Paroxysmal Supraventricular Tachycardias
1895CHAPTER 249
cases, directly from the mitral valve annulus avoiding the coronary
sinus musculature altogether. In typical forms, the conduction time
from the compact AV node region to the atrium is similar to that from
the compact node to the His bundle and ventricles, such that atrial
activation occurs at about the same time as ventricular activation. The
P wave is therefore inscribed during, slightly before, or slightly after the
QRS and can be difficult to discern. Often the P wave is seen at the end
of the QRS complex as a pseudo-r′ in lead V1
and pseudo-S waves in
leads II, III, and aVF (Fig. 249-2).
More unusual forms of AVNRT have P waves falling later, anywhere
between QRS complexes, in which case, an inverted P wave is seen in
the inferior limb leads with the inverted P wave seen in the subsequent
T wave. The rate can vary with sympathetic tone through its effect
on the conduction time of AV nodal tissues. Simultaneous atrial and
ventricular contraction results in atrial contraction against a closed tricuspid valve, producing a cannon A wave visible in the jugular venous
pulse often perceived as a fluttering sensation in the neck. Elevated
venous pressures may also lead to release of natriuretic peptides that
cause posttachycardia diuresis. In contrast to ATs, maneuvers or medications that produce AV nodal block terminate the arrhythmia. Acute
treatment is the same as for other forms of PSVT (discussed below).
Whether ongoing therapy is warranted depends on the severity of
symptoms and frequency of episodes. Reassurance and instruction as
to how to perform the Valsalva maneuver or other vagal nerve stimulating maneuvers to terminate episodes are sufficient for many patients.
II
V1
CS Tricuspid
valve
P waves
A B
Inferior AV node
extension:
Slow pathway
Compact AV node:
Fast pathway
FIGURE 249-1 Atrioventricular (AV) node reentry. A. Leads II and V1
are shown. P waves are visible at the end of the QRS complex and are negative in lead II and may give
the impression of S waves in the inferior limb leads II, III, and aVF and an R′ in lead V1
. B. Stylized version of the AV nodal reentry circuit within the triangle of Koch (see
Fig. 247-1) that involves AV node and its extensions along with perinodal atrial tissue. CS, coronary sinus.
ATRIOVENTRICULAR NODAL REENTRY
TACHYCARDIA
AVNRT is the most common form of paroxysmal supraventricular
tachycardia (PSVT), representing ~60% of cases referred for catheter
ablation. It most commonly manifests in the second to fourth decades
of life, often in women. It is often well tolerated, but rapid tachycardia, particularly in the elderly, may cause angina, pulmonary edema,
hypotension, or syncope. It is not usually associated with structural
heart disease. In patients without associated heart disease, AVNRT is
not a life-threatening arrhythmia; however, it may cause significant
symptoms.
The mechanism is reentry involving the AV node and the perinodal
atrium, made possible by the existence of multiple pathways for conduction from the atrium into the AV node that are capable of conduction in two directions (Fig. 249-1).
Most forms of AVNRT utilize a slowly conducting AV nodal pathway (right inferior extension) that extends from the compact AV node
near the His bundle, inferiorly along the tricuspid valve annulus to the
floor of the coronary sinus. The reentry wavefront propagates up this
slowly conducting pathway to the compact AV node and then exits
from the fast pathway at the top of the AV node. The path back to
the slow pathway probably involves the left atrial septum, which has
connections to the coronary sinus musculature. More unusual forms
of AVNRT utilize a left inferior extension that connects to the compact
AV node through the roof of the coronary sinus or, in extremely rare
I
II
III
V1
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
I
II
III
V1
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
FIGURE 249-2 Atrioventricular nodal reentry tachycardia with retrograde P waves before and after adenosine termination.
1896 PART 6 Disorders of the Cardiovascular System
Administration of an oral beta blocker, verapamil, or diltiazem at the
onset of an episode can be used to facilitate termination. Chronic therapy with these medications or flecainide is an option if prophylactic
therapy is needed. Catheter ablation of the slow AV nodal pathway is
recommended for patients with recurrent or severe episodes or when
drug therapy is ineffective, not tolerated, or not desired by the patient.
Catheter ablation is curative in >95% of patients. The major risk is AV
block requiring permanent pacemaker implantation, which occurs in
<1% of patients.
JUNCTIONAL TACHYCARDIA
Junctional ectopic tachycardia (JET) is due to automaticity within the
AV node. It is rare in adults and more frequently encountered as an
incessant tachycardia in children, often in the perioperative period
of surgery for congenital heart disease. It presents as a narrow QRS
tachycardia, often with ventriculoatrial (VA) block, such that AV
dissociation is present. JET can occur as a manifestation of increased
adrenergic tone and may be seen after administration of isoproterenol,
particularly after catheter ablation in the perinodal region. It may also
occur for a short period of time after ablation for AVNRT. Accelerated
junctional rhythm is a junctional automatic rhythm between 50 and
100 beats/min. Initiation may occur with gradual acceleration in rate,
suggesting an automatic focus, or after a premature ventricular contraction, suggesting a focus of triggered automaticity. VA conduction
is usually present, with P-wave morphology and timing such that it
resembles AVNRT at a slow rate. It can be related to increased sympathetic tone and may produce palpitations. It usually does not require
specific therapy.
ACCESSORY PATHWAYS AND THE
WOLFF-PARKINSON-WHITE SYNDROME
Accessory pathways (APs) occur in 1 in 1500–2000 people and are
associated with a variety of arrhythmias including narrow-complex
PSVT, wide-complex tachycardias, and, rarely, sudden death. Most
patients have structurally normal hearts, but APs are associated with
Ebstein’s anomaly of the tricuspid valve and forms of hypertrophic
cardiomyopathy including PRKAG2 mutations, Danon’s disease, and
Fabry’s disease (Fig. 249-3).
APs are abnormal connections that allow conduction between the
atrium and ventricles across the AV ring. They are present from birth
and are due to failure of complete partitioning of atrium and ventricle
by the fibrous AV rings. They occur across either an AV valve annulus
or the septum, most frequently between the left atrium and free wall
of the left ventricle, followed by posteroseptal, right free wall, and
anteroseptal locations. If the impulse from the sinus node conducts
through the AP to the ventricle (antegrade) before the impulse conducts through the AV node and His bundle, then the ventricles are
preexcited during sinus rhythm, and the electrocardiogram (ECG)
shows a short P-R interval (<0.12 s), slurred initial portion of the QRS
(delta wave), and prolonged QRS duration produced by slow conduction through direct activation of ventricular myocardium over the AP.
The morphology of the QRS and delta wave is determined by the AP
location and the degree of fusion between the excitation wavefronts
from conduction over the AV node and conduction over the AP
(Fig. 249-4).
Right-sided pathways preexcite the right ventricle, producing a left
bundle branch block–like configuration in lead V1
, and often create
marked preexcitation because of relatively close proximity of the AP
to the sinus node (Fig. 249-4). Left-sided pathways preexcite the left
ventricle and may produce a right bundle branch–like configuration in
lead V1
and a negative delta wave in aVL, indicating initial depolarization of the lateral portion of the left ventricle that can mimic Q waves
of lateral wall infarction (Fig. 249-4). Because of the relatively large
distance between the sinus node and left free wall APs, preexcitation
may be minimal or absent on 12-lead ECG. Preexcitation due to an AP
at the diaphragmatic surface of the heart, typically in the paraseptal
region, produces delta waves that are negative in leads III and aVF,
mimicking the Q waves of inferior wall infarction (Fig. 249-4). Preexcitation can be intermittent and disappear during exercise as conduction
over the AV node accelerates and may take over ventricular activation
completely.
