Introduction

Atrioventricular nodal reentrant tachycardia (AVRNT) is the most common form of paroxysmal supraventricular tachycardia (PSVT). It occurs more frequently in women than in men, and the initial episode of tachycardia tends to occur at an older age than in patients with atrioventricular (AV) reentrant tachycardia. Patients frequently complain of regular rapid pounding in the neck due to almost simultaneous atrial and ventricular contractions. A review of 500 consecutive patients studied in the authors’ laboratory revealed a mean age of 47 ± 15 years (range, 16–87 years); 367 (73%) of these patients were females. Twenty-two patients (4.4%) presented with syncope. In 11 (2.2%), sustained AVNRT was induced during an electrophysiology study performed to investigate the cause of syncope. Syncope did not recur after elimination of the arrhythmia.

Most patients with AVNRT present with a narrow complex tachycardia and no visible P wave or with a P wave at the end of the QRS (pseudo-r′ in V ₁ or pseudo-S in II, III, aV _F ) simulating an incomplete right bundle branch block ( Fig. 21.1 ). However, the patient may have a preexisting bundle branch block ( Fig. 21.2 ) or develop a functional bundle branch block due to fast rates that are then maintained by the linking phenomenon. Rate-dependent aberrancy can occur in both the right and the left bundle branches. There are electrocardiographic (ECG) features that suggest AVNRT as follows: (a) pseudo s wave in inferior leads and/or pseudo r’ wave in V1; (b) notch in aVL; (c) no retrograde P waves visible during tachycardia; and (d) pseudo r’ wave in lead aVR; (e) notch in lead 1. The presence of pseudo-r’ in lead aVR appears to be more accurate than other ECG criteria in one study.

Twelve-lead electrocardiogram of a patient with atrioventricular nodal reentrant tachycardia (AVNRT) during tachycardia and tachycardia termination. A, AVNRT presenting as narrow complex tachycardia with a pseudo-r′ (filled arrow) . B, On termination of the tachycardia, the r′ is not present (open arrow) .

Twelve-lead electrocardiogram of a patient with atrioventricular nodal reentrant tachycardia and preexisting right bundle branch block and left anterior hemiblock.

Although most patients have no evidence of structural heart disease, AVNRT can also occur in patients with congenital or acquired heart disease. For example, in patients with an implantable cardiac defibrillator, AVNRT can result in inappropriate implantable cardioverter defibrillator therapies ( Fig. 21.3 ). Although a regular tachycardia is the most frequent presentation of AVNRT, some patients develop a regularly irregular tachycardia due to alternating antegrade or retrograde conduction through different slow AV nodal pathways. Even though the rhythm may appear irregular and resemble other arrhythmias, close inspection reveals that the short and long cycle lengths altersnate on a consistent basis ( Figs. 21.4 and 21.5 ). Although AVNRT can have a benign course, it can also result in disabling symptoms, especially in elderly patients in whom syncope may be the initial presentation. In addition, patients with AVNRT and coexisting intraventricular conduction disease may develop paroxysmal AV block due to the fast atrial rates ( Fig. 21.6 ).

Recurrent atrioventricular nodal reentrant tachycardia (AVNRT) in a patient with corrected transposition of the great vessels resulting in inappropriate implantable cardioverter defibrillator (ICD) therapies (antitachycardia pacing). A, During tachycardia, the P wave can be observed at the end of the QRS (arrows), which is not present after the tachycardia terminates spontaneously. B, Another episode of AVNRT is terminated by anti-tachycardia pacing therapy initiated by the patient’s ICD.

Leads I, II, and III showing a narrow complex tachycardia with alternating cycles lengths of 320 and 410 ms.

Intracardiac recordings corresponding to the same tachycardia shown in Fig. 21.4. Leads I, II, and V ₁ are depicted simultaneously with electrograms from the right atrial appendage (RAA), His bundle (HB), coronary sinus (CS), and right ventricle (RV). During electrophysiology study similar alternating cycle lengths were induced. Please note that the His bundle–atrial interval remain constant but the atrium–His bundle interval oscillates between a faster (190 ms) and a slower (260 ms) conduction over one or more antegrade slow atrioventricular nodal pathways.

Patient with left bundle branch block and recurrent syncope. Induction of atrioventricular nodal reentrant tachycardia repeatedly resulted in phase 3 or acceleration-dependent paroxysmal atrioventricular block due to block distal to the site where the His bundle (HB) electrogram (H) was recorded.

Catheter ablation eliminates AVNRT in most patients with a low risk of complications. Therefore it can be offered as a first-line therapy to symptomatic patients and to those who cannot tolerate or do not wish to take antiarrhythmic agents. In addition, patients with high-risk occupations may undergo catheter ablation as first-line therapy. This chapter focuses on the electrophysiology, diagnosis, and ablation of AVNRT and its variants. All forms of AV nodal reentry can be treated by a combined anatomic and electrogram-guided approach, to guide a safe and successful ablation.

