Ablation of Ventricular Outflow Tract Tachycardias




Abstract


Although ventricular tachycardia (VT) usually occurs in patients with structural heart disease, it can also occur in patients with structurally normal hearts. In this scenario, the mechanism of VT is usually focal and because of adenosine-sensitive, triggered activity. The right and left ventricular outflow tracts are the most common sites of origin of idiopathic outflow tract VT, including the aortic cusps, pulmonary artery, and left ventricular (LV) summit region. Medications such as beta-blockers, calcium-channel blockers, sodium-channel blockers, and potassium-channel blockers can be effective, but must be taken continually to suppress VT and may have associated long-term side effects. Catheter ablation is a safe and effective treatment option for patients with symptomatic outflow tract VT, and when performed by a skilled electrophysiologist can be considered as first-line treatment. Because of the focal, triggered mechanism of these arrhythmias, activation mapping during arrhythmia is optimal to identify the site of earliest activation as the target for ablation. A comprehensive understanding of the anatomy of the outflow tract region is necessary to maximize safety and efficacy of ablation of outflow tract ventricular arrhythmias. Challenges to ablating outflow tract tachycardias include mapping and ablation of noninducible tachycardias and ablation of tachycardias originating from regions that are difficult to target because of anatomic constraints (including the LV summit region, parahissian, and/or intraseptal location).




Keywords

ablation, catheter, outflow tract, premature ventricular complex (PVC), ventricular tachycardia

 




Key Points





  • Ventricular outflow tract tachycardias include the right or left ventricular (LV) outflow tracts, aortic cusps, pulmonary artery, and the corresponding epicardium (LV summit region).



  • The mechanism underlying outflow tract arrhythmias is usually triggered activity, and the site of origin is focal. Activation mapping during arrhythmia is optimal to identify the site of earliest activation as the target for ablation.



  • Mapping of outflow tract tachycardias is often enhanced by the use of electroanatomic mapping systems. Computed tomography, intracardiac echocardiography, and coronary angiography are important adjuncts for mapping and ablation of coronary cusp and epicardial sites of origin.



  • A comprehensive understanding of the anatomy of the outflow tract region is necessary to maximize safety and efficacy of ablation of outflow tract ventricular arrhythmias



  • Challenges to ablating outflow tract tachycardias include mapping and ablation of noninducible tachycardias, and ablation of tachycardias originating from regions that are difficult to target because of anatomic constraints (including the LV summit region, parahissian, and/or intraseptal location).



Ventricular tachycardias (VTs) most frequently occur in patients with structural heart disease. However, approximately 10% of VTs occur in patients with a normal electrocardiogram (ECG), echocardiogram, and coronary angiography, and are hence considered to be idiopathic VTs (IVTs).


IVTs have been classified based on the ventricle of origin, ECG morphology (QRS configuration and axis), clinical pattern of the tachycardia (repetitive, nonsustained, or sustained), evidence of catecholamine dependency, and response to pharmacologic agents. In general, the clinical history, combined with the response of the arrhythmia to programmed stimulation, adenosine, verapamil, and propranolol may help differentiate among different types of IVTs.


This chapter will discuss briefly the mechanism and common clinical presentations of idiopathic outflow tract ventricular tachycardias (OTVTs) and will provide an in-depth description regarding the anatomic and electrocardiographic localization of these arrhythmias and current state of ablation strategies.




Mechanism


The most common origins of IVTs are the right and left ventricular outflow tracts (RVOT, LVOT). In earlier experiences, the majority of OTVTs originated from the RVOT (70%) and less frequently (20%) from the aortic cusps. However, in the more recent reports, OTVTs appear to be equally distributed between the RVOT and aortic cusps. In a minority of patients (10%), the site of origin can be the basal LV pulmonary artery or the LV epicardium.


Idiopathic OTVTs usually exhibit one of three clinical phenotypes: repetitive monomorphic premature ventricular complexes (PVCs; most common), nonsustained monomorphic VT, or exercise-induced sustained VT (least common). Considerable overlap may occur among the three phenotypes. For example, patients with only repetitive monomorphic PVCs may develop salvos of VT or sustained VT during exercise or isoproterenol infusion. The observation that ablating one phenotype at a discrete site eliminates the other two phenotypes of arrhythmia suggests that the three phenotypes are representative of the same focal cellular process.


