 s, similar
to VPB

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Ventricular Tachycardia (contd.)

Causes MI, hypoxia, electrolyte imbalance,
myocardial trauma, digitalis toxicity
Mechanism usually caused by re entry and most
commonly seen in patients following MI
Complications decreases cardiac output,
decreases cardiac perfusion, increases cardiac
workload, can deteriorate into VF

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VT Management

Acute onset is life threatening and requires
immediate treatment
Treat the precipitating metabolic or toxic causes

Monomorphic VT Monomorphic VT Polymorphic VT Polymorphic VT
Hemodynamically stable Hemodynamically unstable Normal QT Prolonged QT
iv amiodarone 150 mg in 100ml NS over 10min f/b infusion iv procainamide 20mg/min iv lidocaine 1 mg/kg cardioversion iv amiodarone 150 mg slow cardioversion iv infusion of 1g magnesium over 2-3 min
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Torsades de pointes
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Ventricular Fibrillation

An irregular rhythm that results from rapid
discharge of impulses from one or more
ventricular foci or from multiple wandering
reentrant circuits in the ventricle
Ventricular contractions erratic, bizarre
patterns of various sizes and configurations
Causes MI, hypoxia, hypothermia, electrolyte
imbalance, electric shock, drugs
Significance No effective CO, life must be
sustained by artificial means

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Ventricular Fibrillation
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VF - Treatment

CPR immediately and then asynchronous external
defibrillation
Manual biphasic device specific 120-200 J
Monophasic 360 J
AED device specific
Epinephrine 1 mg IV every 3 to 5 min or
Vasopressin 40U iv bolus
Consider amiodarone, lidocaine, magnesium sulfate

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Conduction Blocks

Chronic, represent underlying disease state of
myocardium or conduction system
Types
Sinoatrial block
AV block
Incomplete- 1and 2
Complete- 3
IV conduction block

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Sino atrial block

Sinus impulse is blocked within the SA junction
No atrial or ventricular activation
No P wave or QRS complex recorded

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Sino atrial block - Significance

SA block rare, found in same conditions as marked
sinus bradycardia or sinus arrhythmia
Young vagotonic individuals, particularly
athletes
Digitalis administration
Uraemia
Hypokalemia
May be an expression of Sick Sinus Syndrome

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First degree AV block

PR interval gt0.20 sec all P waves conduct to
the ventricles
Healthy individuals, CAD, digitalis
administration, acute rheumatic carditis, beta
blockers
Requires no treatment

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Mobitz Type I / Wenkebach Block

Progressive lengthening of PR interval till an
impulse is not conducted and the beat is dropped
Relatively benign and often reversible
Pacemaker not required
Causes MI, digitalis toxicity
Reflects disease of AV node

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Mobitz Type II Block

Dropped beats occur without progressive
lengthening of PR interval
Less common, more serious
Disease of His bundle or purkinje fibres
Serious prognosis, frequently progresses to
complete block
Treatment pacemaker insertion

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Third Degree AV Block

AV dissociation
QRS complex may be normal or widened
HR usually too slow to maintain adequate CO
Treatment- transvenous endocardial or epicardial
pacemaker(dual chamber)

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Left anterior fascicular block

Delayed activation of antero-superior division
of left bundle
Left axis deviation in frontal plane, usually
-45 to -90 degrees
Deep S waves in leads II, III, aVF
tall R wave in aVL
QRS duration usually lt0.12s unless coexisting
RBBB

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Left anterior fascicular block-Causes

MI
Fibrosis due to chronic coronary insufficiency,
chronic cardiac failure
Fibrosis in chronic cardiomyopathy
Left ventricular hypertrophy
Calcareous encroachment on left bundle branch
from aortic valve or interventricular septum

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Left posterior fascicular block

Right axis deviation
Prominent S waves in leads I, aVL
Tall R waves in leads II, III, aVF
Secondary changes in T wave
QRS duration normal

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Left Bundle Branch Block

Prolonged QRS duration gt 120 msec
ST-T abnormalities
Broad notched, M shaped R waves in left sided
leads I, aVL, V5, V6, no initial q waves
Wide and notched QS in right sided leads
QRS axis - variable

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LBBB - significance

Ominous prognostic sign
Reflects severity of underlying cardiac disease
Obscures or simulates other patterns on ECG
Makes diagnosis of LVH, acute ischaemia or MI
difficult or impossible

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Right Bundle Branch Block

Prominent notched R waves on right sided leads
Wide S waves on left sided leads
QRS prolongation gt120msec
ST-T waves discordant with QRS complex

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RBBB (contd.)

