Introduction
Since its introduction in 1992, catheter ablation of the slow pathway (SP) has been considered the first-line treatment in symptomatic patients with atrioventricular (AV) nodal reentrant tachycardia (AVNRT) [1]. The procedure is usually performed using fluoroscopy but three-dimensional (3D) mapping can provide further help by identifying the anatomical structures that are relevant for the ablation [2]. In some patients with AVNRT it is also possible to record SP potentials in the perinodal region [3]. High-resolution mapping of the Triangle of Koch may increase the overall safety and efficacy of the ablation procedure [4].
The possibility to record His bundle (HB) potentials in humans was reported more than 5 decades ago [5]. In patients with AV conduction disturbances, the site of the block can be determined by recording the time delay between the HB signal and the earliest ventricular activation on surface electrocardiogram. The amplitude and duration of the HB signal depend on multiple factors, such as the type of catheter used, interelectrode spacing and orientation of the catheter tip. Despite widespread use of HB potentials in daily electrophysiology practice, detailed assessments of their signal characteristics in AVNRT patients are lacking. The aim of this study is to determine the distinctive features of the HB potentials, and elucidate if they provide clues for identification of patients with SP, an electrical prerequisite for the development of AVNRT.
Methods
Study patients
Electrophysiological findings of consecutive patients with symptomatic AVNRT due to slow-fast type or fast-slow type reentry and AV reentrant tachycardia (AVRT) due to an accessory pathway were studied between December 2018 to September 2020. The study data was prospectively collected in the Catheter Ablation Registry at the University Heart Center Zurich, which was approved by the Institutional Ethical Committee.
Electrophysiological study findings
All electrophysiological studies were performed in the fasting, non-sedated state. After local anesthesia, multielectrode catheters were introduced percutaneously through the right femoral vein and positioned in high right atrial, right ventricular and HB positions, followed by measurements of basic electrophysiological parameters. AV nodal effective refractory period (AVNERP) was measured at progressively shortening intervals following 8 drive trains at 600 ms. An atrio-His (AH) jump, suggestive of the presence of an SP, was identified, if there was a 50 ms or more increase in H1H2 interval by using 10 ms decrements of A1A2. The longest conduction time of the fast pathway (A1H1) was measured as the last premature extrastimulus coupling interval before an AH jump. The shortest conduction time of the slow pathway (A2H2) was defined as the first premature extrastimulus coupling interval after an AH jump. All measurements were performed under baseline conditions without administration of isoprenaline.
If a tachycardia was not inducible at baseline, isoproterenol was administered. Various stimulation techniques were used in both groups to ensure the induction and reproducibility of the clinical tachycardia. V-A-V response during ventricular entrainment was used to exclude an atrial tachycardia.
Mapping and catheter ablation
After diagnosis of AVNRT or AVRT, a 7-Fr quadripolar, steerable radiofrequency ablation catheter (Navistar 4 mm, Biosense Webster, Irvine, CA, USA) was introduced into the right atrium. Prior to mapping, calibration for respiratory compensation was performed. The filter settings for bipolar signals were set at the 16–500 Hz range. Using the ablation catheter, anatomical locations showing HB potentials were extensively searched and tagged point-by-point using the CARTO 3D electroanatomical mapping system (Biosense Webster, Irvine, CA, USA) to determine the His cloud (Fig. 1). For each patient, there was a minimum of 8 points that determined the His cloud. The HB signal with the maximal amplitude was labeled as HBmax. Every point was double-checked by offline analysis to confirm correct annotation. 3D mapping hallmarks of HBmax, the central point of the coronary sinus ostium (CSO), and the site of SP ablation (ABL) in the standard right anterior oblique view (RAO 30°) were annotated for distance identification. The amplitude and duration of HBmax between the two groups were measured using endocardial tracings at a recording speed of 400 mm/s.
For SP ablation, the inferior/posterior aspect of the interatrial septum adjacent to the CSO was targeted. The local signal typically showed a small, low frequency atrial and a sizeable, high-frequency ventricular deflection, and rarely an SP potential, but no HB signal, as described by previous publications [6–8]. The ablation site was selected if there was adequate safety distance from the lowest HB point. The site of SP ablation (ABL, blue point in 3D map) with best response showing slow junctional beats during ablation was identified for each patient. AVRT patients were ablated along either the right or left AV valvular annulus, depending on the location of the accessory pathway.