The signature characteristic of idiopathic OTVTs is termination following administration of adenosine or verapamil. Lerman and colleagues elegantly demonstrated that the mechanism underlying most idiopathic OTVTs is triggered activity mediated by catecholamine-induced delayed afterdepolarizations. Catecholamine stimulation of the beta-adrenergic receptor results in an increase in intracellular cyclic adenosine monophosphate (cAMP) and I ca,L activities, resulting in spontaneous oscillatory release of Ca 2+ from the sarcoplasmic reticulum that activates a transient inward current ( I ti ) giving rise to delayed afterdepolarizations. Because activation of adenylyl cyclase and I ca,L is critical for the development of cAMP-mediated triggered activity, this arrhythmia is sensitive to a variety of electropharmacologic perturbations such as beta-blockers, calcium-channel blockers, vagal maneuvers, and adenosine. The effect of adenosine on VT (with rare exceptions) is mechanism specific, terminating only ventricular arrhythmias that are attributed to cAMP-mediated triggered activity.


Clinical Presentation


According to a recent population-based study from the Mayo Clinic, which analyzed patients from Olmstead County who were diagnosed with IVTs between 2005 and 2013, it appears that the incidence of IVTs in the general population has increased over time. These arrhythmias are most commonly observed in the third to sixth decade. Sustained IVT occurs with equal distribution between men and women although symptomatic PVCs are more frequently present in women. Interestingly, RVOT arrhythmias show a predilection for females, whereas those originating in the aortic cusps tend to be more common in men. In two large series (including one from the authors’ institution), 70% of patients with RVOT VT were women, whereas approximately 70% of patients with aortic cusp VTs were men.


The most common clinical phenotype of idiopathic OTVTs is repetitive monomorphic PVCs. Palpitations are the most common symptom (48% to 80%) and are usually experienced as isolated forceful beats resulting from the increased stroke volume associated with the normal beat following the PVC. Fatigue and low energy are also common symptoms seen in patients with at least a moderate burden of PVCs. This may be caused by ineffective ventricular contraction during PVCs resulting in a reduced cardiac output. Lightheadedness may be observed in 25% to 50% of patients, whereas true syncope is rare (10%). The latter usually occurs in patients with ventriculo atrial conduction and may be a result of baroreceptor reflex activity.


Exercise testing induces VT in approximately 70% of patients who present with sustained IVT, but only in 10% of patients whose clinical presentation is repetitive monomorphic PVCs. In the former group, sustained VT is typically observed either during exercise or in the recovery phase. This observation can be mimicked with pharmacologic agents as well. Thus in these patients the clinical arrhythmia can be induced during isoproterenol infusion as well as during an isoproterenol washout period. This highlights the evanescent nature of triggered activity-mediated arrhythmias.


Other scenarios that provoke these arrhythmias include physical or emotional stress, anxiety, and stimulants such as caffeine. In females, IVTs occur more often during the premenstrual and perimenopausal periods and with gestation, suggesting a role for hormonal influence.


Idiopathic OTVTs have a benign course in most patients, suggesting that the underlying pathophysiologic process is not progressive and that the tachycardia does not represent an early manifestation of an occult cardiomyopathy. This finding has been confirmed during long-term follow-up studies in patients with RVOT tachycardias. However, there are two exceptions to this general rule. First, patients with a high burden of ventricular arrhythmia can develop a reversible form of LV cardiomyopathy. Tanaka et al. recently demonstrated in a porcine model that prolonged ventricular bigeminy leads to diffuse interstitial fibrosis histologically and results in decreased unipolar voltage as seen with electroanatomic mapping. Consistent with this observation, Bogun et al. showed that a PVC burden greater than 24% was associated with development of PVC-induced cardiomyopathy (sensitivity and specificity of 80%). However, arrhythmia burden alone may be a poor predictor of future development of cardiac dysfunction because patients with a lower burden of arrhythmia (16% ± 4%) also have developed cardiomyopathy, whereas some patients with a higher burden (33% ± 13%) can maintain normal ventricular function over extended follow-up periods. Thus there may be other factors involved in the development of cardiac dysfunction in patients with outflow tract tachycardias. Nevertheless, in patients with OTVT who develop true tachycardia-mediated cardiomyopathy, suppression of the clinical arrhythmia, either pharmacologically or by ablation, is associated with improvement of LV function. It is good clinical practice to monitor cardiac function with periodic (for instance, annual) echocardiograms in asymptomatic patients with PVC burden exceeding 5%, and certainly if symptoms of LV dysfunction develop. Another clinical scenario that is not uncommon is the development of OTVTs in patients with structural heart disease. This is particularly challenging in patients with arrhythmogenic right ventricular cardiomyopathy (ARVC), where the appearance of OTVTs may be a manifestation of the underlying disease, and the prognosis of the arrhythmia in these patients is less benign than the typical OTVT population. Suspicion for ARVC should arise if the arrhythmias manifest multiple ECG morphologies. ECG algorithms have also been developed to improve differentiation between idiopathic OTVTs versus those occurring in the setting of ARVC. Signal-averaged ECG, cardiac magnetic resonance imaging (MRI), and electroanatomic voltage mapping may be helpful to diagnose ARVC in patients presenting with RVOT VT. In one study, voltage and local electrogram abnormalities on electroanatomic maps were helpful in differentiating idiopathic RVOT tachycardia from RVOT tachycardia caused by subclinical ARVC. In these patients the areas of voltage/electrogram abnormalities correlated with fibrofatty myocardial replacement seen on endomyocardial biopsies obtained from these locations.




