Clinical application of an integrated 3-phase mapping technique for localization of the site of origin of idiopathic ventricular tachycardia

BACKGROUND: Radiofrequency (RF) catheter ablation provides curative treatment for idiopathic ventricular tachycardia (VT). METHODS AND RESULTS: Nineteen consecutive patients with an idiopathic VT underwent RF catheter ablation. An integrated 3-phase mapping approach was used, consisting of the successive application of online 62-lead body surface QRS integral mapping, directed regional paced body surface QRS integral mapping, and local activation sequence mapping. Mapping phase 1 was localization of the segment of VT origin by comparing the VT QRS integral map with a database of mean paced QRS integral maps. Mapping phase 2 was body surface pace mapping during sinus rhythm in the segment localized in phase 1 until the site at which the paced QRS integral map matched the VT QRS integral map was identified (ie, VT exit site). Mapping phase 3 was local activation sequence mapping at the circumscribed area identified in phase 2 to identify the site with the earliest local endocardial activation (ie, site of VT origin). This site became the ablation target. Ten VTs were ablated in the right ventricular outflow tract, 2 at the basal LV septum, and 7 at the midapical posterior left ventricle. A high long-term ablation success (mean follow-up duration, 14+/-9 months) was achieved in 17 of the 19 patients (89%) with a low number of RF pulses (mean, 3.3+/-2.2 pulses per patient). CONCLUSIONS: This prospective study shows that integrated 3-phase mapping for localization of the site of origin of idiopathic VT offers efficient and accurate localization of the target site for RF catheter ablation.     

Case Report: Alternating Exit Sites in Reentry Circuit of Ventricular Tachycardia with Nonischemic Cardiomyopathy – Relationship between Ablation Site and Inner Loop

We present a patient with nonischemic cardiomyopathy who had ventricular tachycardia (VT) with QRS morphology alternans. VTs of two QRS morphologies (VT1 and VT2) exhibiting a right bundle branch block pattern with inferior axis was induced by ventricular pacing. The morphology of the QRS complex during VT1 exhibited more distinctively inferior axis than those during VT2. Induced VTs had similar morphologies to clinically the documented VTs. Pacemapping at anterolateral site of the left ventricle during sinus rhythm produced the same QRS complex of VT1 in a surface 12-lead electrocardiogram. A mapping study was performed with an electrode catheter located at the same site of LV during sustained VT1. The analysis of the local electrograms and postpacing interval during concealed entrainment at the catheter mapping revealed this pacing site was at the inner loop of the reentry circuit. Radiofrequency catheter ablation was performed at this site. The morphology of VT1 changed to different QRS morphology (VT2) during the first delivery of radiofrequency energy and was terminated after 20 seconds of the application. Then VT with alternans of QRS morphology and cycle length of VT1 and VT2 was induced by ventricular pacing, and was abolished by the second application of radiofrequency energy at this same site, suggesting that this site was located in the exit site close to inner loop of the reentry circuit and the alternans of QRS morphology was linked to the change of exit site.     

Gitelman's syndrome with exercise-induced ventricular tachycardia.

A 62-year-old female with palpitations was admitted to hospital where she recorded 12,299 monofocal ventricular premature contractions (VPCs) in 24 h and nonsustained ventricular tachycardia (VT) on exertion. She had hypokalemia with renal potassium wasting, a chloride-resistant metabolic alkalosis, elevated plasma renin, elevated plasma aldosterone (relative to the serum K concentration), hypomagnesemia with renal magnesium wasting, decreased urine calcium excretion, and normal blood pressure. The hypokalemia and hypomagnesemia were thought to have precipitated the VT. The coronary angiogram showed normal coronary arteries; however, the left ventriculogram revealed akinesis of the posterolateral wall. Because the VT could not be induced by programmed electrical stimulation either before or during intravenous administration of isoproterenol, the VPC with the same QRS morphology as the VT became the target of radiofrequency catheter ablation (RF-CA). Intracardiac mapping showed that the earliest activation site was situated in the asynergic area of the left ventricle (LV) and radiofrequency catheter ablation directed at the LV asynergy area completely eliminated the VPCs without any complications. During the follow-up period (6 months), she was free from palpitation and VT was not clinically documented.     

