Atrionodal Region

The AN region corresponds to the cells in the transitional region that are activated shortly after the adjacent atrial cells. Transitional cells are histologically distinct from both the cells of the compact AVN and the working atrial myocytes, and they are not insulated from the surrounding myocardium, but tend to be separated from one another by thin fibrous strands. Transitional cells do not represent conducting tracts but a bridge funneling atrial depolarization into the compact AVN via discrete AN inputs (approaches). AN approaches connect the working atrial myocardium from the left and right sides of the atrial septum to the left and right margins of the compact node, with wider extensions inferiorly and posteriorly between the compact node and the CS os and into the eustachian ridge. In humans and animals, two such AN inputs are commonly recognized in the right septal region: the anterior (superior) approaches, which travel from the anterior limbus of the fossa ovalis and merge with the AVN closer to the apex of the triangle of Koch; and the posterior (inferior) approaches, which are located in the inferoseptal RA and serve as a bridge with the atrial myocardium at the CS os. Although both inputs have traditionally been assumed to be RA structures, growing evidence supports the AV conduction apparatus as a transseptal structure that reaches both atria. A third, middle group of transitional cells has also been identified to account for the nodal connections with the septum and left atrium (LA).

Nodal Region

The N region corresponds to the region where the transitional cells merge with midnodal cells. The N cells represent the most typical of the nodal cells, which are smaller than atrial myocytes, are closely grouped, and frequently are arranged in an interweaving fashion. Sodium channel density is lower in the midnodal zone of the AVN than in the AN and NH cell zones. The inward L-type calcium current is the basis of the upstroke of the N cell action potential. The N cells are characterized by a less negative resting membrane potential and low action potential amplitude, slow rates of depolarization and repolarization, few intercellular connections (e.g., gap junctions), and reduced excitability compared with surrounding cells. Therefore conduction is slower through the compact AVN than the AN and NH cell zones. In fact, the N cells in the compact AVN appear to be responsible for the major part of AV conduction delay and exhibit decremental properties in response to premature stimulation because of their slow rising and longer action potentials. Fast pathway conduction through the AVN apparently bypasses many of the N cells by transitional cells, whereas slow pathway conduction traverses the entire compact AVN. Importantly, the recovery of excitability after conduction of an impulse is faster for the slow pathway than for the fast pathway, for reasons that are unclear.

Nodal-His Region

The NH region corresponds to the lower nodal cells, typically distal to the site of Wenckebach block, connecting to the insulated penetrating portion of the HB. The action potentials of the NH cells are closer in appearance to the fast-rising and long-action potentials of the HB.

Differences Between the Fast and Slow Pathways

The fast and slow pathways exhibit different electrophysiological (EP) properties. In general, the fast pathway demonstrates faster conduction velocity but longer refractory periods than the slow pathway. However, many exceptions exist.

The fast pathway forms the normal physiological conduction axis, and the atrial–His bundle (AH) interval during conduction over the fast pathway is usually no longer than 220 milliseconds. Longer AH intervals can be caused by conduction over the slow pathway.

Furthermore, the AVN dual pathways are greatly influenced by changes in the sympathovagal balance. Sympathetic stimulation shortens conduction time and refractoriness, whereas vagal stimulation provides the opposite effect. However, the relative extent of these effects on the two pathways can be different, which can potentially cause conduction to shift from one pathway to the other. An increase in vagal tone preferentially prolongs the effective refractory period (ERP) of the fast pathway compared to the slow pathway. Adrenergic stimulation tends to shorten the anterograde and retrograde ERP of the fast pathway to a greater extent than that of the slow pathway. Conversely, beta-blockers tend to prolong ERP of the fast pathway more than that of the slow pathway. Notably, adenosine produces differential effect on anterograde and retrograde conduction over the different AVN pathways. The effect of adenosine seems to be far less potent on retrograde fast pathway conduction than on the retrograde slow pathway and anterograde fast and slow pathway conduction. The mechanism of adenosine resistance of retrograde fast pathway conduction (both in patients with slow-fast AVNRT and in normal subjects) remains unclear.