Radiofrequency energy was applied with an overall period of 60–120 s on the ablation site with a power setting in the range of 30–50 W for both groups. The endpoint for AVNRT ablation was non-inducibility of the tachycardia. For patients with an AH jump (with or without an echo beat) after ablation, the SP ablation sites were often multiple. Since this study also aims at the SP ablation site, patients who had a residual SP were excluded from analysis. For AVRT patients, abolishing antegrade and/or retrograde accessory pathway conduction was considered as the endpoint of the procedure. Electrophysiologic study was repeated at least 20 min after last ablation to confirm the success of the procedure. In order to prevent thromboembolic complications, intravenous heparin was administered during the procedure and subcutaneous unfractionated heparin was given post-operatively during bed rest. Patients who underwent ablation of left-sided accessory pathways were prescribed acetylsalicylic acid for 4–6 weeks. All patients were discharged from the clinic either on the same day of the procedure or on the day after. They were followed up at our cardiac arrhythmia clinic or by the referring physicians after discharge.
Statistical analysis
Data were expressed as means ± standard deviation. For continuous variables, data were expressed as median (interquartile range), and Kruskal–Wallis test was performed to examine the difference among groups. Mann–Whitney U test was used to test the difference in continuous variables between groups. The correlations between measurements were examined by linear regression analysis. For the HBmax measurements that significantly differed between AVNRT and AVRT groups, receiver operating characteristic (ROC) curve analysis was used to compare the predicted accuracy and determine cut-off values with optimal performance. Statistical significance was set at p < 0.005.
Results
Patient characteristics
A total of 162 patients were finally enrolled in the study. Of these, 112 (57 ± 22 years; 45 males) had AVNRT and the remaining 50 had AVRT (33 ± 12 years; 29 males). No patients were enrolled in the latter group if they had evidence for the presence of concomitant dual AV nodal physiology. Eight patients had coronary artery disease (6 in AVNRT group). Four patients had sick sinus syndrome with an implanted pacemaker, one had dilated cardiomyopathy and one had valvular heart disease, all of whom in the AVNRT group. In the remaining 121 patients (74 AVNRT, 47 AVRT), there was no evidence of an underlying structural heart disease. All patients had normal systolic left ventricular function (left ventricular ejection fraction [LVEF] > 50%), except for one AVNRT patient with cardiomyopathy having an LVEF of 36%. All antiarrhythmic drugs were discontinued prior to electrophysiological study latest on the previous day prior to the procedure. In the AVNRT group, 5 fast-slow type AVNRTs were identified and 107 slow-fast AVNRTs were diagnosed prior to ablation. In the AVRT group, 12 Wolff-Parkinson-White syndrome patients were found to have pre-excited electrocardiogram at baseline. For concealed accessory pathways, 16 patients demonstrated anterograde concealment, 16 demonstrated retrograde concealment, and 6 demonstrated both anterograde and retrograde concealment. Regarding the localization of the accessory pathways around the mitral and tricuspid annuli, there were 6 accessory pathways in the right anterior septum, 4 in the right mid-septum, 9 in the right posterior septum, 10 in the right sided free wall (4 right posterior or right posterolateral, 3 right lateral, 3 right anterior), 4 in the left posterior septum, 1 in the left mid-septum, 16 in the left lateral free wall (13 left lateral or left anterolateral, 3 left posterior or left posterolateral).
The catheter ablation procedure was acutely successful and uneventful in all patients in both AVNRT and AVRT cohorts. Twelve-lead surface electrocardiography parameters and electrophysiological measurements prior to and after ablation in patients of both groups were shown in Table 1.