Anatomic Substrate


Most patients with idiopathic OTVT have demonstrated lack of gross structural heart disease as evidenced by ECG, echocardiography, radionuclide imaging, and cardiac angiography. However, in patients with RVOT VTs that were initially thought to be idiopathic in nature, studies using MRI have shown structural abnormalities including the presence of focal wall thinning, abnormal systolic wall motion, and focal fatty infiltration, findings not appreciated using conventional imaging. The most common site of abnormality in most cases was the RV free wall. However, the abnormal substrate in these studies did not consistently correspond with the site of arrhythmia origin and subsequent studies have shown a considerably lower prevalence of such abnormalities (approximately 10%). Investigators have also conducted right ventricular biopsies in patients with RVOT tachycardias that have shown a wide spectrum of findings ranging from normal tissue to myocardial atrophy and fibrofatty replacement consistent with ARVC. Importantly, during electroanatomic mapping, identification of areas manifesting fractionated electrograms and voltage abnormalities consistent with scar can serve as target locations for obtaining endomyocardial biopsy to increase the diagnostic yield in patients with suspected ARVC, myocarditis, and/or cardiac sarcoidosis who present with OTVTs.


Idiopathic OTVT may also occur in patients with other unrelated cardiac diseases, including patients with a history of coronary disease. In such patients, the presence of an old infarction that is anatomically distinct from the outflow tract signifies the coexistence of two unrelated processes. Ellis et al. reported the presence of unrelated structural heart disease in 43% of patients (42/97) who underwent ablation of an idiopathic OTVT. In that series, patients with idiopathic OTVT and unrelated structural heart disease were more likely to have the source of the arrhythmia ablated from the coronary cusps or basal LV region, when compared with patients lacking structural heart disease in whom the arrhythmia most commonly arose from the RVOT.




Anatomy of the Outflow Tracts


A comprehensive understanding of the anatomic relationship between the structures in the outflow tract region is crucial to successful localization and ablation of these arrhythmias. In the thoracic cavity the cardiac orientation is such that the RVOT, and particularly its free wall, is the most anterior structure. The superior aspect of the RVOT crosses the anterior aspect of the LVOT such that its anterior-most extension together with the pulmonic valve often lies leftwards of the aortic valve ( Fig. 28.1 A ). The pulmonic valve annulus lies superior to the aortic annulus, and the aortic valve is tilted rightward in the horizontal plane such that the left coronary cusp (LCC) typically lies superior (cranial) to the right coronary cusp (RCC) and noncoronary cusp (NCC). The RCC is in close proximity to the RVOT region, and it is because of this anatomic relationship that successful ablation of OTVT originating from the superior and septal RVOT (its leftward aspect) can sometimes be accomplished from the RCC and vice versa. In fact, the structure immediately anterior to the aortic valve is the posterior muscular infundibular portion of the RVOT (see Fig. 28.1A and B ). Importantly, the penetrating bundle of His resides in the membranous interventricular septum directly underneath the NCC.




Fig. 28.1


A, Anatomic relationship between the right and left outflow tract regions in a coronal view. The right ventricular outflow tract (RVOT) is a cylinder-shaped structure that sits anterior to the left ventricular outflow tract (LVOT) and aortic valve. The septal aspect of RVOT is separated by a thin layer from the right and left coronary cusps (RCC and LCC). B, Intimate relationship between the RVOT and the aortic cusps as seen on intracardiac echocardiography. It also shows the higher position of the RVOT relative to the aortic cusps. C, Left ventricular (LV) ostium in a posterocranial projection. Left, The aortic root with the RCC (R), LCC (L), and the noncoronary cusp (NCC, N). Right, The root of the aorta has been removed to show the elliptical ostium of the left ventricle with the junction of the RCC, the LCC, and the LV summit. AIVV, Anterior interventricular vein; APM, anterior papillary muscle; LA, left atrium; LAFT, left anterior fibrous trigone; LFT, left fibrous trigone; LMCA, left main coronary artery; L-RCC, junction between the LCC and the RCC; PPM, posterior papillary muscle; PSP, posterosuperior process of the LV; PV, pulmonic valve; RCA, right coronary artery; RV, right ventricle; SVC, superior vena cava; X, attachment of the LA to the aorto-ventricular membrane.