Incomplete RBBB
Diminution of S wave in lead V2
Slurring of upstroke of S wave in V2
Small r deflection in V2
Increased R amplitude in V2
QRS complex lt 0.11 s

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RBBB - Significance

Common in general healthy population no
prognostic significance in this group
In patients with organic heart disease, new onset
of RBBB predicts higher rate of CAD, CHF and
mortality

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Arrhythmia Management
Sinus arrhythmia No treatment required
Sinus bradycardia Atropine dopamine, epinephrine
Sinus tachycardia ß-blockers, CCB
Atrial premature beats Treatment rarely necessary
Atrial flutter Rate control, Cardioversion
Atrial fibrillation Rate control, cardioversion, antithrombotic
PSVT Carotid sinus massage, adenosine, ß-blocker
Junctional bradycardia Junctional tachycardia Atropine ß-blocker, CCB
Ventricular premature beats Lignocaine
Ventricular tachycardia Amiodarone, lignocaine, cardioversion
Ventricular fibrillation Defibrillation CPR
Torsades de pointes Magnesium
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Cardioversion

DC discharge synchronized with peak of R wave in
QRS complex
Indications
Wide or narrow QRS complex tachycardia in
unstable patients
Stable VT not responding to iv medications
Hemodynamically unstable AF, Atrial flutter, SVT

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Cardioversion (contd.)

Advantage
Avoids delivery of a shock during cardiac
repolarization thus avoiding precipitation of VF
Energy requirements
AF- 100 to 200J monophasic initially?360J or
75J of biphasic
Atrial flutter and PSVT- 50J initially?100J
VT- 50J initially?200J

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Cardioversion (contd.)

Successful cardioversion depends on
Adequately anaesthetized
Shock must be synchronized with the QRS complex
Conductive pre gelled pads to be used

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Antiarrhythmic agents
Class Action Drugs Clinical uses
Ia Na channel block (intermediate association/dissociation) Quinidine, procainamidedisopyramide Ventricular arrhythmias, prevention of paroxysmal recurrent atrial fibrillation, procainamide in WPW syndrome
Ib Na channel block (fast association/dissociation) Lidocaine, phenytoin, mexiletine Ventricular tachycardia, atrial fibrillation
Ic Na channel block (slow association/dissociation) Flecainide, propafenone, moricizine Prevention of paroxysmal atrial fibrillation, recurrent tachyarrhythmias
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Antiarrhythmic agents(contd.)
Class Action Drugs Clinical uses
II Beta blockers Propanolol, esmolol, metoprolol, atenolol Decreases MI mortality, pevent recurrence of tachyarrhythmias
III Potassium channel blockers Amiodarone, sotalol, ibutilide, dofetilide WPW syndrome, atrial fibrillation and ventricular tachycardia(sotalol), atrial flutter(ibutilide)
IV Calcium channel blockers Verapamil, diltiazem Prevent recurrence of PSVT, reduce ventricular rates in AF
Other drugs Enhances vagal activity Digoxin, Atrial fibrillation, AVNRT
Other drugs Prolonged hyperpol. adenosine PSVT
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Adverse effects
Drugs Adverse effects
Quinidine QT prolongation, Torsades de pointes, cinchonism
procainamide QT prolongation, Torsades, hypotension, LE like picture
disopyramide Urinary retention, dry mouth, constipation
lidocaine Neurologic(mc), proarrhythmic
mexiletine neurologic
flecainide proarrhythmic
moricizine Dizziness, nausea
propafenone Metallic taste
Drugs Adverse effects
Propanolol, esmolol, atenolol, metoprolol Worsening of angina, bronchoconstriction, sudden cardiac death
amiodarone Bradycardia, heart blocks, Pulmonary fibrosis, thyroid dysfunction, corneal deposits, photodermatitis, hepatitis
Dofetilide, ibutilide Prolonged QTc
Verapamil AV block, VF, peripheral edema
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References