1. Anti arrhythmic Drugs
Marwa A. Khairy , MD

2. TOPICS COVERED Electrophysiology of the heart
Arrhythmia: definition, mechanisms, types
Drugs :class I, II, III, IV
Guide to treat some types of arrhythmia

3. Electrophysiology of the heart

4. This is the normal pathway for electricity to travel through the heart

5. This is the normal pathway for electricity to travel through the heart

6. This is the normal pathway for electricity to travel through the heart

7. This is the normal pathway for electricity to travel through the heart

8. Cardiac Action Potential
Resting membrane potential
Retention of many intracellular anions.
The resting cell membrane is almost 100 times more permeable to potassium than to sodium,
Na+K+ATPase pump.
Potential inside the cardiac cell is -90 mV relative to outside.
Action potentials depolarize the cell and overshoot to +20 mV
Fast response predominant in the atria and ventricle
Slow response found in the SA and AV nodes
The phases of the action potential are associated with changes in the permeability of the cell membrane to Na, K, and Ca. Permeability is controlled by ion channels.
Ionic basis of the resting potential
The resting cell membrane is relatively permeable to K via the inwardly rectifying K current.
The diffusion gradient of K outward is balanced by impermeable anions that create an electrostatic force.
The Nerst equation for K predicts a Ek of -94 which is slightly more negative than the resting potential due to slow Na leak
If left, the leak would eventually depolarize the cell so the K/Na/ATPase acts to get rid of Na.
The RMP is the electrical potential across the cell membrane during diastole and is about −90 mV, the intracellular membrane surface being negative with respect to the extracellular surface. RMP is maintained by the permeability properties of the cell membrane, which retains negative ions in the cell but allows positive ions to diffuse out. The cell membrane is impermeable to negatively charged ions such as proteins, sulphates and phosphates, which, therefore, remain intracellularly. In contrast, membrane permeability to potassium is higher, allowing it to diffuse out of the cell under its concentration gradient of about 30 : 1.
Potassium diffuses out of the cell until an equilibrium is reached at which the electrostatic attraction of the retained anions balances the chemical force moving the potassium down its concentration gradient out of the cell.
- 90mV
Non-Pacemaker potential

9. Cardiac Action Potential
Phase 0: fast upstroke
Due to Na+ influx
+ 20 mV
N.B. The slope of phase 0 = conduction velocity
Also the peak of phase 0 = Vmax Na Na
Genesis of the upstroke (Phase 0)
Anything that raises the resting potential beyond threshold (-65 mV) will cause an action potential.
Phase 0 due to Na inward.
m gates open in Na channels as Vm becomes less negative.
Na flows in due to the electric gradient until Vm = 0 then concentration gradient takes over.
h gates close the channel due to the rising Vm
h gates remain closed until partially repolarization (effective refractory period).
Further, the speed at which one cell is depolarized (represented by the slope of phase 0) determines how quickly the next cell is
stimulated to depolarize, and thus determines the speed at which the electrical impulse is propagated. If something causes the slope of phase 0 to change, the conduction velocity also changes; the faster the depolarization of the cardiac cells, the faster an electrical impulse moves across the heart Na
- 90 mV
Non-Pacemaker potential

10. Depolarization tissue
Resting Ready
Open, Active M h M h
Open
Closed
threshold
Gate Opens
Open
Slowly Closed
Depolarization tissue
Na/K/ATPase pump active
3 Na out/2 K in helps repolarization
-50 mv M gate closes
-85 mv h gate opens
Inactive refractory M h
Open
Repolarization
Closed

11. Depolarization tissue
Class IA
Resting Ready
Open, Active X X M h M h
Class IC
Open
Closed
threshold
Gate Opens
Open
Slowly Closed
Na channels Blockers
Depolarization tissue
Na/K/ATPase pump active
3 Na out/2 K in helps repolarization
-50 mv M gate closes
-85 mv h gate opens
Class IB X
Inactive refractory M h
Open
Repolarization
Closed

12. Cardiac Action Potential
+ 20 mV
Phase 1: partial repolarization
Due to rapid efflux of K+
Genesis of early repolarization (Phase 1)
Transient outward current of K causes a brief efflux of K because the interior is positive relative to exterior.
- 90 mV
Non-Pacemaker potential