From McAlpine WA. Heart and coronary arteries: An anatomical atlas for clinical diagnosis, radiological investigation, and surgical treatment . Berlin; New York: Springer-Verlag; 1975. With permission.


The classic understanding of outflow tract and great artery junction is that there is an abrupt termination of ventricular myocardium at the level of the semilunar valves. However, it has now been established that myocardial sleeves extend into the aorta and pulmonary artery for variable distances in some patients. The outflow tract–great artery junction is complex both in terms of its development and histology with multiple tissue types interfacing in this region (arterial smooth muscle, cardiac muscle, collagen, and valve tissue). In the pulmonic valve region, the myocardial sleeves can extend symmetrically across the valve cusps from few millimeters to more than 2 cm into the pulmonary artery. The myocardial extensions above the aortic valve are significantly different from those observed in the pulmonic valve. At the base of the RCC, the LV myocardium is closely apposed to the aortic wall with myocardial sleeves running in parallel to the base of the cusp. By contrast, the LCC is separated from the LV myocardium by a thick band of fibrous tissue interspersed with strands of ventricular myocardium.


Fundamental to the understanding of IVTs arising near the aortic and mitral valve is the concept of the LV ostium (see Fig. 28.1C ). The LV ostium is best described as an elliptical opening at the base of LV and is covered by a tough fibrous structure, which is perforated by the aorta anteriorly and the mitral valve posteriorly. The aorta is joined to the LV ostium at an angle of approximately 30° above the horizontal plane with the NCC being most inferior, the LCC most superior, and the RCC most anterior and in direct contact with the LV ostium. The aortic valve itself has a central location at the base of the heart and LV ostium with relationships to all other valves and cardiac chambers. The RCC is positioned immediately posterior to the infundibular aspect of the RVOT. Caudally, the RCC is continuous with the anterior LVOT, and at the level of valve insertion, there is either a true physical continuity or very close proximity to myocardial tissue from either the LVOT or the posterior RVOT. The NCC lies posterior and to the right of the RCC and as such it has no anatomic relationship with any ventricular myocardium. Instead, the NCC lies adjacent to the interatrial septum and has relations to both the right and left atria. This may explain why ventricular arrhythmias rarely originate from the NCC. The commissure between the RCC and NCC forms part of the membranous interventricular septum and is the location of the penetrating bundle of His. The LCC lies superior, posterior, and to the left of the RCC. The commissure between the LCC/RCC is immediately posterior and caudal to the distal RVOT (see Figs. 28.1A and B ). Myocardial tissue is present in the LCC but not to the same extent as in the RCC. In addition, the LCC is usually separated from the LVOT by connective tissue.


The LV summit is an interesting entity, and this region is being increasingly recognized as a source of epicardial IVTs. The LV summit is the triangular epicardial aspect of the most superior portion of the LV extending cephalad to the aortic portion of the LV ostium and is bounded by the origin of the left anterior descending (LAD) artery and left circumflex coronary artery (LCx). The base of this triangle is defined by the first septal perforator of the LAD, and this triangular region is bisected by the anterior interventricular vein (AIV). As will be discussed later, the close proximity of the epicardial coronary vessels make it particularly challenging to target IVT originating from the LV summit region.


Within the OTVT region, the sources of these arrhythmias show a predilection for certain locations. Thus in one study, approximately 80% of RVOT tachycardias were localized to the superior anteroseptal aspect just below the pulmonic valve. Similarly, LVOT tachycardias have been found to originate from a narrow location that includes the LCC and RCC, the bordering aspects of LV ostium (septal parahissian, aorto-mitral continuity [AMC], and the superior mitral annulus), and the adjoining LV summit region. In the entire outflow tract region almost 90% of idiopathic tachycardias seem to originate from a fairly narrow anatomic zone. This observation raises an interesting question about why this location is predisposed to triggered activity. It is conceivable that this may be related to of its embryologic origin (from neural crest cells). However, it remains unclear whether this tissue is naturally present in all individuals and manifests arrhythmias in a select few, or if it is only seen in those patients that subsequently develop OTVTs. Alternatively, predisposition to OTVTs may be the result of an acquired inflammatory process, such as subclinical myocarditis resulting in fibrosis that can disrupt the perivalvular tissue, thus isolating myocardial cell groups, which in turn may develop abnormal resting or threshold membrane potentials thereby promoting abnormalities of impulse formation (triggered activity and/or abnormal automaticity).