Anatomy of the Atrioventricular Node and its Inputs

The anatomy of the AV node and its relationship with nearby atrial structures and with the His bundle were described in great detail by Tawara. The AV node is not a right-sided structure as depicted in most textbooks but is indeed a septal structure located in the AV septum that separated the left ventricle from the right atrium. It is in contact with both the right and the left atria. The AV node is not insulated from the surrounding myocardium as it occurs with the His bundle or the right bundle branch. Right-sided and left-sided inputs provide activation to the AV node proceeding from both atria. Histologically, the AV node is a discrete structure that can be traced in consecutive sections. It is constituted by specialized myocardium with characteristic immunohistochemistry expressing HCN ₄ , which is the major isoform of the funny channel. The compact AV node is located at the apex of the triangle of Koch. This triangle is bounded by the tendon of Todaro posteriorly, the ostium of the coronary sinus (CS os) inferiorly, and the septal leaflet of the tricuspid valve anteriorly. However, AV nodal tissue extends well beyond the compact AV node. AV nodal conduction is modulated by the sympathetic and parasympathetic nervous system. Therefore the ability to demonstrate fast and slow AV nodal pathways in the antegrade and retrograde directions varies depending on the autonomic tone. The right coronary artery provides the AV nodal artery in 90% of patients and may run in the subendocardium close to the CS os, which may explain the rare instances of AV nodal block during radiofrequency (RF) ablation in the area of the slow pathway, despite considerable distance from the compact AV node.

Pathophysiology

The fundamental studies by Gaskell, His, and Tawara a century ago form the basis for the present understanding of the anatomy and physiology of the AV node. Mines, in 1913, was the first to describe the existence of two regions in the specialized conduction system with different conduction and recovery properties. Moe and associates later demonstrated the existence of two AV nodal pathways underlying AVNRT. The fast AV nodal pathway (β pathway) was found to have a longer refractory period than the slow AV nodal pathway (α pathway). These different electrophysiologic properties facilitate the onset and maintenance of AVNRT. Mendez and Moe found that the two AV nodal pathways located in the upper portion of the AV node in the rabbit communicated with a final lower common pathway. Denes and associates were the first to document the presence of dual AV nodal pathways in patients with and without AVNRT. The initial reported prevalence (10%) of dual AV nodal pathways is low compared with present-day findings, probably because electrophysiology studies were initially performed without sedation and therefore under a predominant adrenergic tone. Now under sedation, dual AV nodal pathways are found in most patients, even in those without AVNRT. Dual AV nodal pathways can be uncovered using a single atrial extrastimulus of increasing prematurity ( Fig. 21.7 ) or during decremental atrial stimulation. A 50 ms jump in the atrium–His bundle (AH) interval, following a premature atrial extrastimulus, is considered the hallmark of dual AV nodal physiology. Nevertheless, the lack of a jump does not rule out the existence of two distinct AV nodal pathways. In this regard, a continuous AV nodal conduction curve is observed in a subgroup of individuals with inducible AVNRT.

Demonstration of dual atrioventricular (AV) nodal pathways. Single extrastimuli of progressively shorter coupling intervals were delivered from the right atrial appendage (RAA) at a basic drive of 600 ms. A jump or sudden increase of the atrium–His bundle interval from 120 ms (A) to 180 ms (B) occurs after shortening of the atrial extrastimulus from 300 to 290 ms. The atrial extrastimulus in (B) conducts through the slow AV nodal pathway, followed by retrograde conduction through the fast AV nodal pathway to activate the atrium (echo beat). A, Atrial electrogram; CS, coronary sinus; d, distal; H, His recording; HB, His bundle; p, proximal; RV, right ventricle.

Dual AV nodal physiology is a normal behavior of the human AV node. The response of the AV node to premature stimulation and to different cycle lengths indicates the presence of two or more populations of AV nodal or perinodal cells with different refractoriness and conduction times. As mentioned previously, the presence of dual AV nodal physiology in itself does not imply the presence of AVNRT. A common misconception is to look for dual AV nodal physiology when AVNRT is suspected and to search for another arrhythmia when a jump is not observed. This simplistic approach can prevent identification of the correct mechanism of the arrhythmia. Consistent with these observations, similar incidences of dual AV nodal physiology in patients with and without AVNRT were found. A jump of 50 ms or longer was present in 83% (417 of 500) of patients with AVNRT and in 77% (385 of 500) of patients without AVNRT (studied for other reasons); this difference was not statistically significant. The magnitude of the jump, however, was greater in patients with AVNRT (93 ± 7 vs. 61 ± 7 ms, P < .05). If dual AV nodal pathways are present in most individuals with or without AVNRT, what is required to induce AVNRT? One explanation may be the fact that the slow AV nodal pathways are slower in patients with AVNRT, as reflected by a greater jump in those with clinical arrhythmia. This may represent an increase of collagen with age, which is supported by experimental studies that facilitate the induction of AVNRT by creating lesions that prevent antegrade activation by the superior approach to the AV node in dogs. A longer conduction time over the antegrade slow pathway allows recovery of excitability of the retrograde limb (fast or slow AV nodal pathway). Anatomic differences may be important because a larger CS os is observed in most patients with AVNRT ( Fig. 21.8 ) and may allow for greater conduction time over the slow pathway.

Coronary sinus (CS) angiogram in a patient with slow–fast atrioventricular nodal reentrant tachycardia (AVNRT). Radiograph in the left anterior oblique (LAO) projection of the mapping catheters and angiogram of the CS performed with a pigtail catheter introduced through a preshaped long sheath. Arrows show the borders of the CS ostium. A larger CS ostium has been suggested as the anatomic substrate for greater conduction time in the slow pathway of patients with AVNRT. Multipolar catheters are positioned in the CS, right atrial appendage (RAA), His bundle (HB), and right ventricle (RV).