13. Cardiac Action Potential
+ 20 mV
Phase 2: plateau
Due to Ca++ influx
Genesis of the plateau (Phase 2)
Two types of Ca channels; L and T type.
L-type are long lasting and open when Vm -10 mV and enhanced by cAMP
T-type are transient and open when Vm -70 mV but inactivate quickly.
The positive Vm favours the efflux of K but K current drops which prevents excessive loss of K and loss of the plateau
Ca and some Na enters through slower activating and inactivating channels.
Ca channels are voltage regulated and activated as Vm becomes less negative.
- 90 mV
Non-Pacemaker potential

14. Cardiac Action Potential
+ 20 mV
Phase 3: repolarization
Due to K+ efflux
Genesis of final repolarization (Phase 3)
Repolarization occurs when K efflux exceeds influx of Ca.
Three K channels with different physiochemical properties are responsible for repolarization.
- 90 mV
Non-Pacemaker potential

15. Phase 4: Resting Membrane Potential
Cardiac Action Potential
Phase 4: Resting Membrane Potential
+ 20 mV
Restoration of ionic concentrations
Ca is pumped out by a Na/Ca exchanger and Na is ejected by the Na/K/ATPase pump.
Small component of Ca/ATPase.
Fortunately, the essential features of repolarization are relatively simple: (1) repolarization returns the cardiac action potential to the
resting transmembrane potential; (2) this process takes time; (3) this time, roughly corresponding to the width of the action potential, is the refractory period of cardiac tissue; (4) depolarization mainly depends on sodium channels, and repolarizationmainly depends on potassium channels
- 90 mV
Non-Pacemaker potential

16. Cardiac Action Potential
Phase 4: pacemaker potential
Na influx and K efflux and Ca influx until the cell reaches threshold and then turns into phase 0
Pacemaker cells (automatic cells) have unstable membrane potential so they can generate AP spontaneously
- 40 mV
- 60 mV
Pacemaker potential

17. Cardiac Action Potential
Phase 0:
upstroke:
Due to Ca++ influx
- 40 mV
Depolarization due to calcium NOT sodium!
- 60 mV
Pacemaker potential

18. Cardiac Action Potential
Phase 3: repolarization
Due to K+ efflux
- 40 mV
- 60 mV
Pacemaker potential

19. And less leaky to potassium
Cardiac Action Potential
K+ Channels
Open more
Slow Ca++
Channels Open
- 40 mV
Na+ Leak
And less leaky to potassium
- 60 mV
Pacemaker potential

20. Sympathetic and Parasympathetic
Sympathetic – speeds heart rate by  Ca++ & I-f channel flow
Parasympathetic – slows rate by  K+ efflux &  Ca++ influx

21. Cardiac Action Potential

22. Mechanism of Cardiac Contractile Cell Muscle Excitation, Contraction & Relaxation

23. Cardiac Action Potential
It is also called absolute refractory period (ARP) :
In this period the cell can’t be excited
Takes place between phase 0 and 3
Cardiac action potentials have long refractory periods (RP). No stimulus can produce another action potential during the effective refractory period.

24. Transmembrane action potential occurring in an automatic cardiac cell and the relationship of this action potential to events depicted on the electrocardiogram (ECG).

25. Arrhythmia: Definition, Mechanisms, Types

26. Arrhythemia
Arrhythmia /dysrhythmia: abnormality in the site of origin of impulse, rate, or conduction
If the arrhythmia arises from atria, SA node, or AV node it is called supraventricular arrhythmia
If the arrhythmia arises from the ventricles it is called ventricular arrhythmia

27. Factors Precipitating Cardiac Arrhythmias
1. Ischemia
pH & electrolyte abnormalities
80% – 90% asstd with MI
2. Excessive myocardial fiber stretch/ scarred/ diseased cardiac tissue
3. Excessive discharge or sensitivity to autonomic transmitters
4. Excessive exposure to foreign chemicals & toxic substances
20% - 50% asstd with General Anesthesia
10% - 20% asstd with Digitalis toxicity

28. Mechanisms of Arrhythmogenesis
Abnormal heart pulse formation
Sinus pulse
Ectopic pulse
Triggered activity
Abnormal heart pulse conduction
Reentry
Conduct block
Abnormal Automaticity
Non-pacemaker cells begin to spontaneously and initiate an impulse.
Reduced RMP bringing it closer to the threshold potential.
Ischemia and electrolyte imbalances