Diagnosis


Electrocardiographic Patterns and Anatomic Localization


Because OTVTs have a focal source and occur in patients with structurally normal hearts, their site of origin can usually be predicted by the standard 12-lead ECG. However, given the narrow anatomic zone from which OTVTs originate, coupled with anatomic variations (especially with regard to the heart position within the chest cavity), electrocardiographic overlap between adjacent sites exists and accurate localization requires invasive mapping. Nevertheless, understanding ECG patterns of OTVTs is a useful tool for arrhythmia localization and procedure planning.


The classic ECG profile of RVOT tachycardia is a left bundle branch block (LBBB) pattern with inferior axis evidenced by tall R waves in leads II, III, and aVF, and QS complexes in aVR and aVL. Fig. 28.2 shows common sites of origin of OTVTs in relation to the precordial leads V 1 -V 3 and limb lead I. Because lead V 1 is a unipolar right-sided lead, tachycardias originating from the anterior (free wall) RVOT propagate posteriorly and away from V 1 , creating a predominantly negative or LBBB pattern. Tachycardias originating further posteriorly and leftward (septal aspect) in the RVOT region while still having an LBBB pattern usually manifest a small R wave preceding the large S wave in lead V 1 . Because of the continuity between the posterior RVOT and the anterior LVOT, a similar small R wave (preceding the S wave) in lead V 1 can be seen with tachycardias originating in the RCC region. Further posterior or leftward from the RCC is the AMC and tachycardias originating from this region show more prominent R waves, which are preceded by a small q wave. In the authors’ experience, this qR pattern in lead V 1 together with inferiorly directed axis is pathognomonic of tachycardia origin from an AMC location. Further posterior or leftward to the AMC sits the LCC, and tachycardias originating from this location usually manifest prominent R waves in V 1 . Beyond the LCC is the mitral annulus, and tachycardias originating from this region usually manifest large monophasic R waves in lead V 1 .




Fig. 28.2


Relationship between outflow tract anatomy and electrocardiogram morphology. The RVOT free wall is the most anterior structure, immediately beneath the precordial leads V1−V3. As such, arrhythmias originating from the RVOT free wall are predominantly negative across the precordium. Moving posteriorly toward the spine (from septal RVOT to RCC, LCC, aorto-mitral continuity, and superior mitral annulus, the activation wave front moves increasingly more toward the precordial leads resulting in more positivity in V1 and earlier precordial transition. The RVOT site 1 is the most leftward, thus generating a positive complex in lead I, whereas RVOT site 3 is the most rightward and generates a negative complex in lead I. LCC, left coronary cusp; RCC, right coronary cusp; RVOT, right ventricular outflow tract

From Liang JJ, Han Y, Frankel DS. Ablation of outflow tract ventricular tachycardia. Curr Treat Options Cardio Med 2015:17:363. With permission from Springer.


Other leads can also be helpful in localizing OTVTs. The ratio of QRS complexes in leads aVR and aVL was found to be useful in predicting the relatively superior or inferior location of the tachycardia source within the outflow tract region. In general, leads aV R and aV L being located at the respective shoulders, usually manifest prominent negative (QS) complexes for OTVTs. However, for tachycardias originating at a lower level in the RVOT (near the His-bundle region), complexes in lead aV L become progressively less negative or even isoelectric to positive, whereas complexes in lead aV R remain negative. Conversely, when the source of the tachycardia is leftward and in the superior most aspect of the outflow tract (such as above the pulmonic valve), complexes in lead aV L may be more negative than complexes in lead aV R . Similarly, the ratio of R waves in leads II and III can also help differentiate a more superior from an inferior location of tachycardia sources within the outflow tract region. Interestingly, for OTVTs, QRS complexes in leads II and III are usually mirror images of those in leads aV R and aV L, respectively.