In fact, the proximal CS is significantly larger in patients with AVNRT than those with AVRT (14.1 ± 5 vs. 9.9 ± 2 mm, P < .0001). A cut off of proximal CS greater than 11.2 mm identifies AVNRT with a sensitivity of 92.6% and specificity of 76.9%.

The frequency of premature atrial or ventricular beats and the length of the excitable gap also modulate the frequency and duration of AVNRT. Finally, the coexistence of AVNRT with other arrhythmias, as well as occurrence of familial forms of AVNRT, suggests the possibility of an underlying abnormality.

Disagreement still exists regarding the nature and location of the slow and fast AV nodal pathways. The original mechanism that was advanced to explain this arrhythmia, is that these pathways represent longitudinal dissociation of conduction within the AV node itself. The most recent concept is that they represent different inputs to the AV node. Before the advent of surgical and catheter ablation, the slow and fast AV nodal pathways were believed to be part of the AV node, representing regions with different electrophysiologic properties (i.e., longitudinal dissociation). In fact, several experimental and clinical observations supported an intranodal location of these AV nodal pathways and the reentrant circuit supporting AVNRT. In some patients with AVNRT, atrial activation close to the AV node can be dissociated from the reentrant circuit without interruption of the tachycardia ( Fig. 21.9 ). This observation suggests that reentry confined to the AV node can sustain AVNRT without atrial involvement. Different degrees of ventriculoatrial (VA) block during AVNRT occur in the upper common pathway, allowing continuation of the tachycardia without retrograde atrial activation. In a similar fashion, the His–Purkinje system and the ventricles are not part of the reentrant circuit. This is demonstrated by episodes of 2:1 AV block with persistence of AVNRT ( Fig. 21.10 ). Block can occur either proximal or distal to His bundle activation. This block is functional and occurs in tachycardias with short cycle lengths, which find the His–Purkinje system refractory. As mentioned before, the presence of concurrent intraventricular conduction abnormalities may even result in paroxysmal AV block during AVNRT (see Fig. 21.6 ).

Induction of sustained slow–fast atrioventricular nodal reentrant tachycardia (AVNRT). Rapid atrial pacing at a cycle length of 320 ms results in sustained AVNRT following a critical prolongation of the atrium–His bundle interval (330 ms). The cycle length of the tachycardia was 360 ms. The third tachycardia complex fails to conduct to the atrium (arrows) without perturbation of the tachycardia. A, Atrial electrogram; CS, coronary sinus; d, distal; H, His recording; HB, His bundle; p, proximal; RAA, right atrial appendage; RV, right ventricle.

From Gonzalez MD, Contreras L, Cardona F, et al. V-A block during atrioventricular nodal reentrant tachycardia: reentry confined to the AV node. Pacing Clin Electrophysiol. 2003;26:775-778. With permission.

Slow–fast atrioventricular nodal reentrant tachycardia (AVNRT) with 2:1 conduction to the ventricles. At the top , a rhythm strip with the characteristic electrocardiographic manifestation of AVNRT with 2:1 atrial-to-ventricular conduction is shown. Negative P waves in inferior leads during tachycardia are the nonconducted atrial depolarizations. These P waves are located equidistant between QRS complexes. The ventricular cycle length in tachycardia doubles the atrial cycle length. Functional block during AVNRT (cycle length, 240 ms) occurs distal to His bundle activation (H) as shown in the lower panel . Because ventricular activation occurs almost simultaneously with retrograde atrial activation, the only visible P waves are the nonconducted ones. A, Atrial electrogram; CS, coronary sinus; d, distal; H, His recording; HB, His bundle; HRA, high right atrium; p, proximal; RV, right ventricle.

Earliest atrial activation during retrograde AV nodal conduction can occur in the upper or lower portion of the triangle of Koch, depending on whether the fast or the slow AV nodal pathway is activated. These observations and the results of surgical and catheter ablation of the anterior (superior) or posterior (inferior) approaches to the AV node led to the conclusions that the fast and slow AV nodal pathways have an extranodal component and that the atrium is required to sustain AVNRT. However, the portion of the atrium that is involved in the reentrant circuit remains elusive.

The original description of the AV node, made by Tawara in 1906, included posterior extensions of the AV node reaching both the mitral and tricuspid annuli. These observations were later confirmed by Becker, Inoue, and Anderson ( Fig. 21.11 ). More recently, we demonstrated the presence of a left atrial input to the AV node proceeding from the mitral annulus. This left atrial input to the AV node represents the electrophysiologic counterpart of the leftward extension of the AV node. Therefore in addition to the right-sided superior (anterior) and inferior (posterior) inputs to the AV node, the mitral annulus provides an independent input for activation proceeding from the left atrium (see Fig. 21.11 ). These inputs probably participate in the various forms of AVNRT by providing entrance and exit sites in a reentry that involves the atrium, or they may represent exit points from an intranodal circuit sustaining AVNRT. VA conduction over the slow pathway has been shown to result in earliest atrial activation on the left side of the interatrial septum, which is abolished with ablation of the slow pathway in the right atrium. Consistent with the clinical observation of intranodal reentry, different forms of AVNRT can be contained within the transitional cells of the posterior AV nodal input in a rabbit heart, owing to functional dissociation of cellular activation. Fig. 21.12 depicts possible reentrant circuits that are either contained in the compact AV node or involve the right- and left-sided inputs. As can be observed, there are multiple possible reentrant loops. Identifying the reentrant mechanism in a given patient can be difficult even with entrainment maneuvers.