Investigators used several approaches to identify the location of the atrial input of AVN pathways involved in the AVNRT circuit. The pathway serving as the retrograde limb of an AVNRT circuit can be identified by mapping the site of earliest retrograde atrial activation during AVNRT. The anterograde limb of the AVNRT circuit can be identified by using the resetting response to late-coupled atrial extrastimulation (AES); the site where the AES (with the longest coupling interval) resets the tachycardia identifies the anterograde limb. Atrial entrainment of AVNRT can also identify the anterograde limb of the reentry circuit; the site of the shortest stimulus-to-His interval with a postpacing interval (PPI) equal to the tachycardia cycle length (TCL) identifies the location of the atrial input to the anterograde pathway. Several studies demonstrated that slow pathways with longer conduction times frequently have a more inferior location in the triangle of Koch when compared with locations producing shorter AH intervals. However, atypical locations of those pathways are not infrequent.

Fast Pathway

Typically, a single fast pathway is identified in normal subjects and in patients with AVNRT. During retrograde fast pathway conduction, the earliest retrograde atrial activation is typically recorded at the apex of the triangle of Koch (superior to the compact AVN, at the same site recording the proximal His potential). However, detailed mapping localized the earliest site of atrial activation to the anterior interatrial septum posterior to the tendon of Todaro and eustachian ridge (outside the triangle of Koch, at a level approximately 10 mm inferior to the level recording the proximal HB potential).

Slow Pathways

Data suggest the presence of several slow pathways that can potentially participate in various forms of AVNRT, either as the anterograde or retrograde limbs of the reentry circuit. The slow pathway most commonly incorporated in the AVNRT circuit is formed by the rightward inferior AVN extension (and its corresponding AN approaches), which travels in the triangle of Koch between the tricuspid annulus and the CS os and connects selectively to the floor of the CS os. The earliest atrial activation during retrograde conduction over this pathway is typically located at the inferior aspect of the triangle of Koch, close to the CS os. The second most commonly used slow pathway is formed by the leftward inferior AN extension, which travels within the myocardial coat of the proximal CS leftward (transseptally) toward the left inferoseptal region and mitral annulus. An eccentric activation sequence in the CS is observed during retrograde conduction over this pathway, with the earliest activation site at the roof of the proximal CS (1 to 3 cm from the CS os). Two other slow pathways (inferolateral left atrial pathway and anteroseptal pathway) have been described but are less frequently observed. The earliest retrograde atrial activation is located close to the inferolateral mitral annulus in the LA (for the inferolateral left atrial slow pathway) or the anterior atrial septum, close to the proximal HB (for the anteroseptal slow pathway).

Multiple slow pathways (as demonstrated by multiple discontinuities in the AVN function curves; see later) are present in up to 14% of patients with AVNRT, although not all these pathways are involved in the initiation and maintenance of AVNRT. For example, an eccentric CS activation pattern has been reported frequently (14% to 80%) among patients with atypical forms of AVNRT. Whether the retrograde left-sided AN connection constitutes the critical component of the reentrant circuit or is only an innocent bystander in atypical AVNRT with the eccentric CS activation pattern remains controversial. It may be possible for both the leftward and rightward extensions, either together or separately, to participate in AVN reentry. Right-sided ablation is probably sufficient for most of these patients. However, in some patients, the slow pathway participating in the reentrant circuit cannot be ablated from the posteroseptal RA or the CS os, and requires ablation along the roof of the CS, as much as 5 to 6 cm from the CS os, or mitral annulus.

Upper Turnaround Point

Based on rare cases of dissociation of atrial activation from the tachycardia (e.g., persistence of AVNRT during different patterns of ventriculoatrial [VA] block or during AF) and on similarities between fast-slow AV conduction and longitudinal-transverse conduction in nonuniform anisotropy, early studies proposed that AVNRT results from reentry within the compact AVN (i.e., subatrial) secondary to functional longitudinal dissociation within the AVN into fast and slow pathways. Those studies suggested the presence of an upper common pathway, at least in a subset of patients.

However, current evidence, derived from histological studies, computer modeling, multielectrode recordings, and optical mapping, supports the role of perinodal atrial myocardium and suggests that the fast and slow pathways involved in the reentrant circuit of AVNRT represent conduction over different AN connections, thus making at least a small amount of atrial tissue a necessary part of the reentrant circuit (see Video 17.1 ). The common presence of multiple atrial breakthroughs, and the frequent changes in timing and location of retrograde activation without significant alteration in AVNRT cycle, argues against the existence of an “upper common pathway” or a focal atrial exit site from the AVNRT circuit in the majority of patients.

Lower Turnaround Point

The AVNRT circuit does not involve the ventricles; however, the location of the lower turnaround point of AVN reentry relative to the HB has been controversial. There is good evidence that the distal junction of the slow and fast pathways is located in the AVN, with the existence of a region of AVN tissue extending between the distal junction of the two pathways and the HB (called the “lower common pathway”), at least in a subset of patients.