29. Mechanisms of Arrhythmogenesis
Triggered activity
Early afterdepolarizations associated with QT prolongation (torsades de pointes)
Delayed afterdepolarizations associated with Ca2+ overload (e.g. digoxin)
Spontaneous depolarizations requiring a preceding impulse (a triggering beat) are called
afterdepolarizations (or triggered activity). If afterdepolarizations originate during
phase 2 or 3 of the monophasic action potential (MAP) they are classified as early
afterdepolarizations (EAD) (Fig 2). Afterdepolarizations originating from phase 4 of
the MAP are classified as delayed afterdepolarization (DAD) (Fig 3). An example of
early afterdepolarization (EAD) is drug induced torsade de pointe, a polymorphic form
of ventricular tachycardia that is a potentially lethal complication of anti arrhythmic and
other drugs that prolong the QT-interval.
The extrusion of potassium from myocardial
cells allows the cell’s membrane potential to go back to its resting potential. This process
is called repolarization, and is carried via a potassium channel (IK channel). The process
involves bringing the transmembrane potential back to its resting value. The less negative
the trans membrane potential, the less sodium channels are available to depolarize the cell
making it refractory to any received impulse (unexcitable). The extrusion of potassium
determines the duration of the action potential, the cell’s refractory period and the length
of the QT interval (the electrocardiographic equivalent of repolarization). Drugs that
block this channel such as quinidine, procainamide, sotalol and dofetilide can result in
torsade de pointe. Ventricular arrhythmias secondary to digoxin toxicity is an example of
delayed afterdepolarization. Digoxin mediated increased intracellular Ca++ is believed to
be the mechanism of this type of arrhythmia.

30. The “Re-Entry” Mechanism of Ectopic Beats & Rhythms
Most common mechanism
Requires two separate paths of conduction
Requires an area of slow conduction
Requires unidirectional block

31. Re-entry Circuits as Ectopic Foci and Arrhythmia Generators
Atrio-Ventricular Nodal Re-entry
supraventricular tachycardia
Ventricular Re-entry
ventricular tachycardia
Atrial Re-entry
atrial tachycardia
atrial fibrillation
atrial flutter
Atrio-Ventricular Re-entry
Wolf Parkinson White
supraventricular tachycardia

32. Antiarrhythmic
drugs

33. Pharmacologic Rationale & Goals
The ultimate goal of antiarrhythmic drug therapy:
Restore normal sinus rhythm and conduction
Prevent more serious and possibly lethal arrhythmias from occurring.
Antiarrhythmic drugs are used to:
Suppressing automaticity in pacemaker
Prolonging the effective refractory period
Facilitating impulse conduction along normal conduction pathways
Suppressing automaticity in pacemaker cells by decreasing the slope of phase 4 depolarization,
Prolonging the effective refractory period to eliminate reentry circuits
Facilitating impulse conduction along normal conduction pathways to prevent conduction over a reentrant pathway.

34. Classification of Antiarrhythmic Drugs
Class I: Sodium channel blockers (membrane-stabilizing agents) 1 a: Block Na+ channel and prolong action potential 1 b: Block Na+ channel and shorten action potential 1 c: Block Na + channel with no effect on action potential Class II: β- blockers Class III: Potassium channel blockers (main effect is to prolong the action potential) Class IV: Slow (L-type) calcium channel blockers
Class I -membrane- stabilising agents (sodium channel blockers) ( a ) Block Na + channel and prolong action potential Quinidine , disopyramide , procainamide ( b ) Block Na + channel and shorten action potential Lidocaine , mexiletine ( c ) Block Na + channel with no effect on action potential Flecanide , propafenone Class II - β- adrenoceptor antagonists ( β- blockers) Atenolol , bisoprolol , metoprolol , I- sotalol Class III -drugs whose main effect is to prolong the action potential Amiodarone , d- sotalol Class IV -slow calcium channel blockers Verapamil , diltiazem

35. duration, amplitude of AP,
CLASS IA
Procainamide,
Quinidine,
Disopyramide
Block Na channels
Intermediate (< 5 s) binding
Kinetics
prolong AP
duration, amplitude of AP,
As you can see here, it blunts the upstroke and prolongs phase 2
Slowing of the rate of rise in phase 0  ↓conduction velocity
↓of Vmax of the cardiac action potential
They prolong muscle action potential & ventricular (ERP)
They ↓ the slope of Phase 4 spontaneous depolarization (SA node)  decrease enhanced normal automaticity
Vmax
They make the slope more horizontal