Parameters |
AVNRT |
AVRT |
P |
||
Prior ablation |
Post ablation |
Prior ablation |
Post ablation |
||
N |
N = 112, 45 male |
N = 50, 29 male |
< 0.005* |
||
Age [years] |
57 ± 22 |
33 ± 12 |
> 0.005* |
||
|
|||||
AVBCL [ms] |
369 ± 75 |
398 ± 45 |
363 ± 74 |
366 ± 70 |
> 0.005* |
< 0.0051# |
|||||
> 0.0052# |
|||||
VABCL [ms] |
374 ± 56 |
380 ± 51 |
365 ± 19 |
367 ± 43 |
> 0.005* |
< 0.0051# |
|||||
> 0.0052# |
|||||
A1H1 interval [ms] |
159 ± 38 |
NA |
NA |
NA |
|
A2H2 interval [ms] |
250 ± 48 (n = 107)@ |
NA |
NA |
NA |
|
HV interval [ms] |
45 ± 6 |
45 ± 5 |
NA |
43 ± 4 |
< 0.005* |
< 0.005# |
|||||
Tachycardia CL [ms] |
388 ± 58 |
NA |
372 ± 65 |
NA |
< 0.005* |
HB potential characteristics in AVNRT patients compared with AVRT patients
There were significant differences in HBmax amplitude and duration between the AVNRT (slow-fast and fast-slow type) and AVRT groups after adjusting for age and gender, as shown in Figure 2. The HBmax amplitude was 0.29 ± 0.10 mV in AVNRT patients, whereas it was 0.17 ± 0.05 mV in the AVRT group (p < 0.0001). Likewise, the HBmax duration was 22 ± 5 ms in the AVNRT group and 16 ± 3 ms in the AVRT group (p < 0.0001). Moreover, in five AVNRT patients with fast-slow type reentry, HBmax amplitude was 0.36 ± 0.09 mV and duration was 24 ± 2.8 ms, which were significantly different than those values in AVRT patients (p < 0.0001).
It was then sought to define the diagnostic value of HBmax amplitude and duration for discrimination of AVNRT due to SP from AVRT. After adjusting for age and gender, linear logistic regression analysis revealed that HBmax amplitude and duration were independent predictors for AVNRT (Fig. 3). The area under the ROC curve (AUC) of HBmax amplitude in AVNRT patients was 0.86, and the optimal cut-off to predict AVNRT was equal to or greater than 0.22 mV with a sensitivity of 0.78 and specificity of 0.84 (Fig. 2). Meanwhile, the AUC of HBmax duration was 0.69, and the optimal cut-off to predict AVNRT was equal to or greater than 20 ms with a sensitivity of 0.49 and specificity of 0.83.
Electrophysiological and anatomical correlations of HBmax in AVNRT patients
Three-dimensional CARTO maps showed 15.4 ± 4.9 mm distance between the successful ablation site and the HBmax recording site. The distance between the center of the CSO and the HBmax recordings site was 23.5 ± 5.6 mm. The mean A2H2 interval with an SP conduction was 250 ± 48 ms. The distance between HBmax and CSO was positively correlated with the distance between HBmax and the successful ablation site (r2 = 0.7174, 95% confidence interval [CI] 0.6101 to 0.7989, p = 0.0004), in accordance with the previous publication (Fig. 4) [9]. The HBmax distance from the successful ablation site was positively correlated with the shortest SP conduction time (A2H2) (r2 = 0.3368, 95% CI 0.1515 to 0.4993, p < 0.00001), but it was not correlated with HBmax amplitude or duration. The distance between HBmax and CS ostium was not correlated with A2H2. Likewise, it was neither correlated with HBmax amplitude nor HBmax duration.
Ablation procedure and follow up
Ablation was successfully performed in all patients enrolled. No significant cardiac adverse effects occurred during energy application, and all had preserved AV conduction. The overall duration of each study was 1–3 hours. No patient had tachycardia recurrence or apparent electrocardiography parameter changes with a mean post-ablation period of 6 months.
Discussion
Main findings
The present study had several findings: First, it was demonstrated that HBmax amplitudes were higher and HBmax durations were longer in patients with AVNRT, as compared to those measurements in patients with AVRT. These measurements might be helpful for primary evaluation of the two arrhythmic conditions with a relatively high sensitivity and specificity. Second, the distance between HBmax and successful ablation site was positively correlated with the SP conduction time and with the distance from HBmax to the CSO. These findings may be helpful in choosing the optimal SP site for ablation.
The higher HBmax amplitudes and longer HBmax durations were not only observed in patients with typical AVNRT but were also observed in patients with atypical AVNRT due to fast-slow type reentry, as compared to those measured in patients with AVRT. On the other hand, these measurements were not significantly different in patients with left-sided, right-sided, or septal accessory pathways. The differential diagnosis of atypical AVNRT from AVRT could be challenging since extra electrophysiologic maneuvers were often required, such as parahisian pacing and ventricular entrainment [10, 11]. The HBmax measurements might provide primary clues for dual AVN physiology and lead to corresponding electrophysiological study protocol priority for mechanism identification.