Wolff-Parkinson-White (WPW) syndrome is defined as a preexcited
QRS during sinus rhythm and episodes of PSVT. There are a number of
variations of APs that may not cause preexcitation and/or arrhythmias.
Concealed APs allow only retrograde conduction, from ventricle to
atrium, so no preexcitation is present during sinus rhythm, but SVT
can occur. Other unusual forms of APs occur. Fasciculoventricular
Sinus rhythm—
antegrade
AP conduction
C
Orthodomic AV
reentry—retrograde
AP conduction
Antidromic AV
reentry—antegrade
AP conduction
Delta-wave p p
B
A
FIGURE 249-3 Wolff-Parkinson-White (WPW) syndrome. A. A 12-lead
electrocardiogram in sinus rhythm (SR) of a patient with WPW demonstrating short
P-R interval, delta waves, and widened QRS complex. This patient had an anteroseptal
location of the accessory pathway (AP). B. Orthodromic atrioventricular (AV) reentry in
a patient with WPW syndrome using a posteroseptal AP. Note the P waves in the ST
segment (arrows) seen in lead III and normal appearance of QRS complex. C. Three
most common rhythms associated with WPW syndrome: sinus rhythm demonstrating
antegrade conduction over the AP and AV node; orthodromic AV reentry tachycardia
(AVRT) using retrograde conduction over the AP and antegrade conduction over the
AV node; and antidromic AVRT using retrograde conduction over the AV node and
antegrade conduction over the AP.
Paroxysmal Supraventricular Tachycardias
1897CHAPTER 249
Left lateral Right free wall
aVL V1
Postero septal
PV
AV
TV
MV
II aVF III
Coronary
sinus (CS)
FIGURE 249-4 Potential locations for accessory pathways in patients with WolffParkinson-White syndrome and typical QRS appearance of delta waves that can
mimic underlying structural heart disease such as myocardial infraction of bundle
branch block. AV, aortic valve; MV, mitral valve; PV, pulmonary valve; TV, tricuspid
valve.
connections between the His bundle and ventricular septum produce
preexcitation but do not cause arrhythmia, probably because the circuit
is too short to promote reentry. Atriofascicular pathways, also known
as Mahaim fibers, probably represent a duplicate AV node and HisPurkinje system that connect the right atrium to fascicles of the right
bundle branch and produce a wide-complex tachycardia having a left
bundle branch block configuration.
ATRIOVENTRICULAR RECIPROCATING
TACHYCARDIA
The most common tachycardia caused by an AP is the PSVT designated orthodromic AV reciprocating tachycardia. The circulating reentry
wavefront propagates from the atrium anterogradely over the AV node
and His-Purkinje system to the ventricles and then reenters the atria
via retrograde conduction over the AP. The QRS is narrow or may
have typical right or left bundle branch block, but without preexcitation during tachycardia. Because excitation through the AV node and
AP are necessary, AV or VA block results in tachycardia termination.
During sinus rhythm, preexcitation is seen if the pathway also allows
anterograde conduction. Most commonly, during tachycardia, the R-P
interval is shorter than the P-R interval and can resemble AVNRT.
Unlike typical AVNRT, P waves always follow the QRS and are never
simultaneous with a narrow QRS complex because the ventricles must
be activated before the reentry wavefront reaches the AP and conducts
back to the atrium. The morphology of the P wave is determined by the
pathway location, but it can be difficult to assess because it is usually
inscribed during the ST segment. The P wave in posteroseptal APs is
negative in leads II, III, and aVF, similar to that of AV nodal reentry,
but P-wave morphology differs from AV nodal reentry for pathways
in other locations. Occasionally, an AP conducts extremely slowly
in the retrograde direction, resulting in tachycardia with a long R-P
interval, similar to most ATs. These pathways are usually located in the
septal region and have negative P waves in leads II, III, and aVF. Slow
AP conduction facilitates reentry, often leading to nearly incessant
tachycardia, known as permanent junctional reciprocating tachycardia
(PJRT). Tachycardia-induced cardiomyopathy can occur. Without
an invasive electrophysiology study, it may be difficult to distinguish
this form of orthodromic AV reentry from atypical AV nodal reentry
or AT.
PREEXCITED TACHYCARDIAS
Preexcited tachycardia occurs when the ventricles are activated by
antegrade conduction over the AP. The most common mechanism is
antidromic AV reciprocating tachycardia in which activation propagates
from atrium to ventricle via the AP and then conducts retrogradely to
the atria via the His-Purkinje system and the AV node (or rarely a second AP). The wide QRS complex is produced entirely via ventricular
excitation over the AP because there is no contribution of ventricular
activation over more rapidly conducting specialized His-Purkinje
fibers. This tachycardia is often indistinguishable from monomorphic
ventricular tachycardia. The presence of preexcitation in sinus rhythm
suggests the diagnosis.
Preexcited tachycardia also occurs if an AP allows antegrade conduction to the ventricles during AT, atrial flutter, atrial fibrillation
(AF), or AV nodal reentry, otherwise known as bystander AP conduction. AF and atrial flutter are potentially life-threatening if the AP
allows very rapid repetitive conduction (Fig. 249-5).
Approximately 25% of APs causing preexcitation allow minimum
R-to-R intervals of <250 ms during AF and are associated with a higher
risk of inducing ventricular fibrillation and sudden death. Preexcited
AF presents as a wide-complex, very irregular rhythm. During AF, the
ventricular rate is determined by the conduction properties of the AP
and AV node. The QRS complex can appear quite bizarre and change
on a beat-to-beat basis due to the variability in the degree of fusion
from activation over the AV node and AP, or all beats may be due
to conduction over the AP. Ventricular activation from the Purkinje
system may depolarize the ventricular aspect of the AP and prevent
atrial wavefront conduction over the AP. Slowing AV nodal conduction
without slowing AP conduction can thereby facilitate AP conduction
and dangerously accelerate the ventricular rate. Administration of
AV nodal–blocking agents, including oral or intravenous verapamil,
diltiazem, beta blockers, intravenous adenosine, and intravenous
amiodarone, is contraindicated during preexcited AF. Rapid preexcited
tachycardia should be treated with electrical cardioversion or intravenous procainamide or ibutilide, which may terminate the arrhythmia
or slow the ventricular rate.
MANAGEMENT OF PATIENTS WITH
ACCESSORY PATHWAYS
Acute management of orthodromic AV reentry is discussed below for
PSVT. Patients with WPW syndrome may have wide-complex tachycardia due to antidromic AV reentry, orthodromic AV with bundle
branch block, or a preexcited tachycardia, and treatment depends on
the underlying rhythm. Initial patient evaluation should include assessment for aggravating factors, including intercurrent illness and factors
that increase sympathetic tone. Examination should focus on excluding
underlying heart disease. An echocardiogram is reasonable to exclude
Ebstein’s anomaly and forms of hypertrophic cardiomyopathy that can
be associated with APs.
Patients with preexcitation who have symptoms of arrhythmia are
at risk for developing AF and sudden death if they have an AP that
allows rapid antegrade conduction. The risk of cardiac arrest is in the
range of 2 per 1000 patients in adults but is likely greater in children.