A, Schematic representation of atrioventricular node (AVN) inside the triangle of Koch as viewed from the right anterior oblique (RAO) projection. The boundaries of the triangle of Koch are defined by the tendon of Todaro (TT), the tricuspid annulus (TA), and the ostium of the coronary sinus (CS). The superior, left inferior, and right inferior inputs are shown. B, Schematic representation of AVN as viewed from the left anterior oblique (LAO) projection. The AVN is shown above the CS along with the mitral annulus (MA) and the TA. The superior extension ( anterior in the old anatomic nomenclature) is in contact with both atria. The right inferior input is in contact with the CS. The left inferior input is in contact with the MA. ER, Eustachian ridge; FO, fossa ovalis; HB, His bundle; IVC, inferior vena cava; RA, right atrium; RV, right ventricle.

Modified from Gonzalez MD, Contreras LJ, Cardona F, et al. Demonstration of a left atrial input to the atrioventricular node in humans. Circulation. 2002;106:2930-2934. With permission.

Hypothetical reentrant circuits underlying different forms of atrioventricular nodal reentrant tachycardia (AVNRT). A, Reentry (broken lines) confined to different segments of the AV node without participation of the atria. B, Reentry involving atrial tissue and different segments of the compact AV node and its inputs. C, Reentry involving the musculature of the coronary sinus connecting both inferior inputs and the compact AV node. This circuit has been proposed to describe slow–fast AV nodal reentry. D, Reentry similar to that in C without involvement of the compact AV node. This circuit has been proposed to describe slow–slow and fast–slow AV nodal reentry. Within a given reentrant circuit, opposite wave fronts will give rise to different forms of AVNRT. CS, Coronary sinus; MA, mitral annulus; TA, tricuspid annulus.

Diagnosis

Three main forms of AVNRT are observed: slow–fast, slow–slow, and fast–slow AVNRT. In a single patient, one, two, or all three forms may be present at different times during the electrophysiology study. There is no electrophysiologic finding that alone is diagnostic of AVNRT; the diagnosis is made on the weight of typical features and the exclusion of atrial tachycardias, junctional tachycardia (JT), and septal accessory AV pathways using entrainment maneuvers. Electrophysiologic variables of different forms of AV nodal reentry are given in Table 21.1 .

An initial careful baseline electrophysiologic study is required before any ablation procedure. This is especially relevant for AVNRT because other supraventricular or ventricular arrhythmias may mimic this arrhythmia or coexist. The presence of a concealed accessory AV pathway should be ruled out before induction of the tachycardia by performing para-Hisian and differential ventricular pacing.

The electrophysiology study will demonstrate dual AV nodal physiology in approximately 85% of patients with AVNRT, but dual AV nodal physiology can also be observed in patients without AVNRT. Conversely, the absence of verifiable dual AV nodal physiology does not rule out AVNRT. The diagnostic criteria for dual AV nodal physiology are listed in Box 21.1 . Prolongation of the AH interval to more than 180 ms during decremental atrial pacing is usually indicative of conduction over the slow pathway. This frequently manifests as a paced PR interval greater than the PP interval such that the paced atrial depolarization conducts, not to the next QRS, but to the second QRS following the pacing stimulus ( Fig. 21.13 ).

Antegrade slow-pathway conduction during atrial pacing at 280 ms. The PR interval is 340 ms and therefore exceeds the PP interval. The stimulus conducts, not to the following QRS, but to the second QRS as indicated by the arrows . D, Distal; HRA, high right atrium; M, mid; P, proximal.

It has recently been stated that coronary sinus pacing can initiate AVNRT with a shorter critical AH interval compared with pacing from the right atrium. However, coronary sinus pacing is known to result in a shorter A H interval than right atrial pacing. This is because coronary sinus stimulation will depolarize the AV node via the left atrial input and also because the A H interval is dependent not only on AV nodal conduction but also on how activation reaches the AV node and how the atrium is close to the node.

During atrial extrastimulus testing, dual AV nodal physiology is typically manifested by a jump of 50 ms or longer in the A2H2 interval following a shortening in the A1A2 interval by 10 ms (see Fig. 21.7 ). When two atrial extrastimuli are delivered, a jump from fast to slow-pathway conduction is defined as an increase in the A3H3 interval of 50 ms or more in response to a decrement of 10 ms in the A2A3 interval (A1A2 being constant). The induction of AV nodal echo beats is an indication of dual AV nodal physiology. The diagnosis of retrograde dual AV nodal physiology is made based on jumps but is mainly dependent on changes of earliest atrial activation site ( Box 21.2 ). Retrograde His bundle–atrial (HA) interval jumps, and retrograde slow, antegrade fast AV nodal echo beats, may be seen. In addition, a change in the site of earliest retrograde atrial activation from near the His bundle area to the proximal CS region indicates a transition from retrograde fast pathway to retrograde slow-pathway conduction.

Induction of AVNRT is dependent on achieving a critical AH interval for typical slow–fast AVNRT; this requires exclusive antegrade slow-pathway conduction, which can be achieved by atrial extrastimulus testing or atrial burst pacing near the Wenckebach cycle length. If antegrade slow-pathway conduction cannot be achieved because short antegrade fast-pathway refractoriness, S ₃ stimulation, burst atrial pacing, or ventricular stimulation with or without isoproterenol may be required. If retrograde fast-pathway conduction is absent during ventricular pacing (VA block or earliest retrograde atrial activation at proximal CS) or by lack of echoes or AVNRT following antegrade slow-pathway conduction, isoproterenol infusion should be given. It is important to remember that retrograde block over the fast AV nodal pathway may be due to mechanical trauma of the fast pathway by the catheter recording His bundle activity, which can be minimized by advancing the catheter to the ventricle.