36. Fast onset/offset binding
CLASS IB
Lidocaine
Mexiletine
Phenytoin
Tocainide
Block Na channels
Fast onset/offset binding
kinetics (< 500 ms)
shortened AP duration,
The IB drugs blunt the upstroke slightly because it is a weak sodium channel blocker, but it also has action at potassium channels which Is why it shortens the action potential durationThey shorten Phase 3 repolarization
↓ the duration of the cardiac action potential
They suppress arrhythmias caused by abnormal automaticity
They show rapid association & dissociation (weak effect) with Na+ channels with appreciable degree of use-dependence
No effect on conduction velocity
no change Vmax

37. but minimal prolongation
CLASS IC
Flecainide,
Propafenone,
Moricizine
Block Na channels
Slow binding kinetics (10–20 s)
slow conduction
but minimal prolongation
of refractoriness.
They markedly slow Phase 0 fast depolarization
They markedly slow conduction in the myocardial tissue
They possess slow rate of association and dissociation (strong effect) with sodium channels
They only have minor effects on the duration of action potential and refractoriness
They reduce automaticity by increasing the threshold potential rather than decreasing the slope of Phase 4 spontaneous depolarization.
Vmax

38. Blockade of β-adrenoceptor
CLASS II
Propranolol
Atenolol
Metoprolol
Timolol,
Esmolol
Blockade of β-adrenoceptor

39. CLASS III Block K channels Amiodarone Sotalol, Bretylium Dofetilide
Ibutilide
Includes sotalol and amioderone
Block K channels

40. CLASS IV
Verapamil
Diltiazem
Block slow Ca2+ channel

41. modification of the Sicilian Gambit drug classification system
This is a modification of the Sicilian Gambit drug classification system and
includes designation by the Vaughan Williams system. The sodium channel blockers are subdivided into the A, B, and C
subgroups based on their relative potency. The targets of antiarrhythmic drugs are listed across the top in columns. These
targets are the ion channels—sodium, calcium, and potassium—and the receptors—α-adrenergic, β-adrenergic, cholinergic
(ACh), and adenosinergic (Ado). The next columns show a comparison of the clinical actions of the drugs, including
proarrhythmic potential (Proarrhy), effect on left ventricular function (LV FX), effects on heart rate (Heart Rate), and potential for
extra cardiac side effects (Extra Cardiac). The electrocardiographic tracings indicate the changes (in color) that are caused by
usual dosages of the drug: PR interval (blue), QRS interval (red), and QT interval (green). The drugs are listed in rows with
their brand names shown in parentheses. The symbols in the table indicate the relative potency of the drugs as agonists or
antagonists. The solid triangle indicates the biphasic effects of bretylium to initially release norepinephrine and act as an
agonist and subsequently to block further release and to act as an antagonist of adrenergic tone. The number of arrows and
their directions indicate the magnitude and direction, respectively, of the effect of the drugs on heart rate and left ventricular
function (i.e., inotropy).

42. Proarrhythmia effect of antiarrhythmia agents
Ia, Ic class: Prolong QT interval, will cause VT or VF in coronary artery disease and heart failure patients
III class: Like Ia, Ic class agents
II, IV class: Bradycardia

43. Class I

44. duration, amplitude of AP,
Procainamide
Mechanism of Action
INa (primary) and IKr
(secondary)blockade.
Slowed conduction velocity and pacemaker activity.
Prolonged action potential duration and refractory period.
Vmax
prolong AP
duration, amplitude of AP,

45. Procainamide Clinical Applications
Most atrial and ventricular arrhythmias
Drug of second choice for most sustained ventricular arrhythmias associated with acute myocardial infarction

46. Procainamide Pharmacokinetics
Oral and parenteral; oral slow-release forms available Duration: 2–3 h
eliminated by hepatic metabolism to (NAPA) and renal elimination
NAPA implicated in torsades de pointes in patients with renal failure

47. Procainamide Toxicities, Interactions
Increased arrhythmias, hypotension, lupus-like syndrome
Dose
For stable wide-QRS tachycardia
IV dose: mg/min slowly until
Arrhythmia suppressed, hypotension ensues, QRS duration increases 50%, or maximum dose 17 mg/kg given
Maintenance infusion: 1-4 mg/min
Avoid if prolonged QT or CHF
For stable wide-QRS tachycardia
IV dose: mg/min slowly until
Arrhythmia suppressed, hypotension ensues, QRS duration increases 50%, or maximum dose 17 mg/kg given
Maintenance infusion: 1-4 mg/min
Avoid if prolonged QT or CHF