An invasive electrophysiology study is recommended to assess whether
the pathway can support dangerously rapid heart rates if AF were to
occur, and it is usually combined with potentially curative catheter
ablation. Catheter ablation is warranted for recurrent arrhythmias
1898 PART 6 Disorders of the Cardiovascular System
25mm/s 10mm/mV 150Hz 9.0.9 12SL 243 CID: 0
I
II
III
V1
V5
II
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
I
II
III
V1
V5
II
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
FIGURE 249-5 Preexcited atrial fibrillation (AF) due to conduction over a left free wall accessory pathway (AP). The electrocardiogram shows rapid irregular QRS
complexes that represent fusion between conduction over the atrioventricular node and left free wall AP. Shortest R-R intervals between preexcited QRS complexes of
<250 ms, as in this case, indicate a risk of sudden death with this arrhythmia.
when drugs are ineffective, not tolerated, or not desired by the patient.
Efficacy is in the range of 95% depending on the location of the AP.
Serious complications occur in <3% of patients but can include AV
block, cardiac tamponade, thromboembolism, coronary artery injury,
and vascular access complications. Procedure mortality is <1 in 1000
patients. Ambulatory monitoring or exercise testing is often used to
gain reassurance that the AP is not high risk, evaluating for abrupt loss
of conduction (preexcitation) at physiologic heart rates consistent with
a low-risk pathway, but this is not completely reliable. Gradual loss of
AP conduction with increased sympathetic tone does not reliably indicate low risk since this can occur as AV nodal conduction time shortens, and therefore, the possibility of rapid antegrade AP conduction is
not excluded definitively.
For patients with concealed APs or known low-risk APs causing
orthodromic AVRT, chronic therapy is guided by symptoms and frequency of events. Vagal maneuvers may terminate episodes, as may a
dose of beta blocker, verapamil, or diltiazem taken at the onset of an
episode. Chronic therapy with these agents or flecainide can reduce the
frequency of episodes in some patients.
Adults who have preexcitation but no arrhythmia symptoms have
a risk of sudden death estimated to be 1 per 1000 patient-years.
Electrophysiology study is usually advised for people in occupations
for which an arrhythmia occurrence would place them or others at
risk, such as police, military, and pilots, or for individuals who desire
evaluation for risk. Routine follow-up without therapy is reasonable
in others. Children are at greater risk of sudden death, ~2 per 1000
patient-years.
TREATMENT
Paroxysmal Supraventricular Tachycardia
Acute management of narrow QRS PSVT is guided by the clinical
presentation. Continuous ECG monitoring should be implemented,
and a 12-lead ECG should always be obtained when possible,
since this may be useful in determining the mechanism. In the
presence of hypotension with unconsciousness or respiratory distress, QRS-synchronous direct current cardioversion is warranted,
but this is rarely needed, because intravenous adenosine works
promptly in most situations (see below). For stable individuals, initial therapy takes advantage of the fact that most PSVTs are dependent on AV nodal conduction (AV nodal reentry or orthodromic
AV reentry) and, therefore, likely to respond to sympatholytic and
vagotonic maneuvers and drugs. As these are administered, the
ECG should be continuously recorded because the response can
establish the diagnosis. AV block with only transient slowing of
tachycardia may expose ongoing P waves, indicating AT or atrial
flutter as the mechanism (Fig. 249-6).
Common Atrial Flutter and Macroreentrant and Multifocal Atrial Tachycardias
1899CHAPTER 250
Regular narrow-complex
tachycardia
Hemodynamic instability
Cardioversion
Catheter
ablation
Antiarrhythmic
therapy
Non-DHP CCB
and/or Betablocker
Vagal reflex/
adenosine
No
Ineffective
Ineffective
Recurrent or
incessant
Recurrent
Recurrent
Recurrent
Yes
FIGURE 249-6 Treatment algorithm for patients presenting with hemodynamically
stable paroxysmal supraventricular tachycardia. CCB, calcium channel blocker;
DHP, dihydropyridine.
Carotid sinus massage is reasonable provided the risk of carotid
vascular disease is low, as indicated by absence of carotid bruits
and no prior history of stroke. A Valsalva maneuver should be
attempted in cooperative individuals, and if effective, the patient
can be taught to perform this maneuver as needed. If vagal maneuvers fail or cannot be performed, intravenous adenosine will terminate the vast majority of PSVT episodes by transiently blocking
conduction in the AV node. Adenosine may produce transient chest
pain, dyspnea, and anxiety. It is contraindicated in patients with
prior cardiac transplantation due to potential hypersensitivity due
to surgical sympathetic denervation. It can theoretically aggravate
bronchospasm. Adenosine precipitates AF, which is usually brief,
in up to 15% of patients, so it should be used cautiously in patients
with WPW syndrome in whom AF may produce hemodynamic
instability. Intravenous beta blockers and calcium channel blockers
(verapamil or diltiazem) are also effective but may cause hypotension before and after arrhythmia termination and have a longer
duration of action. These agents can also be given orally and can be
taken by the patient on an as-needed basis to slow ventricular rate
and facilitate termination by Valsalva maneuver.
The differential diagnosis of wide-complex tachycardia includes
ventricular tachycardia, PSVT with bundle branch block aberrancy,
and preexcited tachycardia (see above). In general, these should be
managed as ventricular tachycardia until proven otherwise. If the
tachycardia is regular and the patient is stable, a trial of intravenous
adenosine is reasonable. Very irregular wide-complex tachycardia is
most likely preexcited AF or flutter (see above) and should be managed with cardioversion, intravenous procainamide, or ibutilide. If
the diagnosis of PSVT with aberrancy is unequivocal, as may be the
case in patients with prior episodes, treatment for PSVT with vagal
maneuvers and adenosine is reasonable. In all cases, continuous
ECG monitoring should be implemented, and emergency cardioversion and defibrillation should be available.
Acknowledgment
Gregory F. Michaud and William G. Stevenson contributed to this chapter in the 20th edition, and some material from that chapter has been
retained here.
Macroreentrant atrial tachycardia is due to a large anatomic reentry circuit, often associated with areas of scar in the atria. Common or typical
right atrial flutter is due to a circuit pathway around the tricuspid valve
annulus, bounded anteriorly by the annulus and posteriorly by functional conduction block in the crista terminalis. The wavefront passes
between the inferior vena cava and the tricuspid valve annulus, known
as the sub-Eustachian or cavotricuspid isthmus, where it is susceptible
to interruption by catheter ablation. Thus, common atrial flutter is also
known as cavotricuspid isthmus-dependent atrial flutter. This circuit
most commonly revolves in a counterclockwise direction (as viewed
looking toward the tricuspid annulus from the ventricular apex), which
produces the characteristic negative sawtooth flutter waves in leads
II, III, and aVF and positive P waves in lead V1
. When the direction
is reversed, clockwise rotation produces the opposite P-wave vector
in those leads. The atrial rate is typically 240–300 beats/min but may
be slower in the presence of atrial disease or antiarrhythmic drugs. It
often conducts to the ventricles with 2:1 AV block, creating a regular
tachycardia at 130–150 beats/min, with P waves that may be difficult to
discern from the T wave. Maneuvers that increase AV nodal block will
typically expose flutter waves, allowing diagnosis. AV nodal disease or
AV nodal–blocking agents may render the conduction ratio between
atrium and ventricle higher, resulting in more obvious flutter waves
(Fig. 250-1).
Common right atrial flutter often occurs in association with atrial
fibrillation and often with atrial scar from senescence or prior cardiac
surgery. Right-sided cardiac or pulmonary vascular disease may also
predispose to common right atrial flutter. Some patients with atrial
fibrillation treated with an antiarrhythmic drug, particularly flecainide, propafenone, or amiodarone, will present with atrial flutter rather
than fibrillation, since these agents slow atrial conduction velocity
and can promote reentry, in addition to suppressing ectopic atrial
triggers.