Slow–Fast Variant

The typical form, or slow–fast variant, occurred in 414 (83%) of 500 patients studied at the authors’ institution. Slow–fast AVNRT can be associated with other forms of AVNRT. For example, 3.5% of patients also had slow–slow AVNRT, 2% had fast–slow AVNRT, and in 1%, the three forms coexisted in the same patient.

The electrocardiogram obtained during tachycardia can suggest the diagnosis when the retrograde P wave is superimposed on the terminal portion of the QRS, giving rise to a pseudo-right bundle branch block pattern ( Fig. 21.14 ). As mentioned before, although most patients have a normal QRS, slow–fast AVNRT can also occur in patients with a wide QRS due to preexisting bundle branch block or rate-dependent functional AV block (see Fig. 21.2 ). The tachycardia cycle length (TCL) averaged 361 ± 59 ms in our patients (range, 235–660 ms).

Electrocardiogram during slow–fast atrioventricular nodal reentrant tachycardia. This tracing was obtained in a 76-year-old man with palpitations and syncope. Retrograde P waves at the end of the QRS complex in V ₁ give rise to a pseudo right bundle branch block pattern. The QRS also shows left ventricular hypertrophy and a left anterior fascicular block unrelated to the tachycardia.

The antegrade limb of the tachycardia is the slow AV nodal pathway, with an AH interval longer than 180 ms (range, 190–545 ms; mean, 312 ± 61 ms; see Table 21.1 ). A short VA (measured from the surface QRS to the earliest intracardiac atrial electrogram) time of less than 60 ms excludes reciprocating tachycardias using a concealed accessory pathway. However, atrial tachycardias with 1:1 AV conduction over the slow AV nodal pathway can have a short VA time, simulating AVNRT. The VA relationship during atrial tachycardia may change over time depending on the autonomic tone and facilitate the differential diagnosis. Induction of slow–fast AVNRT is usually accomplished by atrial extrastimuli or rapid atrial stimulation. Adrenergic stimulation (isoproterenol, 1–4 μg per minute) may be needed. Inducibility of AVNRT sometimes occurs only after the infusion of isoproterenol has been discontinued. Occasionally, atropine, 1 to 2 mg, with or without catecholamine infusion is necessary for AVNRT induction. Regardless of the maneuver used, induction of slow–fast AVNRT from the atrium requires antegrade block over the fast AV nodal pathway, with antegrade conduction over the slow AV nodal pathway allowing retrograde conduction over the fast AV nodal pathway. Less commonly, ventricular stimulation can also induce slow–fast AVNRT. Local atrial activation near the exit site of the fast AV nodal pathway (superior aspect of the triangle of Koch) can be recorded using closely spaced electrodes (see Fig. 21.15 and Fig. 21.16 ). The site of earliest retrograde atrial activation is critical to differentiate slow–fast from slow–slow AVNRT because the HA intervals can overlap in these two forms of tachycardia. In the studied population, the HA interval in the slow–fast form was 45 ± 11 ms (range, 25–145 ms). A contemporary conceptualization of the reentry circuit for slow–fast AVNRT is shown in Fig. 21.12C . In this model, retrograde atrial activation through the fast pathway activates both the left and right sides of the atrial septum. The wave front of right atrial activation fails to penetrate into the triangle of Koch because of block along the Eustachian ridge. The left atrial wave front, however, activates the CS myocardium and propagates to the CS os and inferior triangle of Koch between the os and the tricuspid valve. The wave front then ascends the atrial septum in the triangle of Koch to activate the fast pathway and complete the circuit. In this conceptualization, the right inferior extension comprises the anterograde slow pathway, and the fibers crossing the superior tendon of Todaro comprise the retrograde fast pathway. Ablation within the CS or left atrium is necessary when the left inferior extension or left atrial myocardium provides the critical portion to the reentry circuit rather than the right inferior extension.

Two examples of slow–fast atrioventricular (AV) nodal reentry. A, Atrial activation precedes ventricular activation during slow–fast atrioventricular nodal reentrant tachycardia. Using close bipolar electrodes, earliest atrial activation ( dotted lines ) recorded close to the proximal portion of the His bundle precedes ventricular activation. In the absence of these recordings, atrial activation would appear to be simultaneous to ventricular activation. B, Intracardiac electrograms recorded during slow–fast AV nodal reentry. The earliest atrial activity ( arrow ) is recorded on the His catheter and is approximated by the vertical line. Atrial activation in the coronary sinus (CS) is concentric. The tachycardia cycle length (TCL) is 350 ms, atrium–His bundle (AH) interval is 270 ms, and His bundle–atrial (HA) interval is 80 ms. D/d, Distal; H, His recording; HB, His bundle; HRA, high right atrium; M, mid; P/p, proximal; RAA, right atrial appendage; RV, right ventricle; RVA, right ventricular apex.