Although the 12-lead ECG is extremely helpful in localizing the site of origin of OTVTs, it is important to verify accurate ECG lead position because even minor changes in the location of certain leads can substantially alter the morphology of QRS complexes recorded by those leads. This is particularly true for precordial leads V 1 and V 2 as well as limb lead I. It is not uncommon for precordial leads V 1 and V 2 to be misplaced an intercostal space higher or lower than their standard location (fourth intercostal space). Similarly, the electrodes for limb lead I can sometimes be displaced from the shoulder to the nearby upper chest area. These lead displacements are particularly common during exercise test protocols (done to evoke outflow tract ventricular arrhythmias) or during electrophysiology study (to accommodate the precordial defibrillation pads). Such minor changes in lead placement have been shown to alter the morphology of QRS complexes significantly, which in turn can affect the accuracy of the ECG to localize the site of origin of the clinical arrhythmia. Thus superior displacement of precordial leads V 1 and V 2 can result in reduced R wave amplitude and R/S ratio, whereas inferior displacement of these leads can increase R wave amplitude and the R/S ratio ( Figs. 28.3A and B ). It is thus conceivable that in a case in which VT is originating from the cusp region, if leads V 1 and V 2 are misplaced superiorly resulting in reduced R wave amplitude and lower R/S ratio of QRS complexes, then the tachycardia origin may be erroneously localized to the RVOT region. Similarly, for tachycardias originating in RVOT, if leads V 1 and V 2 are misplaced inferiorly, then because of increased R wave amplitude and R/S ratio, the source may be erroneously localized to the cusp region. It was also found that anterior displacement of the upper limb leads from shoulders to the adjacent upper chest/torso can significantly reduce the R wave amplitude and/or even reverse the QRS polarity in limb lead I ( Fig. 28.3C ). This alteration in QRS morphology can influence one’s ability to distinguish anterior/leftward accurately from posterior/rightward location of the tachycardia source in the superior RVOT region.




Fig. 28.3


The effect of vertical displacement of precordial leads V 1 and V 2 on the premature ventricular complex (PVC) morphology. PVCs were originating from the anterior free wall of superior right ventricular outflow tract (A), and the junction of the left and right coronary cusp regions (B) was serially recorded with leads V 1 and V 2 in the fourth intercostal space (normal), third intercostal space (superior), and fifth intercostal space (inferior). Superior displacement of leads resulted in decrease of R wave amplitude, whereas inferior displacement resulted in more prominent R wave amplitude in these leads. C, Influence on displacement of leads from the shoulder to the bordering chest wall on QRS morphology in limb lead I. In this case, with leads on the shoulder, lead I shows notched R wave, whereas with leads on the bordering chest wall, the complex changes to an rS morphology in lead I. See text for details. VT, Ventricular tachycardia.


Clinical Arrhythmias from Right Ventricular Outflow Tracts


To characterize electrocardiographic patterns of RVOT tachycardias, our group has previously created a numbering system dividing the RVOT into nine distinct anatomic sites ( Fig. 28.4A ). Sites 1 to 3 are the most superior anatomic sites below the pulmonic valve in a posterior to anterior orientation. Sites 4 to 6 and 7 to 9 are respectively the two rows below from an outflow to inflow orientation. This numerical site classification from 1 to 9 is applied separately to the septal and free wall aspects of the RVOT.




Fig. 28.4


Schematic representation of the right ventricular outflow tract (RVOT). A, Locations of the nine standard mapping sites along the septal RVOT are shown in right anterior oblique projection (RAO). Sites 1 to 3 represent the first row of sites underneath the pulmonic valve in an anterior to posterior orientation. B, The RVOT in a coronal projection depicting sites 1 to 3 along the septal and the free-wall aspects of the superior RVOT. Site 1 is posterior and rightward relative to site 3, which is anterior and leftward; site 2 is between these. The QRS complex morphology in multiple leads can help localize tachycardia origin from these sites. See text for details. FW, Free wall; LCC, left coronary cusp; NCC, noncoronary cusp; PV, pulmonic valve; RCC, right coronary cusp; RV, right ventricle; TV, tricuspid valve.


The vast majority of RVOT arrhythmias arise from its most superior aspect, just below the pulmonic valve. Therefore the ECG characteristics of these anatomic sites were studied in detail in 14 patients with structurally normal hearts. Under guidance with an electroanatomic mapping system, a 4-mm mapping catheter was carefully positioned serially at sites 1 to 3 in both the RVOT septum and free wall ( Fig. 28.4B ) and pace mapping from each site was performed. Fig. 28.5 shows pace maps from all six superior RVOT sites. Pace maps from septal sites manifested monophasic R waves in the inferior leads, which were taller and narrower in comparison with those over the corresponding free-wall sites ( Fig. 28.6A ). The duration of the R wave in lead II was specifically analyzed, and at septal sites this was found to be significantly shorter when compared with R wave at corresponding free wall locations ( Fig. 28.6B ). In addition, the contour of the R wave in the inferior leads was helpful in differentiating between pace maps of septal and free wall locations in the superior RVOT. Typically, R waves from free wall sites demonstrated characteristic notching, which was uncommon in corresponding septal locations (see Fig. 28.5 ). The precordial QRS transition too was helpful in distinguishing septal from free wall locations in the superior RVOT. In this series, the combination of late precordial transition (at or beyond lead V4) and notching of the R wave in the inferior leads was found to be a sensitive and specific ECG criterion for identifying tachycardias originating from the free wall aspect of superior RVOT.