Macroreentrant atrial tachycardias (ATs) that are not dependent
on conduction through the cavotricuspid isthmus are referred to as
atypical atrial flutters. They can occur in either atrium and are almost
universally associated with areas of atrial scar. Right atrial atypical flutter often occurs after cardiac surgery if an atriotomy is performed in
the right atrium as part of the surgery. Left atrial flutter and perimitral
left atrial flutter are commonly seen after extensive left atrial ablation
for atrial fibrillation or atrial surgery. The clinical presentation is similar to common atrial flutter but with different P-wave morphologies.
They can be difficult to distinguish from focal AT, and in most cases,
the mechanism can only be confirmed by an electrophysiology study
(Fig. 250-2).
250 Common Atrial Flutter
and Macroreentrant and
Multifocal Atrial Tachycardias
William H. Sauer, Paul C. Zei
■ FURTHER READING
Brugada J et al: 2019 ESC Guidelines for the management of patients
with supraventricular tachycardia. The task force for the management
of patients with supraventricular tachycardia of the European Society
of Cardiology (ESC) Developed in collaboration with the Association
for European Paediatric and Congenital Cardiology (AEPC). Eur
Heart J 41:655, 2020.
Callans DJ: Josephson’s Clinical Cardiac Electrophysiology: Techniques
and Interpretations, 6th ed. Philadelphia, Wolters Kluwer, 2021.
Jalife J, Stevenson W (eds): Zipes and Jalife’s Cardiac Electrophysiology: From Cell to Bedside, 8th ed. Philadelphia, Elsevier, 2022.
1900 PART 6 Disorders of the Cardiovascular System
I
II
III
II
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
Right atrium
Typical CTI-Dependent
Counterclockwise Atrial
Flutter
Tricuspid
Valve
Annulus
Tricuspid
Valve Annulus
CTI-Dependent
Counterclockwise
Atrial Flutter
FIGURE 250-1 Electrocardiogram (ECG) and electroanatomic map of typical flutter. In the upper panel, a 12-lead ECG of typical atrial flutter is shown. Note the sawtooth
pattern of atrial activation, with negative flutter (F) waves, as well as 4:1 atrioventricular (AV) conduction during flutter. In the lower panel, counterclockwise (more common,
left portion of the panel) and clockwise typical, cavotricuspid isthmus (CTI)–dependent atrial flutter is shown on electroanatomic maps. These maps of the electrical
activation pattern during flutter were obtained during electrophysiologic study and catheter ablation, viewed from the vantage point of the right ventricle through the
tricuspid valve. Colors refer to local activation time, demonstrating a complete timing of the electrical circuit around the peritricuspid RA.
ATRIAL FLUTTER
Initial management of atrial flutter is similar to that for atrial fibrillation, discussed in more detail in Chap. 251. Electrical cardioversion is warranted for hemodynamic instability or severe symptoms.
Otherwise, rate control can be achieved with administration of AV
nodal–blocking agents, but this is often more difficult than for atrial
fibrillation. The risk of thromboembolic events is thought to be similar
to that associated with atrial fibrillation, and hence, management of
stroke risk is similar to the approach for atrial fibrillation. Anticoagulation is warranted prior to conversion for episodes >48 h in duration
and chronically for patients at increased risk of thromboembolic
stroke based on the CHA2
DS2
-VASc scoring system (see Chap. 251
and Table 251-2).
For a first episode of atrial flutter, conversion to sinus rhythm
without subsequent chronic use of an antiarrhythmic drug therapy is
reasonable. For recurrent episodes, antiarrhythmic drug therapy with
sotalol, dofetilide, disopyramide, and amiodarone may be considered,
but >70% of patients experience recurrences. For recurrent episodes
of common atrial flutter, catheter ablation of the cavotricuspid isthmus abolishes the arrhythmia in >95% of patients with a low risk of
Common Atrial Flutter and Macroreentrant and Multifocal Atrial Tachycardias
1901CHAPTER 250
I
II
III
V1
V5
II
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
FIGURE 250-2 Electrocardiogram (ECG) and electroanatomic map of mitral annular flutter after pulmonary vein isolation. In the upper panel, a 12-lead surface ECG
demonstrates atypical atrial flutter. Note the flutter wave morphology with positively deflected flutter waves in the inferior leads (II, III, aVF), with 3:1 atrioventricular (AV)
conduction. In the lower panel, the corresponding electroanatomic map obtained during electrophysiologic study and catheter ablation is shown. This panel shows the left
atrium (LA) from the vantage point of the left ventricle, through the mitral valve. Colors refer to local activation time, demonstrating a complete timing of the electrical circuit
around the peri-mitral valve LA tissues. (Adapted from Fig. 245-1 in the 20th edition of Harrison’s Principles of Internal Medicine.)
complications that are largely related to vascular access and rarely heart
block. Therefore, catheter ablation for atrial flutter can be considered as
first-line therapy. Approximately 50% of patients presenting with atrial
flutter develop atrial fibrillation within 5 years after diagnosis, which
is an important consideration in patients with a high-risk profile for
thromboembolism. In general, patients with atrial flutter are treated
identically to those with atrial fibrillation in terms of recommendations
for anticoagulation for stroke prevention (Fig. 250-3).
MULTIFOCAL ATRIAL TACHYCARDIA
Multifocal AT (MAT) is characterized by a rhythm with at least three
distinct P-wave morphologies with rates typically between 100 and
150 beats/min. Unlike atrial fibrillation, there are clear isoelectric
intervals between P waves and the atrial rate is slower. The mechanism
is likely triggered automaticity from multiple atrial foci. It is usually
encountered in patients with chronic pulmonary disease and acute
illness (Fig. 250-4).
Therapy for MAT is directed at treating the underlying disease and
correcting any metabolic abnormalities. Electrical cardioversion is
ineffective. The calcium channel blockers verapamil or diltiazem may
slow the atrial and ventricular rate. Patients with severe pulmonary
disease often do not tolerate beta blocker therapy. MAT may respond to
amiodarone, but long-term therapy with this agent is usually avoided
due to its toxicities, particularly pulmonary fibrosis. The associated risk
of thromboembolism in MAT remains unclear but is not considered to
be the same as atrial fibrillation or atrial flutter.
1902 PART 6 Disorders of the Cardiovascular System
Atrial flutter/MRAT
Hemodynamic
instability
No Yes
No Yes
Yes
Yes
No
If not available
or contraindicated
IV ibutilide
or dofetilide IV or
oral (in-hospital)
(I B)
PPM/ICD
present?
Electrical
cardioversion
preferred
Low-energy
synchronized
cardioversion (I B)
IV beta blocker
or
IV diltiazem or
verapamil
(IIa B)
Rhythm control
strategy
Synchronized
cardioversion
(I B)
High-rate
atrial pacing
(I B)
IV amiodarone
(IIb C)
Invasive or noninvasive
high-rate atrial pacing
(IIb B)
No
FIGURE 250-3 Approach to the patient with atrial flutter or macroreentrant atrial tachycardia (MRAT). ICD, implantable cardioverter-defibrillator; PPM, permanent
pacemaker. (Adapted from FM Kusumoto et al: Heart Rhythm 16:e128, 2019.)
FIGURE 250-4 Multifocal atrial tachycardia. Rhythm strip obtained from a patient with severe pulmonary disease during an acute illness. Arrows note three distinct P-wave
morphologies.
Atrial Fibrillation
1903CHAPTER 251
Acknowledgment
Gregory F. Michaud and William G. Stevenson contributed to this chapter in the 20th edition and some material from that chapter has been
retained here.
■ FURTHER READING
Brugada J et al: 2019 ESC Guidelines for the management of patients
with supraventricular tachycardia. The task force for the management
of patients with supraventricular tachycardia of the European Society
of Cardiology (ESC) developed in collaboration with the Association
for European Paediatric and Congenital Cardiology (AEPC). Eur
Heart J 41:655,2020.