High-density mapping using a multipolar close electrodes catheter (PentaRay) of the triangle of Koch, proximal coronary sinus, and fossa ovalis during Slow-Fast AVNRT. The right atrium is viewed from the left lateral projection. Earliest retrograde atrial activation is recorded in the region of the fossa ovalis (FO), posterior to the site where the His bundle electrogram was recorded and the tendon of Todaro (not shown). HB, His bundle; TA, tricuspid annulus; CS, coronary sinus; JR, site where junctional rhythm was induced in sinus rhythm during RF energy delivery.

The response after ventricular overdrive pacing is an additional maneuver to support the diagnosis of AVNRT. During ventricular pacing with 1:1 V-A conduction and atrial entrainment, the VA interval is more than 85 ms longer than the corresponding VA interval during tachycardia. Upon cessation of ventricular pacing with tachycardia continuation, a VAV, ventricular-atrial-ventricular response is noted. In addition, the difference between the ventricular postpacing interval (PPI) and TCL is more than 115 ms. Correction of the PPI may be needed to account for rate-related prolongation of the return AH interval—Δ = [PPI – (AH return – AH supraventricular tachycardia) – TCL] ( Fig. 21.17 ). The HA interval is typically stable during tachycardia and after pacing maneuvers.

Correction of ventricular postpacing interval (PPI) for atrium–His bundle (AH) interval prolongation in the return cycle. Overdrive ventricular pacing that captures the atrium is terminated with continuation of a narrow complex tachycardia. The ventricular postpacing interval is long compared with the tachycardia cycle length (TCL) (difference > 115 ms) consistent with atrioventricular (AV) nodal reentry. The AH interval in the return cycle is prolonged (190 ms) compared with that in tachycardia (67 ms) because of concealed or decremental conduction in the AV node. After correction for this AH prolongation, the difference between the postpacing interval and the tachycardia cycle length is < 115 ms (57 ms), consistent with AV reciprocating tachycardia. The patient underwent successful ablation of a concealed posteroseptal pathway. CS, Coronary sinus; D, distal; HA, His bundle-atrial bundle; HRA, high right atrium; M, mid; P, proximal; RVA, right ventricular apex; SVT, supraventricular tachycardia.

To some extent, it is possible to dissociate both the atrium and the ventricle from the tachycardia. However, atrial or ventricular preexcitation will eventually advance AVNRT if His bundle activation is altered. AV block, either distal to His, or between the His and lower common pathway, is sometimes seen at the onset of tachycardia. Late ventricular extrastimuli introduced during His refractoriness will not perturb AVNRT, but those that are able to advance retrograde His bundle activation will preexcite the atrium and entrain the tachycardia.

Slow–Slow Variant

Slow–slow AVNRT occurred in 49 (10%) of the 500 patients with AVNRT. In this form of reentry, a slow AV nodal pathway is used as the antegrade limb, and another slow AV nodal pathway as the retrograde limb ( Fig. 21.18 ). Reentry using both the right and left inferior AV nodal inputs has been proposed. The electrocardiogram during tachycardia may show characteristic negative P waves in inferior and precordial leads, typical of earliest retrograde atrial activation in the proximal CS (see Fig. 21.18 ). This tachycardia can be induced by atrial or ventricular stimulation and frequently requires administration of isoproterenol. As previously mentioned, although the HA interval is usually longer than that recorded during slow–fast AVNRT, an overlap in the HA intervals between these two forms of AVNRT is frequently observed (see Table 21.1 ). In the patients studied, the ranges of HA during slow–slow and slow–fast AVNRT were 90 to 210 ms and 25 to 145 ms, respectively (see Table 21.1 ). The earliest site of retrograde atrial activation was found in the right atrium near the anterior edge of the CS os or just inside the CS (mean distance from the os, 1.5 ± 0.5 cm) ( Fig. 21.19 ). The earliest site of retrograde atrial activation near the CS os is what characterizes slow–slow AVNRT, and not the HA interval. In the series, the TCL was 411 ± 62 ms; the AH interval was 282 ± 71 ms; the HA interval was 141 ± 32 ms (range, 90–210 ms); and the shortest HA interval (measured at the earliest atrial activation site during tachycardia) was 85 ± 43 ms (see Table 21.1 ). Short HA intervals may also occur and are typically attributed to long conduction times in the lower common pathway, almost offsetting the longer HA times. Multiple slow pathways are often demonstrable with atrial extrastimulus testing. Neither the antegrade nor retrograde fast pathway is necessary for this reentrant circuit and therefore may be absent.

Slow–slow atrioventricular (AV) nodal reentry. Surface electrocardiogram showing slow–slow AV nodal reentry with the P wave in the ST segment. Panel A, the P wave is inverted in the inferior leads. Panel B displays surface electrocardiographic leads I, aVF, and V1 along with intracavitary electrograms. AH, Atrium–His bundle; AVNRT, atrioventricular nodal reentrant tachycardia; CS, coronary sinus; D, distal; HA, His bundle-atrial bundle; HRA, high right atrium; M, mid; P, proximal; RVA, right ventricular apex. Earliest retrograde atrial activation is recorded in the proximal coronary sinus ( arrow ).

Demonstration of a lower common pathway in atrioventricular (AV) nodal reentrant tachycardia using a retrograde slow AV nodal pathway. Left, The His bundle–atrial (HA) interval during tachycardia measured to the earliest atrial activation site in the proximal coronary sinus (CS 7) is 90 ms. Right, During ventricular stimulation at the tachycardia cycle length (345 ms), the HA interval is 140 ms, consistent with a common lower pathway distal to the reentrant circuit supporting the tachycardia. d, Distal; HBE, His bundle electrogram; m, mid; p, proximal; RAA, right atrial appendage.