The existence of a lower common pathway was proposed to explain several observations, including (1) AV block occurring without interruption of AVNRT and without recording of a His electrogram; (2) ventricular extrastimulation (VES) during AVNRT prematurely depolarizing the HB without affecting the tachycardia; (3) AES during AVNRT resulting in changes in the relative activation of HB and atrium (i.e., varying His bundle-atrial [HA] intervals); and (4) the HA interval during ventricular pacing at the TCL is longer than that during AVNRT.

The HA interval (measured from the end of the His potential to the earliest atrial activation in the HB recording, assuming stable activation sequence) during ventricular pacing represents a true conduction time between the HB and atrium. In the presence of a lower common pathway, the HA interval during AVNRT represents the relative activation times between the HB and junctional atrium, since the reentrant wavefront travels retrogradely up an AVN pathway to activate the atrium, while at the same time propagating down the lower common pathway to activate the HB (i.e., the HA is a “pseudo-interval”). Consequently, in the presence of a lower common pathway between the AVNRT circuit and HB recording site, the HA during AVNRT is expected to be shorter than that during ventricular pacing. The difference between the two HA intervals (ΔHA interval) is proportional to the length of the lower common pathway.

However, these phenomena can be interpreted in ways that do not involve the presence of a common pathway. For example, the first two phenomena assume that the recorded “proximal HB” potential corresponds to the actual “proximal end of the HB,” which is probably inaccurate in many cases. Hence, those phenomena also can be explained by intra-Hisian block occurring beyond the site of HB recording rather than in a “lower common pathway.” Furthermore, the last two phenomena assume that retrograde conduction follows the same pathway during pacing and tachycardia, and the difference between the HA interval during tachycardia and that during ventricular pacing at the TCL was assumed to reflect the conduction time over the lower common pathway. On the contrary, mapping studies have demonstrated that the breakthrough of atrial activation during AVNRT is frequently slightly discordant from that observed during ventricular pacing. Hence, relying on the measuring the HA interval from the same recoding sites, rather than detailed mapping for the true site of “earliest” atrial activation, may not be accurate.

Typical (Slow-Fast) Atrioventricular Nodal Reentrant Tachycardia

Retrograde conduction.

Typical AVNRT uses the fast pathway for retrograde conduction. During slow-fast AVNRT, the earliest retrograde atrial activation is usually recorded at the anterior interatrial septum posterior to the tendon of Todaro, close to the apex of the triangle of Koch ( Fig. 17.2 ).

Surface Electrocardiogram and Endocardial Recordings of the Different Types of Atrioventricular Nodal Reentrant Tachycardia (AVNRT).

The dashed line marks the site with the earliest atrial activation. In slow-fast (typical) AVNRT, the initial site of atrial activation is usually recorded in the His bundle (HB) catheter. In slow-slow AVNRT, the P wave lies outside the QRS in the ST-T wave, and the RP interval is longer than that in slow-fast AVNRT. The earliest retrograde atrial activation is usually in the inferoposterior part of the triangle of Koch. Slow pathways with longer conduction times have a more inferior location in the triangle of Koch. In fast-slow AVNRT, the earliest site of retrograde atrial activation is usually recorded at the base of the triangle of Koch or coronary sinus ostium. An eccentric retrograde atrial activation sequence with the earliest retrograde activation site inside the CS can be observed in atypical fast-slow AVNRT. CS _dist , Distal coronary sinus; CS _prox , proximal coronary sinus; HRA , high right atrium; RVA , right ventricular apex.

Importantly, retrograde atrial activation has been mapped to the inferior triangle of Koch, the roof of the CS (1 to 3 cm from the CS os), or the left side of the septum in up to 9% of patients ( Fig. 17.3 ). These forms of AVNRT were considered variants of slow-fast AVNRT with an inferior exit for the retrograde fast pathway. More recently, however, those AVNRTs with earliest retrograde atrial activation outside the traditional location of the fast pathway (formerly described as “posterior” or “leftward inferior extension” or “left variant” slow-fast AVNRT) have been considered as a variant “slow-slow AVNRT.” In the latter setting, two slow pathways (the right and left inferior AVN extensions) are used in the AVNRT circuit. The very short (and occasionally negative) HA interval observed during tachycardia, despite retrograde conduction over a slow pathway, could be explained by the presence of a relatively long lower common pathway. Retrograde conduction over the slow pathway with simultaneous bystander conduction over the lower common pathway (from the distal junction of the two slow pathways to the HB) results in simultaneous atrial and ventricular activation and shortening of the recorded HA interval, which mimics slow-fast AVNRT. Older patients (>60 years) often have longer conduction times over the retrograde fast pathway, resulting in HA intervals similar to those in slow-slow AVNRT, but still with the earliest atrial activation at the tendon of Todaro.