Callans DJ: Josephson’s Clinical Cardiac Electrophysiology: Techniques
and Interpretations, 6th ed. Philadelphia, Wolters Kluwer, 2021.
Jalife J, Stevenson W (eds): Zipes and Jalife’s Cardiac Electrophysiology: From Cell to Bedside, 8th ed. Philadelphia, Elsevier, 2022.
PATHOPHYSIOLOGY AND EPIDEMIOLOGY
Atrial fibrillation (AF) is a cardiac arrhythmia characterized by seemingly disorganized, rapid, and irregular atrial electrical activation,
resulting in loss of organized atrial mechanical contraction. These
rapid and irregular electrical signals input into the atrioventricular
(AV) node, which determines ventricular activation and rate. The
conducted ventricular rate is variable, resulting in an irregular, usually
rapid ventricular rate, ranging typically between 110 and 160 beats/
min in most. In some patients, the sustained ventricular rate can
exceed 200 beats/min, whereas in others with either high vagal tone or
AV nodal conduction disease, the ventricular rate may be excessively
slow (Fig. 251-1).
251 Atrial Fibrillation
William H. Sauer, Paul C. Zei
I
II
III
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
I
II
III
aVR
aVL
aVF
V1
V2
V3
V4
V5
V6
FIGURE 251-1 Electrocardiogram of an irregularly irregular heart rhythm without discernable P waves. The disorganized atrial activation is best appreciated in lead V1
for this patient.
AF is the most common sustained arrhythmia; as a result, it is a
major public health issue. Prevalence increases with age, with >95%
of AF patients >60 years of age. The prevalence in humans over age
80 is ~10%. The lifetime risk of developing AF for men aged 40 years
old is ~25%. AF is slightly more common in men than women and
more common in whites than blacks. Risk factors for developing AF in
addition to age and underlying cardiac disease include hypertension,
diabetes mellitus, cardiac disease, family history of AF, obesity, and
sleep-disordered breathing. AF is not a benign condition, with a 1.5-
to 1.9-fold increased risk of mortality after controlling for underlying
cardiac disease. Perhaps the most important consequence of AF is a
significantly increased risk of stroke compared to the general population, causing ~25% of all strokes. The risk of dementia is increased in
patients with AF, as is the risk of MRI-detected asymptomatic embolic
infarct. AF, most often when ventricular rate remains uncontrolled for
prolonged periods, increases the risk of developing congestive heart
failure and cardiomyopathy. Moreover, as a corollary, patients with
underlying heart disease, in particular cardiomyopathy and congestive heart failure, are at higher risk for developing AF. AF is a marker
for worsened morbidity and mortality in patients with existing heart
disease, although the precise extent of the independent risk increase
associated with AF in heart disease is unclear. AF may, on occasion, be
associated with an identifiable precipitating factor, such as hyperthyroidism, acute alcohol intoxication, myocardial infarction, pulmonary
embolism, pericarditis, and cardiac surgery, where AF occurs in up to
30% of patients postoperatively.
AF is clinically most typically defined by the pattern of episodes.
Paroxysmal AF is defined as a pattern of AF episodes that occur
spontaneously and terminate with a relatively short duration, most
commonly defined as 7 days or less. Persistent AF refers to AF that
occurs continuously for >7 days but <1 year, whereas long-standing
persistent AF refers to AF that has been persistent for >1 year. These
descriptors for AF correlate with the underlying pathophysiology of
AF. AF tends to be a progressive condition, with, at this point, no definitive “cure” that will completely eliminate AF durably in a predictable
fashion. The pathophysiology of AF, however, remains incompletely
understood. Most data support a multifactorial process that leads to
the development of manifest AF. Clinical and epidemiologic studies
have demonstrated that, in addition to cardiovascular disease, obesity,
1904 PART 6 Disorders of the Cardiovascular System
hypertension, diabetes mellitus, and sleep-disordered breathing are
associated with higher risk of developing AF. The proposed pathophysiology suggests a “final common pathway” of these risk factors leading
to electrophysiologic changes in atrial tissues. Alterations in regulation
of membrane channels and other proteins result in abnormal electrical
excitability. Atrial tissues, in particular pulmonary vein musculature,
exhibit enhanced automaticity, resulting in ectopic beats (premature
atrial contractions), as shown in Fig. 251-2. Bouts of rapid atrial ectopy
may then initiate either atrial tachycardia or frank AF. Additional cellular and, eventually, tissue remodeling results in abnormal conduction
properties throughout the atria, including, in particular, shortening of
atrial tissue refractory periods. This enables sustained AF through a
combination of rapid automaticity-based “drivers” and areas of functional reentry. Further remodeling leads to the development of fibrosis
and left atrial enlargement (Table 251-1).
These functional and anatomic changes in atrial tissues appear to
correlate with the progression of clinical AF. AF tends to be a progressive disease in most, although exceptions occur. Typically, for a period
of time, patients experience sporadic ectopic beats, likely originating
from the pulmonary veins, preceding the onset of frank AF.
Other regions of the atria have been demonstrated to produce
ectopic depolarizations that may trigger AF; these include the muscular tissue sleeves within the superior vena cava, coronary sinus, or
the remnant of the vein of Marshall. When enough frequent bursts
of ectopic beats/tachycardia and/or changes in underlying substrate
support the maintenance of AF for short periods, the patient develops
episodes of paroxysmal AF. In the untreated patient, over time, as
electrical and remodeling continues to progress, episodes of paroxysmal AF may be prolonged to the point of not terminating spontaneously, the hallmark of persistent AF. After further remodeling,
not only do patients continue on to long-standing persistent AF but
Sinus
P wave
Blocked PAC PAC initiates AF
Sinus
P wave
25 mm/sec 10 mm/mV 0.5–40 Hz
FIGURE 251-2 Surface electrocardiogram (ECG) of atrial ectopy initiating atrial fibrillation (AF). In this single-lead surface ECG recording, the tracing begins with two
conducted sinus beats. A nonconducted premature atrial contraction (PAC) (labeled “blocked PAC”) is shown after the second QRS complex. After the next sinus P wave
and QRS, an ectopic beat (PAC) initiates atrial fibrillation, as demonstrated by (somewhat organized) erratic atrial activity and an irregular ventricular response.
TABLE 251-1 Categorization of Atrial Fibrillation (AF) by Clinical Temporal Characteristics and Associated Features
PAROXYSMAL AF PERSISTENT AF LONG-STANDING PERSISTENT AF
Definition Episodes self-terminate or via CV in <7 d Episodes do not self-terminate in <7 d Persistent AF >1 year
LA size Normal to mildly enlarged Mild to severely enlarged Typically, severely enlarged
LA scar burden Low Moderate High
Efficacy of AAD Often effective Not as effective Usually refractory
When to offer ablation? First-line therapy reasonable First-line appropriate but usually offered after
AAD failure
After AAD failure, not always a good
option
Ablation technique PV isolation alone usually effective PV isolation and any identified non-PV AF
source
PV isolation; additional ablation for
substrate modification likely needed
Note: With paroxysmal, persistent, and long-standing persistent AF, definitions are based on duration of events and diagnosis overall. These categorizations correlate with
LA size, LA scar burden, and resultant efficacy of medical and ablative therapies.
Abbreviations: AAD, antiarrhythmic drugs; CV, cardioversion; LA, left atrium; PV, pulmonary vein.
also the efficacy of therapeutic interventions to restore sinus rhythm
diminishes.