From Curtis AB, Gonzalez MD. Supraventricular tachycardia. In: Naccarelli GV, Curtis AB, Goldschlager NF, eds. Electrophysiology Self-Assessment Program . Bethesda, MD: American College of Cardiology; 2000. With permission.

Characteristic of the slow–slow form of AVNRT is the presence of a lower common pathway. In other words, there is a portion of the AV node that is distal to, and not part of, the reentrant circuit that sustains the tachycardia. The presence of a lower common pathway is demonstrated by comparing the HA interval during tachycardia with the earliest atrial activation site, with the HA interval observed during ventricular pacing at the same cycle length as the tachycardia. In patients with slow–slow AVNRT, the HA interval during ventricular pacing (measured from the end of the His bundle deflection) is longer than that recorded during tachycardia (see Fig. 21.19 ).

As in the slow–fast form, preexcitation of the atrium during slow–slow AVNRT only follows ventricular extrastimuli that advance retrograde His bundle activation ( Fig. 21.20 ). However, because of the presence of a lower common pathway, retrograde His bundle activation needs to be advanced more than 15 ms before retrograde atrial activation is also advanced. By contrast, during AV reentrant tachycardia, late ventricular extrastimuli can advance retrograde atrial activation even when retrograde His bundle activation is not altered, as long as ventricular activation near the earliest atrial activation site is advanced. An atrial tachycardia with 1:1 AV conduction can be differentiated from AVNRT by comparing the sequence of atrial activation during tachycardia with that observed during ventricular pacing at a cycle length identical to that of the tachycardia. An atrial tachycardia has a different sequence of atrial activation than that observed during ventricular pacing with 1:1 VA conduction and may demonstrate a ventriculo-atrial-atrio-ventricular (VAAV) response after ventricular pacing. In patients with AVNRT and long retrograde conduction times, a pseudo-VAAV response may occur, suggesting the wrong diagnosis of atrial tachycardia ( Fig. 21.21 ). This happens when the retrograde VA interval exceeds the paced RR interval and atrial activation precedes ventricular activation during tachycardia.

Entrainment of slow–fast atrioventricular nodal reentrant tachycardia (AVNRT) using double ventricular extrastimuli. S ₁ peels back the refractory period of the right ventricle, which in turn allows S ₂ to capture the right ventricle and advances retrograde His bundle activation. This maneuver is frequently required in AVNRT with short cycle lengths in which the ventricular effective refractory period is reached before His bundle activation can be advanced. Note that S ₂ advances both retrograde His bundle and atrial activations with constant His bundle–atrial intervals (35 ms), consistent with absence of lower common pathway. The sequence of atrial activation following S ₂ is identical to that observed during tachycardia. CS, Coronary sinus; D, Distal; HB, His bundle; P, proximal; RAA, right atrial appendage; RV, right ventricle.

Paseudo VAAV (ventriculo-atrial-atrio-ventricular) response to the termination of ventricular overdrive pacing during atrioventricular nodal reentry. Because of very long retrograde conduction times, the atrial electrogram during ventricular pacing is associated, not with the preceding ventricular complex, but with two complexes before (arrows) . This pattern may be confused with the response of atrial tachycardia to ventricular overdrive pacing. HRA, High right atrium; M, mid; P, proximal; V, ventricular electrogram.

Fast–Slow Variant

The fast–slow form of AVNRT occurred in 37 (7%) of the 500 patients with AVNRT. Similar to slow–slow AVNRT, the complete reentry circuit is not fully understood. In fast–slow AVNRT, it is assumed that the fast AV nodal pathway is used as the antegrade limb and one or more slow AV nodal pathways as the retrograde limb, with the assumption that this arrhythmia is the reversal of the typical slow–fast circuit. However, this simplified concept has been challenged by the concept that fast–slow reentry may represent reentry within the right and left inferior AV nodal inputs but in a direction opposite to that of slow–slow AVNRT. The electrocardiogram during tachycardia may show a PR interval that is shorter than the RP interval (long-RP tachycardia) ( Fig. 21.22A ). The AH interval is less than 180 ms, with P waves inverted in inferior leads (see Table 21.1 ). The HA interval is longer than the AH interval because of retrograde conduction over the slow AV nodal pathway.

A, Electrocardiogram during fast–slow atrioventricular (AV) nodal reentrant tachycardia. Negative P waves in inferior and precordial leads are recorded before the QRS complexes with a PR shorter than the RP interval, giving rise to a long RP tachycardia pattern. B, Intracardiac electrograms recorded during fast–slow AV nodal reentry. Note that the earliest atrial activation (vertical dotted line and arrow) occurs at the proximal coronary sinus (CS P). The tachycardia cycle length (TCL) is 385 ms, the atrium–His bundle (AH) interval is 65 ms, and the His bundle–atrial (HA) interval is 320 ms. D, Distal; HRA, high right atrium; M, mid; RVA, right ventricular apex; TCL, tachycardia cycle length.