Retrograde Atrial Activation During Typical Atrioventricular Nodal Reentrant Tachycardia.

Sinus rhythm is shown on the left, slow-fast atrioventricular nodal reentrant tachycardia is shown in the center, and ventricular pacing during sinus rhythm appears on the right. The dashed line denotes earliest atrial activation (proximal CS, near ostium), significantly before the His bundle atrial activation (most visible during ventricular pacing). CS _dist , Distal coronary sinus; CS _prox , proximal coronary sinus; His _dist , distal His bundle; His _mid , middle His bundle; His _prox , proximal His bundle; HRA , high right atrium; RV , right ventricle; SVT, supraventricular tachycardia.

Atypical (Fast-Slow) Atrioventricular Nodal Reentrant Tachycardia

Atypical (Slow-Slow) Atrioventricular Nodal Reentrant Tachycardia

As the name implies, the reentrant circuit in slow-slow AVNRT uses two slow pathways (the right and left inferior AVN extensions). These patients often exhibit multiple AH interval jumps during AES testing, which is consistent with multiple slow pathways.

Catheter Ablation

Once it is decided to initiate treatment for AVNRT, the question arises whether to initiate pharmacological therapy or to use catheter ablation. Because of its high efficacy (>95%) and low incidence of complications, catheter ablation has become the preferred therapy over long-term pharmacological therapy and can be offered as an initial therapeutic option. It is reasonable to discuss catheter ablation with all patients suspected of having AVNRT. However, patients considering radiofrequency (RF) ablation must be willing to accept the risk, albeit low, of AV block and pacemaker implantation.

Pharmacological Therapy

For patients with AVNRT who are not candidates for, or prefer not to undergo, catheter ablation, long-term pharmacological therapy can be effective in 30% to 60% of patients. Most pharmacological agents that depress AVN conduction (including beta-blockers and calcium channel blockers) can reduce the frequency of recurrences of AVNRT. If those agents are ineffective, class IC (flecainide or propafenone in patients without structural or ischemic heart disease) or class III antiarrhythmic agents (sotalol or dofetilide) may be considered. Given the potential adverse effects of digoxin and amiodarone, these agents are generally reserved as last-resort therapy.

Outpatients may use a single dose of verapamil, diltiazem, or propranolol to acutely terminate an episode of AVNRT. This so-called pill-in-the-pocket approach (i.e., administration of a drug only during an episode of tachycardia for the purpose of termination of the arrhythmia when vagal maneuvers alone are not effective) is appropriate to consider for patients with infrequent episodes of AVNRT that are prolonged but well tolerated, and it obviates exposure of patients to long-term and unnecessary therapy between rare arrhythmic events. This approach necessitates the use of a drug that has a short onset of action (i.e., immediate-release preparations). Candidate patients should be free of significant LV dysfunction, sinus bradycardia, and preexcitation. Single-dose oral therapy with diltiazem (120 mg) plus propranolol (80 mg) has been shown to be superior to both placebo and flecainide in terminating AVNRT.

Two Families of PR Intervals

A shift of anterograde conduction from the fast pathway to the slow pathway can manifest as sudden prolongation of the PR interval, and vice versa ( Fig. 17.6 ). This shift can occur spontaneously and result in alternans of the PR interval (i.e., long and short PR intervals alternate with each other) or manifest as two families of PR intervals (short and long), with sudden and sustained prolongation or shortening of the PR interval that can be observed on different occasions. The shift also can be precipitated by a change in autonomic tone or by a PAC or a PVC that causes conduction block or concealment in one pathway and allows conduction over the other ( Fig. 17.7 ).

Dual Atrioventricular Node Physiology Manifesting as Two Different PR Intervals During Normal Sinus Rhythm.

Note that the shift in atrioventricular conduction from the fast to the slow atrioventricular node pathway (arrow) occurs without any changes in the sinus cycle length (680 milliseconds). This phenomenon indicates that the fast pathway anterograde effective refractory period is long relative to the sinus cycle length. AH , Atrial–His bundle.

Dual Atrioventricular Node Physiology.