48. Quinidine
Similar to procainamide but more toxic (cinchonism, torsades); rarely used in arrhythmias
The effective dosage of quinidine varies among individuals
because of several factors. Although quinidine sulfate is
usually administered every 6 hours, there are wide interindividual
differences in its elimination half-life, which ranges
from 3 to 19 hours.11 Plasma protein binding also varies widely,
ranging from 50% to 95%.11 Oral bioavailability is approxi-
Quinidine metabolism is inhibited by cimetidine35 and
induced by phenytoin, phenobarbital,36 and rifampicin,24 with
the latter agents leading to reduced, often subtherapeutic,
quinidine concentrations. Clinical digoxin toxicity has been
described in 20% to 40% of patients receiving quinidine and
digoxin concurrently.35 The magnitude of this interaction is
dependent on quinidine dosage, and in some patients it may
not appear until the dosage is increased to higher levels.37,38
The rise in digoxin levels appears with the first dose of quinidine;
therefore, it is suggested that digoxin dosage be halved
when quinidine therapy is initiated. A similar interaction has
been reported for quinidine and digitoxin.
Quinidine is a potent inhibitor of the hepatic cytochrome
P450 (CYP) specific for debrisoquine metabolism
(CYP2D6),39,40 although it is not metabolized by this specific
CYP isozyme.41,42 Thus, it may interfere with the biotransformation
and actions of pharmacologic agents that are
dependent on this cytochrome for their metabolism, which
include propafenone, mexiletine, flecainide, metoprolol,
timolol, sparteine, and bufuralol.43 Quinidine worsens neuromuscular
blockade in patients with myasthenia gravis44 and
may prolong the effects of succinylcholine

49. Disopyramide
Similar to procainamide but significant antimuscarinic effects; may precipitate heart failure; not commonly used

50. Lidocaine Mechanism of Action Sodium channel (INa) blockade
Blocks activated and inactivated channels with fast kinetics
Does not prolong and may shorten action potential

51. Lidocaine Clinical Applications
Terminate ventricular tachycardias and prevent ventricular fibrillation after cardioversion
Dosage:
1.5 mg/kg IV, then
1– 4 mg/min; repeat
1/2 initial dose after
10 min

52. Lidocaine Pharmacokinetics IV first-pass hepatic metabolism
Reduce dose in patients with heart failure or liver disease
Toxicities
Neurologic symptoms

53. Mexiletine
Orally active congener of lidocaine; used in ventricular arrhythmias, chronic pain syndromes

54. Flecainide Mechanism of Action: Sodium channel (INa) blockade
Dissociates from channel with slow kinetics
no change in action potential duration

55. Flecainide Clinical Applications:
Supraventricular arrhythmias in patients with normal heart
do not use in ischemic conditions (post-myocardial infarction)

56. Flecainide Pharmacokinetics: Oral hepatic and kidney metabolism
half life ∼ 20 h
Toxicities:
Proarrhythmic
Notice: Class 1C drugs are particularly of low safety and have shown even increase mortality when used chronically after MI

57. Propafenone
Orally active, weak b-blocking activity; supraventricular arrhythmias; hepatic metabolism.

58. Moricizine
Phenothiazine derivative, orally active; ventricular arrhythmias, proarrhythmic. Withdrawn in USA.

59. Class II

60. Propranolol Mechanism of Action:
Direct membrane effects (sodium channel block) and prolongation of action potential duration
slows SA node automaticity and
AV nodal conduction velocity

61. Propranolol Clinical Applications:
Atrial arrhythmias and prevention of recurrent infarction and sudden death
Pharmacokinetics:
Oral, parenteral
duration 4–6 h

62. Propranolol Dose: 1 mg over 1 min (total 10-12 mg; 0.15 mg/kg).
onset:5 min
Toxicities:
Asthma, AV blockade, acute heart failure
Interactions: With other cardiac depressants and hypotensive drugs

63. Esmolol
Short-acting, IV only; used for intraoperative and other acute arrhythmias
Loading dose of mcg/kg IV over 1 min, then mcg/kg/min; titrate by 50 mcg/kg/min q min. up to 200 mcg/kg/min
Onset: 2-3 min.
0.5 mg/kg over 1 min, followed by mg/kg/min for 4 min; if no response after 5 min, 0.5 mg/kg for 1 min, followed by 0.1 mg/kg for 4 min; infusion mg/kg/min for rate control.