Similar to the slow–slow form, fast–slow AVNRT can be induced by atrial or ventricular stimulation, frequently during administration of isoproterenol. In some patients, AVNRT is induced only by ventricular stimulation. In addition, the presence of a lower common pathway results in an HA interval during tachycardia that is shorter than that observed during ventricular stimulation. Earliest retrograde atrial activation is close to the CS os ( Fig. 21.22B ). With forms of AV nodal reentry that have long RP intervals, the AH interval during atrial pacing at the TCL exceeds the AH interval in tachycardia by greater than 40 ms. For AV reciprocating tachycardias, the difference in the values of these intervals is 20 to 40 ms, and for atrial tachycardias, it is less than 20 ms.

Differential Diagnosis

The diagnosis of AVNRT requires exclusion of alternative mechanisms. These include AV reentry using a retrograde accessory pathway, atrial tachycardia, and JT ( Table 21.2 ). Orthodromic reciprocating tachycardia can be excluded when the VA time is less than 60 ms, which is common in slow–fast AVNRT. Exception to this rule is a slowly conducting accessory AV pathway in which the A follows not the preceding V, but the previous one. Another exception is an atrial tachycardia with 1:1 antegrade conduction in which the A occurs immediately after the previous V. During reentrant tachycardia, a critical maneuver to diagnose an accessory pathway participating as the retrograde limb is the entrainment technique. Whenever atrial activation is advanced without a change in the atrial activation sequence following a premature ventricular extrastimulus during His bundle refractoriness, a retrograde accessory pathway participating in the tachycardia is reliably diagnosed. If there is a change in the atrial activation sequence, an innocent bystander accessory pathway must be suspected. In response to ventricular overdrive pacing, orthodromic reciprocating tachycardia also produces a VAV response; however, the differences in VA times between pacing and tachycardia are less than 85 ms, and the PPI–TCL difference is less than 115 ms. A long return AH interval may invalidate this maneuver unless the correction is applied (see earlier discussion).

In sinus rhythm, para-Hisian pacing can clearly differentiate between retrograde conduction over the AV node versus retrograde conduction over an anteroseptal and midseptal accessory pathway. It should be remembered that para-Hisian pacing may fail to demonstrate retrograde conduction over accessory AV pathways located at other sites. VA times determined during pacing in sinus rhythm from the base and apex of the right ventricle can help to identify the presence of an accessory pathway. With this maneuver, pacing from the base of the right ventricle will produce a shorter VA time than apical ventricular pacing in the presence of an accessory pathway. By contrast, the VA times are shorter when pacing from the right ventricular apex when retrograde conduction occurs through the AV node.

It is critical to differentiate retrograde conduction over the AV node versus a para-Hisian accessory A V pathway before inducing tachycardia. It is important to determine whether there is retrograde conduction only over the AV node, only over an accessory A V pathway, or over both an accessory A V pathway and the AV node. In fact, both AVNRT and AVRT may coexist in the same patient.

Atrial tachycardias that originate in perinodal structures are not uncommon. Thus atrial activation sequence may be identical to that of slow–fast AVNRT. An atrial tachycardia can be diagnosed when there is variability in the HA interval during tachycardia. Ventricular pacing at a rate faster than the rate of the tachycardia typically accelerates the atrial rate to that of the pacing rate with concealed entrainment. After abrupt termination of the pacing train, the next beat of AVNRT typically occurs at a cycle length somewhat longer than that of the tachycardia owing to the presence of decremental slow-pathway conduction. However, the next beat typically has the same HA interval as during spontaneous tachycardia. By contrast, the postpacing HA interval for atrial tachycardias is typically different from that in tachycardia. The presence of a VAAV sequence of activation following rapid ventricular pacing suggests (but does not prove) an atrial tachycardia as the mechanism. However, it should be recognized that slow–slow and fast–slow AVNRTs are usually associated with this same response during transient entrainment when the VA interval exceeds the ventricular pacing cycle length (see Chapter 10 and Fig. 21.21 ). Atrial tachycardia has a VAAV–His–V response, whereas AVNRT may show a VA–His–AV response. In addition, the permanent form of junctional reciprocating tachycardia (PJRT) with a decrementally conducting retrograde accessory pathway usually has the same response (VAAV) to rapid ventricular pacing. The clear distinction between AVNRT and PJRT is made by the response to premature ventricular stimuli. Fast–slow AVNRT is not affected by appropriately timed ventricular extrastimuli unless retrograde His bundle activation is advanced, whereas during PJRT, the atrial activation may be either advanced or delayed when the V but not the His is advanced. For long RP tachycardias, comparing the AH intervals between tachycardia and atrial pacing at the TCL can differentiate among AVNRTs (difference, >40 ms), atrial tachycardia (difference, <20 ms), and reciprocating tachycardias (difference, >20 but <40 ms).

Differentiation of an accelerated junctional rhythm from slow–fast AVNRT may be difficult. Both tachycardias have a short and constant HA conduction interval with earliest retrograde atrial activation near the apex of the triangle of Koch (fast-pathway region, behind the tendon of Todaro). An automatic JT can be differentiated from AVNRT by the response to premature atrial contractions (PACs) introduced during or before AV junctional refractoriness ( Fig. 21.23 ). A PAC introduced during AV junctional refractoriness cannot penetrate to the automatic focus and therefore cannot alter the tachycardia. By contrast, a junctional refractory PAC may advance the following beat of tachycardia by conduction in the slow pathway in AVNRT. PACs introduced before AV junctional refractoriness may advance the immediately following beat and continue an automatic tachycardia but must terminate AVNRT because of collision of the antegrade PAC wave front and retrograde tachycardia wave front in the fast pathway.

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