Sinus rhythm with atrioventricular conduction over the slow pathway and long PR and AH intervals (to the left). After a premature ventricular complex (PVC) that results in concealed retrograde conduction into the slow pathway, anterograde atrioventricular conduction shifts from the slow pathway to the fast pathway with sudden shortening of the PR interval. AH , Atrial–His bundle; CS _dist , distal coronary sinus; CS _prox , proximal coronary sinus; HRA , high right atrium; RVA , right ventricular apex.

Dual Ventricular Response to a Single Supraventricular Beat

Rarely, a single atrial impulse (e.g., PAC) can conduct simultaneously along the slow and fast pathways, producing two QRS complexes (“double fire”). The reverse can also occur, with two atrial impulses from one ventricular complex.

Rapid Ventricular Rates During Atrial Fibrillation

Ventricular rates during AF can exhibit a bimodal distribution of R-R intervals on Holter recordings. The shorter R-R intervals (the faster ventricular rates) are believed to be a result of conduction over the slow pathway (because of its shorter refractory periods), while the fast pathway mediates relatively slower ventricular rates. Ablation of the slow AVN pathways in these patients can potentially eliminate the fast ventricular rates and produce a unimodal R-R interval distribution.

P Wave Morphology

In typical (slow-fast) AVNRT, the P wave is usually not visible because of the simultaneous atrial and ventricular activation. The P wave can distort the initial portion of the QRS (mimicking a q wave in the inferior leads), lie just within the QRS (inapparent), or distort the terminal portion of the QRS (mimicking an s wave in the inferior leads or a terminal r wave in lead V1) ( Fig. 17.8 ). When apparent, the P wave is significantly narrower than the sinus P wave, and is negative in the inferior leads, findings that are consistent with concentric retrograde atrial activation over the fast AVN pathway. In atypical AVNRT, the P wave is relatively narrow, negative in the inferior leads, and positive in lead V1 (see Fig. 17.8 ). Compared to orthodromic AVRT using a posteroseptal BT, the retrograde P waves in slow-slow AVNRT are more negative in lead aVF (>0.16 mV negative amplitude).

Electrocardiogram Morphology of the Different Types of Atrioventricular Nodal Reentrant Tachycardia (AVNRT) .

Arrows mark the P waves. In slow-fast (typical) AVNRT, the P wave may lie within the QRS (invisible, first panel ) or distort the terminal portion of the QRS (mimicking an r wave in lead V1, second panel ). In slow-slow AVNRT, the P wave lies outside the QRS in the ST-T wave, and the RP interval is longer than that in slow-fast AVNRT. In fast-slow AVNRT, the P wave lies before the QRS with a long RP interval. In all varieties of AVNRT, the P wave is relatively narrow, negative in the inferior leads, and positive in lead V1.

QRS Morphology

The QRS morphology during AVNRT is usually the same as in normal sinus rhythm (NSR). The development of prolonged functional aberration during AVNRT is uncommon, and it usually occurs following the induction of AVNRT by ventricular stimulation more frequently than by atrial stimulation, or following the resumption of 1 : 1 conduction to the ventricles after a period of block below the tachycardia circuit. At times, alternans of QRS amplitude can occur when the tachycardia rates are rapid. Occasionally, AVNRT can coexist with ventricular preexcitation over an AV BT, whereby the BT is an innocent bystander.

P-QRS Relationship

In typical (slow-fast) AVNRT, the RP interval is very short (−40 to 75 milliseconds). Variation of the P-QRS relationship with or without block can occur during AVNRT, especially in atypical variants of the tachycardia. This phenomenon usually occurs when the conduction system and the reentry circuit are unstable during initiation or termination of the tachycardia, which is likely secondary to decremental conduction in the lower common pathway. The ECG manifestation of P-QRS variations with or without AV block during tachycardia, especially at the initiation of tachycardias or in cases of nonsustained tachycardias, can be misdiagnosed as atrial tachycardias (ATs). Moreover, the variations can be of such magnitude that long RP tachycardia can masquerade for brief periods of time as short RP tachycardia.

Usually, the A/V ratio during AVNRT is equal to 1; however, 2 : 1 AV block can be present because of a block below the reentry circuit (usually below the HB and, infrequently, in the lower common pathway). In such cases, narrow, inverted P wave morphology in the inferior leads inscribed exactly between QRS complexes strongly suggests AVNRT ( Fig. 17.9 ). The incidence of reproducible sustained 2 : 1 AV block during induced episodes of AVNRT is approximately 10%. Rarely, VA block can occur because of a block in an upper common pathway; however, some of these cases may represent reentry using a retrogradely conducting nodofascicular or nodoventricular pathway with intranodal block above the level of the circuit ( see Chapter 19 ).