64. Class III

65. Amiodarone Mechanism of Action:
Blocks IKr, INa, ICa-L channels,β adrenoceptors
Prolongs action potential duration and QT interval
slows heart rate and AV node conduction
Low incidence of torsades de pointes
Amiodarone is a drug of multiple actions and is still not well understood
It is extensively taken up by tissues, especially fatty tissues (extensive distribution)
t1/2 = 60 days
Potent P450 inhibitor
Amiodarone antiarrhythmic effect is complex comprising class I, II, III, and IV actions
Dominant effect: Prolongation of action potential duration and refractoriness
It slows cardiac conduction, works as Ca2+ channel blocker, and as a weak β-adrenergic blocker
Toxicity
Most common include GI intolerance, tremors, ataxia, dizziness, and hyper-or hypothyrodism
Corneal microdeposits may be accompanied with disturbed night vision
Others: liver toxicity, photosensitivity, gray facial discoloration, neuropathy, muscle weakness, and weight loss
The most dangerous side effect is pulmonary fibrosis which occurs in % of the patients

66. Amiodarone Clinical Applications:
Serious ventricular arrhythmias and supraventricular arrhythmias

67. Amiodarone Pharmacokinetics: Oral, IV
variable absorption and tissue accumulation
hepatic metabolism, elimination complex and slow
Dose
• First dose: IV 300 mg over 10 minutes
• Repeat as needed if VT recurs
• Follow by maintenance infusion of 900 mg over 24 hrs
When amiodarone is loaded intravenously, 1 g is delivered during
the first 24 hours as follows: 150 mg is infused during the first 10
minutes (15 mg/min), followed by 360 mg during the next 6 hours
(1 mg/min), and then followed by 540 mg during the next 18 hours
(0.5 mg/min). If intravenous therapy is still desired after the first
24 hours, the infusion can continue at 0.5 mg/min (720 mg/24 h).

68. Amiodarone Toxicities:
Bradycardia and heart block in diseased heart, peripheral vasodilation, pulmonary and hepatic toxicity
hyper- or hypothyroidism.
Interactions:
Many, based on CYP metabolism

69. Sotalol Sotalol IV dose:
B-Adrenergic and IKr blocker, direct action potential prolongation properties, use for ventricular arrhythmias, atrial fibrillation
Dose:
Sotalol IV dose:
100 mg (1.5 mg/kg) over 5 minutes
Avoid if prolonged QT

70. Dofetilide Mechanism of Action: IKr block
Prolongs action potential, effective refractory period

71. Dofetilide Clinical Applications:
Maintenance or restoration of sinus rhythm in atrial fibrillation

72. Dofetilide Pharmacokinetics: Oral renal excretion Toxicities:
Torsades de pointes (initiate in hospital)
Interactions:
Additive with other QT-prolonging drugs

73. Ibutilide
Potassium channel blocker, may activate inward current; IV use for conversion in atrial flutter and fibrillation

74. Dronedarone
Amiodarone derivative; multichannel actions, reduces mortality in patients with atrial fibrillation

75. Class IV

76. Verapamil Mechanism of Action:
blocks both activated and inactivated L-type calcium (SA & AV node)
AV nodal conduction time and ERP
Extracardiac Effects: Peripheral vasodilation (Less than nifedipine)
Cardiac Effects
Verapamil blocks both activated and inactivated L-type calcium
channels. Thus, its effect is more marked in tissues that fire frequently,
those that are less completely polarized at rest, and those
in which activation depends exclusively on the calcium current,
such as the SA and AV nodes. AV nodal conduction time and
effective refractory period are consistently prolonged by therapeutic
concentrations. Verapamil usually slows the SA node by its
direct action, but its hypotensive action may occasionally result in
a small reflex increase of SA rate.
Verapamil can suppress both early and delayed afterdepolarizations
and may antagonize slow responses arising in severely depolarized
Tissue
Toxicity
Verapamil’s cardiotoxic effects are dose-related and usually avoidable.
A common error has been to administer intravenous verapamil
to a patient with ventricular tachycardia misdiagnosed as
supraventricular tachycardia. In this setting, hypotension and
ventricular fibrillation can occur. Verapamil’s negative inotropic
effects may limit its clinical usefulness in diseased hearts (see
Chapter 12 ). Verapamil can induce AV block when used in large
doses or in patients with AV nodal disease. This block can be
treated with atropine and β-receptor stimulants.
Adverse extracardiac effects include constipation, lassitude,
nervousness, and peripheral edema. Effective oral dosages are higher than intravenous dosage
because of first-pass metabolism and range from 120 mg to 640 mg
daily, divided into three or four doses.
Therapeutic Use
Supraventricular tachycardia is the major arrhythmia indication
for verapamil. Adenosine or verapamil are preferred over older
treatments (propranolol, digoxin, edrophonium, and vasoconstrictor
agents) and cardioversion for termination. Verapamil can
also reduce the ventricular rate in atrial fibrillation and flutter. It
only rarely converts atrial flutter and fibrillation to sinus rhythm.
Verapamil is occasionally useful in ventricular arrhythmias.
However, intravenous verapamil in a patient with sustained ventricular
tachycardia can cause hemodynamic collapse.