CLINICAL PRESENTATION AND
MANIFESTATIONS
The clinical manifestations of AF result from (1) symptoms related
to the irregular, often rapid but sometimes slow ventricular rates that
result; (2) the hemodynamic consequences of altered cardiac function;
(3) the consequences of cardioembolic phenomena; and/or (4) the
impact of AF on cardiovascular function over time. AF is diagnosed by
electrocardiogram (ECG), either by 12-lead standard ECG or limited
lead ambulatory monitor ECG, with findings of lack of organized atrial
activity (no P wave), with an irregular ventricular response. The role
of screening populations for AF is evolving with the use of wearable
monitors and home ECG capabilities.
With irregular, rapid ventricular rates, there is variable cardiac displacement and contraction, resulting in the sensation of palpitations
and awareness of the heartbeat, when of course, in a normal rhythm,
most humans do not sense each and every heartbeat. Interestingly,
many patients are, for the most part, unaware of the irregular ventricular beating for unknown reasons.
During AF, there is loss of the contribution of atrial systole to overall
cardiac output and, with irregular ventricular rates, variable ventricular
filling and, as a consequence, variable stroke volume. The resultant
impact on overall cardiac output may result in exercise intolerance,
fatigue, weakness, presyncope, or dyspnea. In patients with underlying
cardiac disease, the additional hemodynamic compromise resulting
from AF may result in exacerbation of the disease and/or symptoms.
Patients with hypertrophic cardiomyopathy, coronary artery disease,
heart failure with either depressed or preserved ejection fraction, or
amyloidosis are particularly susceptible. In patients with concomitant
Atrial Fibrillation
1905CHAPTER 251
AV nodal conduction disease, bradycardia during AF may result in
presyncope or syncope. Pauses at the time of spontaneous conversion
from AF to sinus rhythm, a manifestation of sinus node dysfunction
that commonly occurs in patients with AF, may result in presyncope
or syncope as well.
With the loss of atrial mechanical contraction, blood stasis may promote in situ thrombosis, which, when embolized, may result in a range
of clinical consequences, most importantly, ischemic stroke. Thrombus
formation occurs primarily in the left atrial appendage. Over time,
recurrent thromboembolism to the brain, even if asymptomatic, may
result in debilitating neurologic sequelae. An increased risk of dementia in patients with AF may be the consequence of this phenomenon.
In patients with prolonged periods of rapid ventricular rates
resulting from AF, there is risk of developing a tachycardia-induced
cardiomyopathy, with associated depressed left ventricular function.
Tachycardia-induced myopathy appears generally to be reversible once
ventricular rates are controlled. In patients with long-standing persistent AF, the atria, especially the left atrium, tend to be more dilated and
to contain a higher burden of fibrotic, noncontractile atrial tissue. More
recently, the hemodynamic consequences of a noncompliant, fibrotic
left atrium, including elevated left atrial filling pressures, volume
overload, and congestive heart failure, have been described as “stiff left
atrial syndrome.”
TREATMENT
Atrial Fibrillation
The treatment and management of the patient with AF centers on
three aims: (1) control of patient symptoms through a strategy of
rate control and/or rhythm control; (2) appropriate mitigation of
thromboembolism risk; and (3) addressing modifiable risk factors
for progression of AF. In the acute onset of AF, if significant hemodynamic compromise, pulmonary edema, or evidence of coronary ischemia is present, emergent cardioversion is recommended.
Electrical cardioversion can be achieved with a QRS synchronous
shock, preferably in a sedated patient, or via pharmacologic cardioversion, most typically with the intravenous administration of
the class III antiarrhythmic ibutilide. Ibutilide should be avoided
in patients with baseline prolonged QT interval or severe left ventricular dysfunction, given the risk of torsades des pointes. In the
hemodynamically stable patient with new-onset AF, therapy should
focus on control of ventricular rate to prevent hemodynamic sequelae, consideration of anticoagulation to mitigate thromboembolic
risk, and consideration of restoration and maintenance of sinus
rhythm—a so-called rhythm control strategy. If restoration of sinus
rhythm is being considered, a more immediate risk of thromboembolism must be factored into the management strategy. Although
there is a lack of definitive data, it is presumed that if the presenting
episode of AF is >48 h or if the episode duration is unknown, there
is risk for precipitating a thromboembolic complication through
cardioversion, whether electrical or pharmacologically achieved.
Therefore, in this circumstance, the patient should be either initiated on anticoagulation, with cardioversion deferred for at least
4 weeks after uninterrupted anticoagulation, or evaluated to exclude
the presence of left atrial appendage thrombus. Most commonly,
transesophageal echocardiography (TEE) is used to evaluate for left
atrial appendage thrombus, although computed tomography (CT)
angiography has been demonstrated to have excellent sensitivity
and specificity as well.
CARDIOVERSION AND ANTICOAGULATION
The major source of thromboembolism and stroke in AF is formation of thrombus in the left atrial appendage where flow is relatively
stagnant, although thrombus occasionally forms in other locations
as well. Following conversion from prolonged AF to sinus rhythm,
atrial mechanical function can be delayed for weeks, such that
thrombi can form even during sinus rhythm. When AF has been
present for >48 h and in patients at high risk for thromboembolism,
such as those with mitral stenosis or hypertrophic cardiomyopathy,
conversion to sinus rhythm is associated with an increased risk of
thromboembolism. Thromboembolism can occur soon or several
days after restoration of sinus rhythm if appropriate anticoagulation
measures are not taken.
Cardioversion within 48 h of the onset of AF is common practice
in patients who have not been anticoagulated, provided that they
are not at high risk for stroke due to a prior history of embolic
events, rheumatic mitral stenosis, or hypertrophic cardiomyopathy with marked left atrial enlargement. These low-risk patients
with occasional episodes of AF can be instructed to notify their
physician when AF occurs to arrange for cardioversion to be done
within 48 h.
If the duration of AF exceeds 48 h or is unknown, there is greater
concern for thromboembolism after cardioversion, even in patients
considered low risk (CHA2
DS2
-VASc of 0 or 1 [see below]) for
stroke. There are two approaches to mitigate the risk related to
cardioversion. One option is to anticoagulate continuously for
3 weeks before and a minimum of 4 weeks after cardioversion. A
second approach is to start anticoagulation and perform a TEE or
high-resolution cardiac CT scan to detect the presence of thrombus
in the left atrial appendage. If thrombus is absent, cardioversion
can be performed and anticoagulation continued for a minimum
of 4 weeks to allow time for recovery of atrial mechanical function.
In either case, cardioversion of AF is associated with a substantial
risk of recurrence, which may not be symptomatic. Longer-term
maintenance of anticoagulation is considered based on the patient’s
individual risk for stroke, commonly assessed using the CHA2
DS2
-
VASc score.
ACUTE RATE CONTROL
The goal of rate control in AF is to allow more diastolic filling
time, improving cardiac output and reducing patient symptoms.
In the longer term, adequate rate control will minimize the risk of
congestive heart failure and tachycardia-induced cardiomyopathy.
Acute rate control can be achieved with beta blockers and/or the
calcium channel blockers verapamil and diltiazem administered
either intravenously or orally, as warranted by the urgency of the
clinical situation. Digoxin has been used for many years for rate
control, particularly in patients susceptible to congestive heart
failure, because it lacks the negative inotropic effect seen in calcium
channel blockers and beta blockers. It acts synergistically with
beta blockers and calcium channel blockers and, therefore, may be
useful as an added agent when rate control is inadequate. However,
recent evidence suggests increased mortality with its use, and so its
utilization has declined.