Typical Atrioventricular Nodal Reentrant Tachycardia With Intermittent 2 : 1 Atrioventricular (AV) Block.

His potential (H) is observed following conducted atrial impulses, but not after blocked atrial impulses, thus indicating AV block in the lower common pathway or in the portion of the His bundle proximal to the recording site. Note that intermittent AV block results in long-short cycle sequences associated with a right bundle branch block (RBBB) pattern during complexes conducted following a short cycle. RBBB is also observed intermittently during supraventricular tachycardia with 1 : 1 AV conduction. Note the lack of effect of RBBB on the tachycardia cycle length (A-A interval) or ventricular-atrial interval. CS _dist , Distal coronary sinus; CS _prox , proximal coronary sinus; HRA , high right atrium; RVA , right ventricular apex.

In atypical (fast-slow) AVNRT, the RP interval is longer than the PR interval. In slow-slow AVNRT, the RP interval is usually shorter than, and sometimes equal to, the PR interval. Occasionally, the P wave is inscribed in the middle of the cardiac cycle, thus mimicking AT with 2 : 1 AV conduction (see Fig. 17.2 ). Slow-slow AVNRT can be associated with RP intervals and P wave morphology similar to that during orthodromic AVRT using a posteroseptal AV BT. However, although both SVTs have the earliest atrial activation in the posteroseptal region, conduction time from that site to the HB region is significantly longer in AVNRT than in orthodromic AVRT. The results are a significantly longer RP interval in lead V1 and a significantly larger difference in the RP interval between lead V1 and inferior leads during AVNRT. Therefore ΔRP interval (V1 − III) of more than 20 milliseconds suggests slow-slow AVNRT (sensitivity, 71%; specificity, 87%).

Programmed Atrial Stimulation During Sinus Rhythm

Anterograde dual AVN physiology.

Demonstration of anterograde dual AVN pathway conduction curves requires a longer ERP of the fast pathway than the slow pathway ERP and the atrial functional refractory period (FRP), as well as a sufficient difference in conduction times between the two pathways. Dual AVN physiology can be diagnosed by demonstrating one of the following: (1) a “jump” in the AH interval in response to progressively more premature AES; (2) two ventricular responses to a single atrial impulse; (3) a PR interval exceeding the R-R interval during rapid atrial pacing; or (4) different PR or AH intervals during NSR or fixed-rate atrial pacing ( Box 17.2 ).

Box 17.2

Dual Atrioventricular Node Physiology

Manifestations of Anterograde Dual Atrioventricular Node Physiology

• •
  

  A “jump” in the AH interval of ≥50 ms in response to a 10-ms decrement of the AES coupling interval or atrial PCL

  
  
• •
  

  Dual ventricular response to a single atrial beat (“double fire”)

  
  
• •
  

  PR interval exceeding the R-R interval during rapid atrial pacing

  
  
• •
  

  Two distinct PR or AH intervals during NSR or fixed-rate atrial pacing

Manifestations of Retrograde Dual Atrioventricular Node Physiology

• •
  

  A “jump” in HA interval of ≥50 ms in response to a 10-ms decrement of the VES coupling interval or ventricular PCL

  
  
• •
  

  Two atrial responses to a single ventricular impulse

AES , Atrial extrastimulation; AH , atrial-His; CL , cycle length; NSR , normal sinus rhythm; PCL , pacing cycle length; VES , ventricular extrastimulation.

AH interval jump.

In contrast to the normal pattern of AVN conduction, in which the AH interval gradually lengthens in response to progressively shorter AES (i.e., shorter coupling intervals), patients with dual AVN physiology usually demonstrate a sudden increase (“jump”) in the AH interval at a critical AES (A1-A2) coupling interval ( eFig. 17.1 ). Conduction with a short PR or AH interval reflects fast pathway conduction, whereas conduction with a long PR or AH interval reflects slow pathway conduction. The AH interval jump signals block of anterograde conduction of the progressively premature AES over the fast pathway (once the AES coupling interval becomes shorter than the fast pathway ERP) and anterograde conduction over the slow pathway (which has an ERP shorter than the AES coupling interval), with a longer conduction time (i.e., longer A2-H2 interval). A jump in the A2-H2 (or H1-H2) interval of ≥50 milliseconds in response to a 10 millisecond shortening of either the A1-A2 interval (i.e., AES coupling interval) or the A1-A1 interval (i.e., pacing cycle length [PCL]) is defined as a discontinuous AVN function curve and is considered evidence of dual anterograde AVN pathways ( see Fig. 4.23 ).