77. Verapamil Clinical Applications:
Supraventricular tachycardia. Atrial fibrillation and flutter .
Cardiac Effects
Verapamil blocks both activated and inactivated L-type calcium
channels. Thus, its effect is more marked in tissues that fire frequently,
those that are less completely polarized at rest, and those
in which activation depends exclusively on the calcium current,
such as the SA and AV nodes. AV nodal conduction time and
effective refractory period are consistently prolonged by therapeutic
concentrations. Verapamil usually slows the SA node by its
direct action, but its hypotensive action may occasionally result in
a small reflex increase of SA rate.
Verapamil can suppress both early and delayed afterdepolarizations
and may antagonize slow responses arising in severely depolarized
Tissue
Toxicity
Verapamil’s cardiotoxic effects are dose-related and usually avoidable.
A common error has been to administer intravenous verapamil
to a patient with ventricular tachycardia misdiagnosed as
supraventricular tachycardia. In this setting, hypotension and
ventricular fibrillation can occur. Verapamil’s negative inotropic
effects may limit its clinical usefulness in diseased hearts (see
Chapter 12 ). Verapamil can induce AV block when used in large
doses or in patients with AV nodal disease. This block can be
treated with atropine and β-receptor stimulants.
Adverse extracardiac effects include constipation, lassitude,
nervousness, and peripheral edema. Effective oral dosages are higher than intravenous dosage
because of first-pass metabolism and range from 120 mg to 640 mg
daily, divided into three or four doses.
Therapeutic Use
Supraventricular tachycardia is the major arrhythmia indication
for verapamil. Adenosine or verapamil are preferred over older
treatments (propranolol, digoxin, edrophonium, and vasoconstrictor
agents) and cardioversion for termination. Verapamil can
also reduce the ventricular rate in atrial fibrillation and flutter. It
only rarely converts atrial flutter and fibrillation to sinus rhythm.
Verapamil is occasionally useful in ventricular arrhythmias.
However, intravenous verapamil in a patient with sustained ventricular
tachycardia can cause hemodynamic collapse.

78. Verapamil Toxicities:
constipation, sinus arrest, hypotension, headache, nervousness
Dose:
5-10 mg ( mg/kg) over 2 min; if no response, additional 5-10 mg after min; 3-10 mg every 4-6 h for rate control. Onset:3-5 min.
Cardiac Effects
Verapamil blocks both activated and inactivated L-type calcium
channels. Thus, its effect is more marked in tissues that fire frequently,
those that are less completely polarized at rest, and those
in which activation depends exclusively on the calcium current,
such as the SA and AV nodes. AV nodal conduction time and
effective refractory period are consistently prolonged by therapeutic
Verapamil and diltiazem bind only to open depolarized voltage-operated Ca2+ channels, and hence preventing re-polarization until the drug dissociates from the channels.
Therefore, they are use-dependent blocking rapidly beating heart since in a normally-paced heart, Ca2+ channels have enough time to repolarize and the drug to dissociate from the channel before the next conduction cycle
Verapamil and diltiazem slow conduction and prolong effective refractory period in Ca2+ current-dependent tissues like AV node
concentrations. Verapamil usually slows the SA node by its
direct action, but its hypotensive action may occasionally result in
a small reflex increase of SA rate.
Verapamil can suppress both early and delayed afterdepolarizations
and may antagonize slow responses arising in severely depolarized
Tissue
Toxicity
Verapamil’s cardiotoxic effects are dose-related and usually avoidable.
A common error has been to administer intravenous verapamil
to a patient with ventricular tachycardia misdiagnosed as
supraventricular tachycardia. In this setting, hypotension and
ventricular fibrillation can occur. Verapamil’s negative inotropic
effects may limit its clinical usefulness in diseased hearts (see
Chapter 12 ). Verapamil can induce AV block when used in large
doses or in patients with AV nodal disease. This block can be
treated with atropine and β-receptor stimulants.
Adverse extracardiac effects include constipation, lassitude,
nervousness, and peripheral edema. Effective oral dosages are higher than intravenous dosage
because of first-pass metabolism and range from 120 mg to 640 mg
daily, divided into three or four doses.
Therapeutic Use
Supraventricular tachycardia is the major arrhythmia indication
for verapamil. Adenosine or verapamil are preferred over older
treatments (propranolol, digoxin, edrophonium, and vasoconstrictor
agents) and cardioversion for termination. Verapamil can
also reduce the ventricular rate in atrial fibrillation and flutter. It
only rarely converts atrial flutter and fibrillation to sinus rhythm.
Verapamil is occasionally useful in ventricular arrhythmias.
However, intravenous verapamil in a patient with sustained ventricular
tachycardia can cause hemodynamic collapse.