Fig. 28.5


Sample 12-lead electrocardiogram pace maps from sites 1 to 3 along the septum and free-wall aspects of the right ventricular outflow tract (RVOT). Sites were tagged on an electroanatomic shell (CARTO; Biosense Webster, Diamond Bar, CA) displayed in the center of the figure in a coronal projection. The pace maps from septal RVOT sites 1 to 3 are shown to the left of the shell and those from the free-wall sites 1 to 3 are shown to the right of the map. Pace maps from all sites displayed left bundle branch block morphology with an inferior frontal plane axis. The R waves in the inferior leads (II, III, and aV F ) were taller and narrower for pace maps from septal sites as compared with the corresponding free wall sites. In addition, the precordial QRS transition was later for free wall sites when compared with septal locations. Transition from anterior to posterior sites over both the septal and free wall aspects of the RVOT resulted in increasing R wave amplitude in lead I.



Fig. 28.6


Comparison of QRS amplitude and width in lead II between pace maps of septal and free wall right ventricular outflow tract (RVOT) sites 1, 2, and 3. Amplitude of the R wave is higher for pace maps from septal sites (A). Each line represents R wave amplitude (mV) at a specific site for an individual patient. The mean R wave amplitude is also shown. The R wave duration was also shorter for pace maps from septal RVOT compared with the corresponding free wall sites (B). Each line represents R wave duration (ms) at a specific site for an individual patient. The mean R wave duration is also shown.


The QRS morphology in limb lead I can be helpful in distinguishing anterior or leftward locations from posterior or rightward locations in the superior RVOT region. Lead I manifests a positive polarity ( R wave) for pace maps and tachycardias originating from posterior or rightward locations (site 1), whereas for pace maps and tachycardias originating from anterior or leftward aspect of the superior RVOT (site 3), complexes in lead I manifest negative polarity (QS pattern). This applies to both the septal and free wall aspects ( Fig. 28.7 ). Site 2, midway between the anterior and posterior RVOT, typically displays either a biphasic or a multiphasic QRS pattern in limb lead I (see Fig. 28.7 ). Table 28.1 summarizes the ECG criteria to localize arrhythmias in the superior RVOT origin.




Fig. 28.7


Electrocardiogram (ECG) morphologies of tachycardias that were successfully ablated in the superior right ventricular outflow tract (RVOT). The left-hand side of the figure displays the 12-lead ECG morphology of characteristic septal RVOT tachycardias from sites 1 through 3, whereas the right-hand side of the figure displays the ECG morphology of characteristic free wall RVOT tachycardias from sites 1 and 3. Tachycardias originating from free wall show notching in the inferior leads and late precordial transition (≥V 4 ). In comparison, tachycardias originating from septal RVOT have earlier precordial transition and lack notching of the R wave in the inferior leads. For both septal and free wall tachycardias, lead I helps distinguish anterior (leftward) from posterior (rightward) location. See text for details.


TABLE 28.1

Diagnostic Criteria















RVOT source


  • Septal



  • Free wall



  • Anterior sites



  • Posterior sites

LBBB pattern; R wave transition after V 3 ; tall R in leads 2, 3, aV F


  • Absence of notching in leads 2, 3, aV F ; precordial transition < V 4



  • Presence of notching in leads 2, 3, aV F ; precordial transition ≥ V 4



  • Negative lead 1



  • Positive lead 1

Coronary cusps


  • Left coronary cusp



  • Right coronary cusp



  • Left–right junction

Strongly inferior axis; precordial transition earlier than in NSR


  • m or w pattern in V 1



  • QS or rS pattern in V 1



  • QS pattern, with notching on downstroke, in V 1

Aorto-mitral continuity RBBB, inferior axis, qR pattern in V 1
LV summit Inferior axis, delayed upstroke in lead 2, QS in lead 1, R/S ratio in V 2 < 1

LBBB , Left bundle branch block pattern; LV , left ventricle; NSR , normal sinus rhythm; RBBB , right bundle branch block pattern; RVOT , right ventricular outflow tract.