Dual Atrioventricular Node Physiology.

H1-H2 intervals (left) and A2-H2 intervals (right) are at various A1-A2 intervals, with a discontinuous atrioventricular nodal curve. At a critical A1-A2 interval, the H1-H2 and A1-H2 intervals increase markedly. At the break in the curves, atrioventricular nodal reentrant tachycardia is initiated.

(From Olgin JE, Zipes DP. Specific arrhythmias: diagnosis and treatment. In: Libby P, Bonow RO, Mann DL, Zipes DP, eds. Braunwald’s Heart Disease: A Textbook of Cardiovascular Medicine . 7th ed. Philadelphia: Saunders; 2008:880.)

Two ventricular responses to a single atrial impulse.

Rapid atrial pacing or AES can result in two ventricular complexes to a single paced atrial impulse (referred to as “1 : 2 response”). The first ventricular complex is caused by conduction of the atrial impulse over the fast AVN pathway, and the second complex is caused by conduction over the slow AVN pathway ( Fig. 17.10 ). This response requires a unidirectional retrograde block in the slow AVN pathway. Typically, in the presence of dual AVN pathways, conduction propagates simultaneously over both fast and slow AVN pathways. However, the wavefront conducting down the fast pathway reaches the distal junction of the two pathways before the impulse conducting down the slow pathway; hence, it conducts retrogradely up the slow pathway to collide with the impulse conducting anterogradely down that pathway. Thus the anterograde impulse conducting down the slow pathway does not have the opportunity to reach the HB and the ventricle. Rarely, however, the slow pathway conducts only anterogradely or has a very long retrograde ERP. In this setting, the wavefront traveling anterogradely down the fast pathway blocks (but does not conceal) in the slow pathway retrogradely and fails to retard the impulse traveling anterogradely down that pathway. Consequently, the wavefront traveling down the slow pathway can reach the HB and ventricle to produce a second His potential and QRS in response to a single atrial impulse. Because retrograde block in the slow pathway is a prerequisite to a 1 : 2 response, when such a phenomenon is present, it indicates that the slow pathway cannot support reentrant tachycardia using the slow pathway as the retrograde limb. The 1 : 2 response should be differentiated from pseudo-simultaneous fast and slow pathway conduction, which is a much more common phenomenon during rapid atrial pacing. In the latter case, all paced atrial impulses block anterogradely in the fast pathway and conduct exclusively down the slow pathway with prolonged AH intervals (with PR intervals longer than atrial PCL), so that the last paced atrial impulse falls before the His potential caused by conduction of the preceding paced atrial impulse. Thus the last paced atrial impulse is followed by two His potentials and two ventricular complexes. The last response may then be followed by induction of AVN echo beats or AVNRT, mimicking simultaneous fast and slow pathway conduction ( Fig. 17.11 ).

Dual Atrioventricular Node (AVN) Physiology: Two Ventricular Complexes to a Single Paced Atrial Impulse.

Rapid atrial pacing during normal sinus rhythm. Each paced atrial impulse conducts anterogradely over the fast AVN pathway (red arrows) . However, the last paced impulse conducts anterogradely over both the fast (red arrow) and slow (blue arrow) pathways, resulting in two His bundle and ventricular responses. CS _dist , Distal coronary sinus; CS _prox , proximal coronary sinus; HRA , high right atrium; RVA , right ventricular apex.

Induction of Typical Atrioventricular Nodal Reentrant Tachycardia (AVNRT) With Atrial Pacing.

(A) Each of the atrial paced impulses (S1) conducts anterogradely over the slow atrioventricular node (AVN) pathway. The last paced impulse, following anterograde conduction down the slow pathway, also conducts retrogradely up the fast AVN pathway to initiate typical AVNRT with right bundle branch block (RBBB). (B) Each of the atrial paced impulses conducts anterogradely over the slow AVN pathway with a long PR interval (blue arrows) ; this is longer than the pacing cycle length, resulting in crossing over, which can mimic a 1 : 2 atrioventricular response caused by anterograde conduction over both the fast and slow AVN pathways. Following anterograde conduction down the slow pathway, the last paced impulse also conducts retrogradely over the fast pathway, initiating typical AVNRT. Red arrows illustrate atrial activation sequence during atrial pacing versus AVNRT. (C) Atrial pacing from the coronary sinus ostium induces typical AVNRT. Each of the atrial paced impulses (S1) conducts over the fast AVN pathway except for the last paced impulse, which conducts over both the fast and slow AVN pathways (blue arrows) , resulting in a 1 : 2 response (i.e., 2 ventricular responses to a single atrial impulse); this is followed by induction of typical AVNRT with RBBB. The possibility of conduction of the paced atrial beats over the slow AVN pathway with a long atrial–His bundle (AH) interval (longer than the paced cycle length) is unlikely because the His potential preceding the first tachycardia complex (indicated by the green arrow ) occurs later (i.e., at a longer AH interval) than what would be expected if that His potential was actually a result of conduction of the last atrial stimulus (as compared with the previous AH intervals). CS _dist , Distal coronary sinus; CS _prox , proximal coronary sinus; HRA , high right atrium; RVA , right ventricular apex.