79. Unclassified

80. Adenosine Endogenous chemical Mechanism of Action:
Increase in potassium efflux decreases calcium influx.
This hyperpolarizes cardiac cells
Clinical Applications:
PSVT
Rapid IV injection
t 1/2: ( sec)
S: flushing, chest pain, and dyspnea
Caution in patients (AV) block, bronchial asthma
Adenosine activates A1-purinergic receptors decreasing the SA nodal firing and automaticity, reducing conduction velocity, prolonging effective refractory period, and depressing AV nodal conductivity
It is the drug of choice in the treatment of paroxysmal supra-ventricular tachycardia
It is used only by slow intravenous bolus
It only has a low-profile toxicity (lead to bronchospasm) being extremly short acting for 15 seconds only
Adenosine is formed by serial dephosphorylation of adenosine
triphosphate. It is an α-agonist and the drug of choice
for pharmacologic termination of hemodynamically stable
AVNRT. Sixty percent of patients respond at a dose of 6 mg,
and an additional 32% of patients respond at a dose of 12 mg.
Its therapeutic effect is short, lasting approximately 10 seconds.
This extremely short half-life results from rapid active
transport of the drug into red blood cells and endothelial cells,
where it is metabolized. To be effective, adenosine should be
injected rapidly and flushed quickly through the intravenous
tubing with saline.
Common side effects of adenosine include facial flushing,
dyspnea, and chest pressure. Generally, these effects are transient,
lasting less than 60 seconds. Less common side effects
include nausea, light-headedness, headache, sweating, palpitations,
hypotension, and blurred vision.
Several drugs influence the clinical effectiveness of adenosine.
Caffeine and theophylline antagonize the actions of

81. Adenosine Dose: Adenosine IV dose:
First dose: 6 mg rapid IV push; follow with NS flush.
Second dose: 12 mg if required.
Adenosine activates A1-purinergic receptors decreasing the SA nodal firing and automaticity, reducing conduction velocity, prolonging effective refractory period, and depressing AV nodal conductivity
It is the drug of choice in the treatment of paroxysmal supra-ventricular tachycardia
It is used only by slow intravenous bolus
It only has a low-profile toxicity (lead to bronchospasm) being extremly short acting for 15 seconds only
Adenosine is formed by serial dephosphorylation of adenosine
triphosphate. It is an α-agonist and the drug of choice
for pharmacologic termination of hemodynamically stable
AVNRT. Sixty percent of patients respond at a dose of 6 mg,
and an additional 32% of patients respond at a dose of 12 mg.
Its therapeutic effect is short, lasting approximately 10 seconds.
This extremely short half-life results from rapid active
transport of the drug into red blood cells and endothelial cells,
where it is metabolized. To be effective, adenosine should be
injected rapidly and flushed quickly through the intravenous
tubing with saline.
Common side effects of adenosine include facial flushing,
dyspnea, and chest pressure. Generally, these effects are transient,
lasting less than 60 seconds. Less common side effects
include nausea, light-headedness, headache, sweating, palpitations,
hypotension, and blurred vision.
Several drugs influence the clinical effectiveness of adenosine.
Caffeine and theophylline antagonize the actions of

82. Magnesium Mechanism of Action: unknown Clinical Applications:
Used for treatment of torsades de pointes
Toxicities:
Bradycardia
Respiratory paralysis
Flushing
Headache
Given in 2 gm over 10 min

83. Compare?? class ECG QT Conduction velocity Refractory period IA ++ ↓ ↑IB no IC + II
↓In SAN and AVN
↑ in SAN and AVN
III No IV
↓ in SAN and AVN

84. Management of some types of arrhythemia

88. WPW AF

89. 2010 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care