CHRONIC RATE CONTROL
For patients who remain in AF chronically, the goal of rate control is to
both alleviate symptoms and prevent deterioration of ventricular function from excessive rates. β-Adrenergic blockers and calcium channel
blockers are often used either alone or in combination. Exertionrelated symptoms are often an indication of inadequate rate control.
Rate should be assessed with exertion and medications adjusted
accordingly. Adequate rate control is defined as a resting heart rate
of <80 beats/min that increases to <100 beats/min with light exertion, such as walking. If it is difficult to slow the ventricular rate to
that degree, allowing a resting rate of up to 110 beats/min is acceptable provided it does not cause symptoms and ventricular function
is normal; however, periodic assessment of ventricular function
is warranted because some patients develop tachycardia-induced
cardiomyopathy.
If adequate rate control in AF is difficult to achieve, further consideration should be given to restoring sinus rhythm (see below).
Catheter ablation of the AV junction to create permanent AV block
and implantation of a permanent pacemaker reliably achieve rate
control without the need for AV nodal–blocking agents, a so-called
“ablate and pace” strategy. These patients not only remain in AF but
also become dependent on the pacemaker to support ventricular
1906 PART 6 Disorders of the Cardiovascular System
rate. The typical pacing configuration with placement of a ventricular lead in the right ventricular apex may induce dyssynchronous
ventricular activation that can depress ventricular function in some
patients. Biventricular pacing or direct pacing of the His bundle or
left bundle branch may be used to minimize the degree of ventricular dyssynchrony.
STROKE PREVENTION IN ATRIAL FIBRILLATION
Thromboembolic complications, in particular, stroke, are the most
significant and potentially life-threatening sequelae of AF. Therefore, appropriate stroke prevention strategies are a key aspect of
AF management. The mainstay of stroke prevention is continuous
anticoagulation therapy, most commonly using an oral medication.
Specific patient populations have a high risk of stroke, including patients with hypertrophic cardiomyopathy, mitral stenosis,
and prior stroke history, and therefore, anticoagulation is recommended, barring contraindications. AF in patients without mitral
stenosis is commonly referred to as nonvalvular AF. In the majority
of patients with AF, the decision about whether a stroke prevention
regimen is indicated is largely based on an assessment of stroke
risk, balanced by the risk of the preventative therapy. The risk of
stroke appears to be most accurately predicted by the presence
of underlying risk factors known in increase stroke risk. The
CHA2
DS2
-VASc scoring system (Fig. 251-3) is a widely used tool
to estimate stroke risk. Anticoagulation is currently recommended
in the United States for patients with a score of ≥1, unless the lone
risk factor is female gender. Stroke risk increases with increasing
CHA2
DS2
-VASc score, such that annual stroke risk may be as high
as nearly 20% without anticoagulation. On the other hand, anticoagulation carries a risk of serious and potentially life-threatening
bleeding complications, in particular, intracranial hemorrhage and
gastrointestinal bleed. Bleeding risk is often assessed using the
HAS-BLED scoring system (Fig. 251-3). If bleeding risk is deemed
to be outweighed by stroke risk, anticoagulation is recommended.
It is important to note that the perceived burden of AF has not been
shown to predict stroke risk. The approach to patients with paroxysmal AF is therefore the same as for persistent AF. It is recognized
that many patients who appear to have infrequent AF episodes
based on office visits often have asymptomatic episodes that put
them at risk. Absence of AF during periodic monitoring is not sufficient to indicate low risk. The role of continuous monitoring with
implanted recorders or pacemakers as a guide for anticoagulation in
patients with a borderline risk profile is not clear.
The options for anticoagulation are the oral factor Xa inhibitors
apixaban, edoxaban, or rivaroxaban; the oral antithrombin inhibitor
dabigatran; and the vitamin K antagonist warfarin.
Antiplatelet agents alone are generally not sufficient. In nonvalvular AF, warfarin reduces the annual risk of stroke by 64%
compared to placebo and by 37% compared to antiplatelet therapy.
Patients with AF with an increased risk of stroke also have an
increased risk of venous thromboembolism, which appears to be
lower with oral anticoagulation. The direct-acting anticoagulants
dabigatran, rivaroxaban, apixaban, and edoxaban were noninferior
to warfarin in individual trials of nonvalvular AF patients, and
intent-to-treat analysis of pooled data suggests superiority to warfarin by small absolute margins of 0.4–0.7% in reduction of mortality,
stroke, major bleeding, and intracranial hemorrhage. Warfarin is
required for patients with rheumatic mitral stenosis or mechanical
heart valves. The newer, direct-acting anticoagulants have not been
tested in rheumatic heart disease, and a direct thrombin inhibitor
did not prevent thromboembolism in patients with mechanical heart
valves. Warfarin can be an inconvenient agent that requires several
days to achieve a therapeutic effect (prothrombin time [PT]/international normalized ratio [INR] >2), requires monitoring of PT/INR to
adjust dose, and has many drug and food interactions that can hinder patient compliance and render maintaining a therapeutic effect
challenging. The direct-acting agents are easier to use and achieve
reliable anticoagulation promptly without requiring dosage adjustment based on blood tests. Dabigatran, rivaroxaban, and apixaban
have renal excretion, cannot be used with severe renal insufficiency
(creatinine clearance <15 mL/min), and require dose adjustment
for modest renal impairment, which is of particular concern in the
elderly, who are at increased bleeding risk. Limited experience with
apixaban demonstrates safety and efficacy in patients undergoing
chronic hemodialysis for end-stage kidney disease. Excretion can
also be influenced by P-glycoprotein inducers and inhibitors. Warfarin anticoagulation can be reversed by administration of fresh frozen
plasma, prothrombin complex concentrate, and vitamin K. Reversal
agents are available for dabigatran (idarucizumab), and Xa inhibitors
are available (andexanet alfa), and both are administered intravenously. These agents may be pro-thrombotic and administration
must be judicious. The antiplatelet agents aspirin and clopidogrel are
inferior to warfarin for stroke prevention in AF and do not have less
risk of bleeding. Clopidogrel combined with aspirin is better than
aspirin alone for stroke prevention, but this combination is inferior
to warfarin and has a greater bleeding risk than aspirin alone.
Bleeding is the major risk of anticoagulation. Major bleeding
requiring transfusion and intracranial bleeding occur in ~1% of
patients per year with warfarin. Direct-acting anticoagulants appear
to have a lower risk of intracranial bleeding compared with warfarin
without sacrificing protective effects against thromboembolism.
Risk factors for bleeding include age >65–75 years, heart failure,
renal insufficiency, prior bleeding, and excessive alcohol or nonsteroidal anti-inflammatory drug use. In patients who require dual
antiplatelet therapy (e.g., aspirin and clopidogrel) after coronary
or peripheral arterial stenting, there is a substantially increased
bleeding risk when standard oral anticoagulation with warfarin or
a direct-acting anticoagulant is added. The optimal combination
of agents for patients with AF who also require antiplatelet therapy
remains unclear.
Chronic anticoagulation is contraindicated in some patients
due to bleeding risks. Because most atrial thrombi likely originate
CHA2DS2-VASc HAS-BLED
Risk Criteria
Congestive heart
failure
1 Hypertension 1
Age >75 2 Abnormal renal or liver
function
1 each
Hypertension 1 Bleeding diasthesis 1
Diabetes mellitus 1 Labile INR (on warfarin) 1
Prior stroke or TIA 2 Age >65 1
Vascular disease 1 Drugs or alcohol 1 each
Age >65 1
Sex category (F) 1
0
2
4
6
8
10
12
14
16
1 2 3 4 5 6
Annual Stroke or Major Bleeding Rate (%)
as a Function of Score
CHA2DS2-VASc HAS-BLED
FIGURE 251-3 CHA2
DS2
-VASc and HAS-BLED Systems. The CHA2
DS2
-VASc scoring
system gives a point for each outlined stroke risk factor, whereas the HAS-BLED
scoring system gives a point for each bleeding risk factor, as outlined in the table. In
the chart below the table, the corresponding risk of stroke (CHA2
DS2
-VASC) or major
bleed event (HAS-BLED) is plotted as a percent risk per annum as a function of
score. F, female; INR, international normalized ratio; TIA, transient ischemic attack.