PR interval longer than RR interval.

The PR interval gradually prolongs as the atrial pacing rate increases. When a critical pacing rate is reached, the PR interval typically exceeds the R-R interval, with all AVN conduction over the slow AVN pathway (see Fig. 17.11 ). This manifests as crossing over of the pacing stimulus artifacts and QRSs; that is, the paced atrial complex is conducting not to the QRS immediately following it, but rather to the next QRS, because of a very long PR interval. There should be consistent 1 : 1 AV conduction that remains stable over the span of several cycles for this observation to be interpreted (i.e., without Wenckebach block). Such slow AVN conduction, sometimes called “skipped P waves,” is seen only when conduction propagates over a slow AVN pathway, and it is not seen in the absence of dual AVN physiology. This phenomenon is diagnostic of the presence of dual AVN physiology, even in the absence of an AH interval jump and therefore is very helpful in patients with smooth AVN function curves. In fact, 96% of patients with AVNRT and smooth AVN function curves have a PR/RR interval ratio greater than 1 (i.e., PR interval longer than PCL) during atrial pacing at the maximal rate with consistent 1 : 1 AV conduction (vs. 11% in controls).

Two distinct AH intervals during NSR or at identical atrial PCLs.

This phenomenon can occur when the fast pathway anterograde ERP is long relative to the sinus or paced CL (see Fig. 17.6 ). Such a phenomenon also requires a long retrograde ERP of the fast pathway. Otherwise, AVN echo beats or AVNRT would result, because once the impulse blocks anterogradely in the fast pathway and is conducted down the slow pathway, it would subsequently conduct retrogradely up the fast pathway if the ERP of the fast pathway were shorter than the conduction time (i.e., shorter than the AH interval) over the slow pathway.

Determinants for the occurrence of sustained slow pathway conduction include markedly abnormal, anterograde and retrograde conduction properties of the fast pathway and, possibly, differential sensitivity to vagal activity of the fast pathway, compared with the slow pathway.

Programmed Ventricular Stimulation During Sinus Rhythm

Para-Hisian Pacing During Sinus Rhythm

Para-Hisian pacing helps exclude the presence of a septal AV BT, which can mediate orthodromic AVRT with a retrograde atrial activation sequence similar to that during AVNRT. In the absence of a BT, para-Hisian pacing results in a shorter SA (or VA) interval when the HB-RB is captured (S − H = 0 and SA = HA) than the SA interval when only the ventricle is captured (SA = S − H + HA) with no change in the atrial activation sequence or HA interval. This response to para-Hisian pacing is termed pattern 1 or AVN/AVN pattern .

A change in the retrograde atrial activation sequence with loss of HB-RB capture indicates the presence of a retrogradely conducting BT. Similarly, an SA (VA) interval that is constant regardless of whether the HB RB is being captured indicates the presence of a BT, whereas prolongation of the SA (or VA) interval on loss of HB capture, compared with that during HB capture, excludes the presence of a retrogradely conducting BT, except for slowly conducting and far free-wall BTs. Please refer to Chapter 20 for a more detailed discussion of para-Hisian pacing.

Initiation by Programmed Atrial Stimulation

Atypical AVNRT.

Anterograde dual AVN physiology is usually not demonstrable in patients with atypical AVNRT. In addition, as noted, the presence of a “1 : 2 response” to AES predicts noninducibility of atypical AVNRT because it indicates failure of the slow pathway to support retrograde conduction, a prerequisite for the atypical AVNRT circuit.

When atypical AVNRT is initiated with atrial stimulation, it is usually with modest prolongation of the AH interval over the fast pathway and anterograde block in the slow pathway, followed by retrograde slow conduction over the slow pathway ( Fig. 17.12 ). Therefore a critical AH interval delay is not obvious.

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