In older reports, the site of origin of RVOT tachycardia was infrequently (approximately 4% to 6%) found to be above the plane of the pulmonic valve. However, subsequent studies have suggested that the incidence of supravalvular foci from the pulmonary artery may be higher than previously thought. The myocardial sleeves extending beyond the pulmonic valve into the pulmonary artery are the likely source of such supravalvular foci. In that context it is interesting to note that although Hasdemir et al. previously reported a 17% incidence of suprapulmonic muscular sleeves in autopsied hearts, Gami et al. subsequently reported a much higher (73%) incidence. Using electroanatomic voltage mapping and intracardiac echocardiography (ICE), Liu, et al. have also demonstrated that sleeves of myocardial tissue extended above the pulmonic valve in approximately 90% of patients. These supravalvular tachycardias have been shown to manifest LBBB morphology with intermediate, right, or vertical frontal plane axes and a precordial transition in V 2 or later. Compared with RVOT tachycardias arising below the pulmonic valve, tachycardias from the pulmonary artery may have greater R wave amplitude in the inferior leads. Another clue supporting suprapulmonic valve origin is a taller R wave in lead III compared with lead II, which is likely because of more leftward orientation of the suprapulmonic valve compared with the infrapulmonic valve location in the RVOT (see Fig. 28.1 ). However, because of considerable overlap, there are no unique characteristic ECG features that can consistently and reliably differentiate the source of OTVT as being from above or below the pulmonic valve. Lead I can be helpful in differentiating between RCC versus a suprapulmonic valve site of origin. Because the distal RVOT and pulmonic valve are situated relatively leftward of the aortic root and RCC, tachycardias originating in the latter location manifest a relatively large R wave in lead I. Ablation of suprapulmonic sites of origin was usually performed within 5 to 21 mm above the pulmonic valve. At the successful ablation sites, a low-amplitude, sharp (or multicomponent), presystolic electrical potential (preceding the QRS onset by 28.2 ± 2.9 ms) was usually noted during the clinical arrhythmia. Although aortic cusp VAs frequently manifest early activation as isolated presystolic potentials with mismatched unipolar and bipolar timing, pulmonic cusp VAs tend to have simultaneous earliest ventricular activation in unipolar and bipolar recordings at the site of successful ablation. In sinus rhythm, the successful ablation site usually manifested a small far-field atrial signal. In one study, a standard 4-mm-tip radiofrequency (RF) catheter was used for pulmonary artery OTVT ablation, and in this series the investigators delivered power for up to 60 to 90 seconds using a temperature cut-off at 55°C. In another study, a 3.5-mm-tip open-irrigation catheter was used with maximum power delivery of 40 W, temperature not to exceed 43°C, a flow rate of 20 mL/min, and energy delivery duration of 60 seconds.


Clinical Arrhythmias From Basal Left Ventricle


In the authors’ experience, idiopathic arrhythmias originating from the basal LV constitute approximately 10% to 20% of OTVTs. The basal LV includes the septum, inferior, anterior, and lateral walls bordering the mitral valve. The aortic valve is typically positioned at 30-degree angle superior to the mitral valve in close proximity to this region and is a part of the LV ostium (as discussed earlier).


When targeting tachycardias originating from the basal LV, it is helpful to create a detailed electroanatomic map of this region at the outset. The following protocol is recommended: the planes of mitral and aortic valves should be well defined. Using a retrograde aortic approach, the aortic valve is crossed, and the mapping catheter is positioned in the mitral annulus such that the distal pair of electrodes records a large ventricular electrogram preceded by a smaller or equal-size atrial electrogram. In this orientation, at least three distant anatomic points along the mitral annulus (medial, lateral, and superior or inferior) are acquired. Next, the catheter is retracted into the aorta and then advanced down to the aortic valve, where the individual cusps (RCC, LCC, and NCC) are mapped. Orthogonal fluoroscopy and ICE are useful when mapping this region ( Fig. 28.8 ). The utility of the latter imaging technique is significantly enhanced by the ability of some 3-dimensional electroanatomic systems to rapidly create a shell of the chamber of interest (CARTOSOUND, Biosense Webster, Diamond Bar, CA), which can be quite helpful in localizing the aortic and mitral valves. After careful delineation of the mitral and aortic valves including the aortic cusps, the catheter is advanced into the LV and multiple evenly distributed anatomic points (≥100) are acquired to create an endocardial geometric shell of the LV with emphasis on its basal portion.


Feb 21, 2019 | Posted by in CARDIOLOGY | Comments Off on Ablation of Ventricular Outflow Tract Tachycardias

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