Atrial Fibrillation
1907CHAPTER 251
in the left atrial appendage, surgical removal of the appendage,
combined with atrial maze surgery, may be considered for patients
undergoing surgery, although removal of the appendage has not
been unequivocally shown to reduce the risk of thromboembolism.
Percutaneously deployed devices that occlude or ligate the left atrial
appendage are also available, appear to be noninferior to warfarin in
reducing stroke risk, and are considered in patients who have a high
risk of thromboembolism but serious bleeding risk from chronic
oral anticoagulation (Table 251-2).
RHYTHM CONTROL
The decision to administer antiarrhythmic drugs or perform catheter ablation to attempt maintenance of sinus rhythm (commonly
referred to as the rhythm control strategy) is mainly guided by
patient symptoms and preferences regarding the benefits and risks
of therapies. In general, patients who maintain sinus rhythm have
better survival than those who continue to have AF. This may
be because continued AF is a marker of disease severity. In older
randomized trials, administration of antiarrhythmic medications
to maintain sinus rhythm did not improve survival or symptoms
compared to a rate control strategy, and the drug therapy group
had more hospitalizations. Disappointing efficacy and toxicities of
available antiarrhythmic drugs and patient selection bias may be
factors that influenced the results of these trials. Recently, a randomized trial evaluating an early rhythm control strategy (within
1 year of initial presentation) compared to standard rate control
demonstrated a reduction in cardiovascular events, including death
from cardiovascular causes and stroke. Differences between this
study and earlier randomized trials that failed to show a significant
difference in outcomes in rate versus rhythm control included the
use of catheter ablation and a high adherence rate to anticoagulation despite apparent rhythm control. In patients with heart failure
due to depressed left ventricular function, a catheter ablation–based
strategy to maintain sinus rhythm appears to provide mortality benefit compared with a medical rhythm control strategy. In a broader
population of patients with AF, a large, randomized, prospective
study comparing catheter ablation rhythm control medications
demonstrated a nonsignificant trend toward reduced hospitalizations and improved mortality, mostly driven by patients with heart
failure.
A rhythm control strategy is usually selected for patients with
symptomatic paroxysmal AF, recurrent episodes of symptomatic
persistent AF, AF with difficult rate control, and AF that has
resulted in depressed ventricular function or that aggravates heart
failure. A rhythm control strategy is more likely to be favored in
younger patients than in sedentary or elderly patients in whom rate
control is more easily achieved. Even if sinus rhythm is apparently
maintained, anticoagulation is recommended according to the
CHA2
DS2
-VASc stroke risk profile because asymptomatic episodes
of AF are common. Following a first episode of persistent AF, a
strategy using AV nodal–blocking agents, cardioversion, and anticoagulation is reasonable, in addition to addressing possible aggravating factors. If recurrences are infrequent, periodic cardioversion
is reasonable. However, if a patient has frequent symptomatic AF
despite rate control, then a rhythm control strategy incorporating
catheter ablation and/or antiarrhythmic medications is indicated.
Based on recent randomized trial data demonstrating superiority
of ablation over medications for maintenance of sinus rhythm and
benefits of an early rhythm control strategy, there is a trend toward
offering ablation earlier in the course of treatment, especially for
individuals with paroxysmal AF.
Pharmacologic Therapy for Maintaining Sinus Rhythm The goal
of pharmacologic therapy is to maintain sinus rhythm or reduce
episodes of AF. Risks and side effects of antiarrhythmic drugs are
a major consideration in selecting therapy. Drug therapy can be
instituted once sinus rhythm has been established or in anticipation of cardioversion. However, antiarrhythmic medications may
in some instances pharmacologically cardiovert the patient into
sinus rhythm. Therefore, an appropriate anticoagulation strategy
approach similar to electrical cardioversion is recommended, particularly at the time of initiation of therapy. β-Adrenergic blockers
and calcium channel blockers help control ventricular rate, improve
symptoms, and possess a low-risk profile, but have low efficacy for
preventing or terminating AF episodes. Class I sodium channel–
blocking agents (e.g., flecainide, propafenone, disopyramide) are
options for patients without significant structural heart disease, but
negative inotropic and proarrhythmic effects warrant avoidance
in patients with coronary artery disease or heart failure. The class
III agents sotalol and dofetilide can be administered to patients
with coronary artery disease or structural heart disease but have
~3% risk of inducing excessive QT prolongation and torsades des
pointes. Dofetilide should be initiated only in a hospital with ECG
monitoring, and many physicians take this approach with sotalol as
well. Dronedarone increases mortality in patients with heart failure
or long-standing persistent AF. All of these agents have modest
efficacy in patients with paroxysmal AF, of whom ~30–50% will
benefit. Amiodarone is more effective, maintaining sinus rhythm
in approximately two-thirds of patients. It can be administered to
patients with heart failure and coronary artery disease. However,
>40% of patients experience amiodarone-related toxicities during
long-term therapy, and thus, careful monitoring of potential toxicities, including liver, lung, and thyroid abnormalities, must be
accompanied with this therapy.
Catheter And Surgical Ablation for Maintaining Sinus Rhythm
Successful catheter ablation avoids antiarrhythmic drug toxicities,
but procedural risks and efficacy depend on operator experience.
For patients with previously untreated but recurrent paroxysmal
AF, catheter ablation has superior efficacy compared to antiarrhythmic drug therapy, and ablation is even more clearly superior to antiarrhythmic drugs for patients who have recurrent AF despite drug
treatment. Long-term control of AF is more difficult to achieve in
patients with persistent AF, likely because of more extensive atrial
abnormalities and associated greater comorbidities in these patients
(Fig. 251-4).
Catheter ablation involves percutaneous venous access (typically
via the femoral veins), trans(atrial) septal puncture, and radiofrequency ablation or cryoablation to electrically isolate the left atrial
regions around the pulmonary vein antra, abolishing the ability
of triggering foci in these regions to initiate AF and also likely
impacting the substrate for reentry in the left atrium. Extensive
areas of ablation are required, and gaps in healed ablation areas
TABLE 251-2 Novel Oral Anticoagulant Dosing
DABIGATRAN RIVAROXABAN APIXABAN EDOXABAN
Standard dose 150 mg bid 20 mg qd 5 mg bid 60 mg qd
Reduced dose 110 mg bid 15 mg qd 2.5 mg bid 30 mg qd
Dose reduction criteria Dabigatran 110 mg bid in patients
with: age ≥80 years, concomitant
use of verapamil, or increased
bleeding risk
Creatine clearance
15–49 mL/min
At least 2 of 3 criteria: age
≥80 years, body weight ≤60 kg,
or serum creatinine ≥1.5 mg/dL
(133 mol/L)
If any of the following: creatinine clearance
30–50 mL/min, body weight
≤60 kg, or concomitant use of dronedarone,
cyclosporine, erythromycin, or ketoconazole
Note: As of publication, four novel or direct oral anticoagulants are available and indicated for stroke prevention for atrial fibrillation. The standard dosing, reduced dosing,
and criteria for reduced dosing are shown for each agent.
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