Distinctive HB potential in AVNRT patients
It has been known for more than 30 years that longitudinal dissociation within the posterior AV nodal region is the main mechanism, which gives rise to localized reentry and AVNRT [12]. Despite this, the signal characteristics of the HB potentials in human beings with an SP have not been scrutinized in depth to date. Only previous observations from rabbit AVNRT models show an augmentation of the HB signal amplitude during pacing with short premature coupling intervals [13]. The current study, using electroanatomical 3D mapping of the AV nodal and HB region, fills the knowledge gap for patients with AVNRT and is in line with previous observations from animal models. In the present study, particular attention was paid to obtaining a complete representation of the HB cloud by taking 8 or more annotation points along the area of HB that showed distinct HB potentials. The observed augmentation of the HBmax signal (especially its amplitude) in patients with AVNRT possibly reflects an electrical region that represents the continuation of two distinct electrical pathways joining together into an enhanced HB deflection. Clearly, this also necessitates proper orientation of the fibers at the bipolar recording site of the His catheter. This illustration is shown in the form of a schematic diagram in Figure 5.
The presence of an SP may also be manifested in some occasions during sinus rhythm. Intermittent occurrence of prolonged PR intervals, which may arise following ectopic beats, may suggest an SP [14]. Ablative elimination of the SP in such patients will restore physiological AV conduction over the fast pathway. Moreover, dual AV nodal non-re-entrant tachycardia, which is characterized by double antegrade conduction from a single sinus nodal activity simultaneously via the slow and fast AV nodal pathways into the ventricle, has been described [15, 16]. Furthermore, SP potentials prior to the HB deflection can also be detected by electrophysiological catheter during sinus rhythm on some occasions [3].
Meanwhile, immunobiological study on human AV junction demonstrates differential Cx43(+) myocyte distribution, with rightward nodal extensions and HB much more than leftward nodal extensions and compact node (Fig. 5) [17]. These observations provide further proof of the unique conduction properties of different parts of AV junctional area, which contribute to longitudinal dissociation and reentrant arrhythmias.
HBmax electrophysiology correlates with related anatomy in AVNRT patients
The positive correlation between SP conduction time and the distance from HBmax to successful ablation site, as observed in our study, may simply imply a longer conduction time for the SP wavefront to perpetuate due to a longer anatomical distance. This finding is in line with the findings of Dagres et al. [18] who demonstrated that SP with longer conduction intervals was more often ablated in a more inferior area of the Koch’s triangle.
The observed difference in tachycardia cycle length between AVNRT and AVRT in the current study is in line with previous observations in adult patients [19]. In contrast, tachycardia cycle length of the two arrhythmic conditions does not differ in pediatric patients [20]. This discrepancy is explained as the conduction of both fast and slow pathways is faster in children than in adults. The adult patients in the study herein, did not manifest a correlation between age and SP conduction time or the distance from HBmax to CSO.
Limitations of the study
The present study has some limitations. HBmax in this study was observed during sinus rhythm before any electrophysiological maneuvers or medication induction was introduced. This could only give us a preliminary assessment of possible differential diagnosis of dual AVN physiology or AVNRT. Whereas the fundamental evaluation and step-by-step electrophysiological study can never be underestimated. Moreover, since the focus herein was on the effective ablation site compared to other anatomical structures within the triangle of Koch, patients with multiple SPs were excluded. Therefore, we could not comment on whether observations would hold true in patients with slow-slow type reentry.
Conclusions
HBmax amplitudes are higher and HBmax durations are longer in patients with AVNRT, as compared to those in AVRT. These features may provide preliminary clues to differentiate the two arrhythmic conditions with relatively high sensitivity and specificity. Moreover, the distance between HBmax and successful ablation site is positively correlated with the SP conduction time and with the distance from HBmax to the CSO. These findings are helpful in determining the presence of an SP and in optimizing SP ablation.
Acknowledgments
We thank Daria Vdovenko (University of Zurich) and Kevin He (University of Michigan) for their constructive advice on statistical analysis.