Epicardial Macro-Reentrant Ventricular Tachycardia Exhibiting an Endocardial Centrifugal Activation Pattern in a Case with Arrhythmogenic Right Ventricular Cardiomyopathy

A 55-year-old man with arrhythmogenic right ventricular cardiomyopathy underwent catheter ablation of ventricular tachycardia (VT) with left bundle branch block and left superior axis QRS morphology with an early precordial transition. Endocardial mapping during the VT revealed a focal activation pattern from a small region of low voltage in the left ventricular (LV) septum. Despite earliest endocardial activation in the LV septum, epicardial mapping demonstrated a macro-reentrant circuit with successful catheter ablation at an inferior peritricuspid annular site. Activation from the reentrant circuit propagated through the scar area in the epicardial right ventricle to the remote endocardial LV breakout site.     

Radiofrequency catheter ablation of upper septal idiopathic left ventricular tachycardia exhibiting left bundle branch block morphology

Idiopathic left ventricular (LV) tachycardia usually exhibits right bundle branch block morphology. There are only a few sporadic cases that exhibit left bundle branch block (LBBB) morphology. We report a patient whose QRS complex during ventricular tachycardia (VT) was relatively narrow (100 msec) and exhibited LBBB (precordial R wave transition between V3 and V4) and a normal frontal plane axis. This VT was ablated successfully by radiofrequency current applied to the LV upper septum, where the earliest endocardial activation was recorded.     

Determinants of inducibility of ventricular tachycardia

We analyzed the incidence and predictive factors for induction of clinical ventricular tachycardia (VT) during an electrophysiologic study in 127 patients with structural heart disease and spontaneous VT documented by 12-lead electrocardiography. Eighty-five patients had coronary artery disease (CAD), 24 had idiopathic dilated cardiomyopathy (IDC), and 18 had right ventricular dysplasia (RVD). Clinical variables were age, gender, electrocardiographic patterns of spontaneous arrhythmia, cardiac diagnosis, left ventricular (LV) ejection fraction (EF), infarct location, and presence of LV aneurysm. Clinical VT was induced in 76 patients (60%, group 1) and was not induced in 51 patients (group 2). Clinical VT was induced in 83% of patients with RVD, 58% of patients with CAD, and 50% of patients with IDC (p = 0.07). LVEF tended to be significantly higher in group 1 than in group 2 (p = 0.06). The presence of left QRS axis in the frontal plane during spontaneous VT was significantly associated with a higher inducibility both in the general group (69% vs 46%, p <0.02) and in patients with CAD (70% vs 44%, p <0.02). In patients with CAD, only the presence of a left QRS axis was significantly associated with a higher inducibility. A multivariate analysis identified only the left QRS axis as a significant and independent predictor of induction of clinical VT. The association of a leftward axis with inducibility suggests that vectorial factors in the depolarization wavefronts may be related to inducibility since conventional stimulation is performed from the right ventricle, producing a leftward axis in most cases.     

Usefulness of QRS prolongation in predicting risk of inducible monomorphic ventricular tachycardia in patients referred for electrophysiologic studies

QRS prolongation on surface electrocardiography has been identified as a marker for increased cardiac mortality. A potential mechanism for increased mortality is ventricular tachycardia (VT). This study aimed to evaluate the relation between bundle branch block and sustained monomorphic VT inducibility in patients referred for electrophysiologic studies. We analyzed a cohort of 777 patients (age 63 +/- 18 years, 67% men, left ventricular [LV] ejection fraction [EF] 45% +/- 16, prior myocardial infarction 41%) referred for electrophysiologic studies between 1994 and 2001 who underwent programmed stimulation for VT. Forty-five percent of patients were referred for syncope or a history of VT and/or ventricular fibrillation. Thirty-one percent of patients had prolonged QRS duration (> or =120 ms). Patients with prolonged QRS duration were older, had lower LVEFs, and were more likely to have a history of myocardial infarction. Prolonged QRS was a significant predictor of sustained monomorphic VT inducibility (p <0.0001). On multivariate analysis correcting for age, sex, LVEF, history of myocardial infarction, medications, and QRS conduction delay proved to be independently associated with sustained monomorphic VT inducibility (relative risk 3.290, 95% confidence interval 2.185 to 4.953 for prolonged vs normal QRS duration). Thus, a prolonged QRS duration on surface electrocardiography is a strong, independent predictor of inducible sustained monomorphic VT. Conduction delay may be an important risk factor, providing a substrate for the development of reentrant monomorphic VT, and furthermore suggests a potential mechanism for the increased mortality observed in patients with prolonged QRS.     

The Origin of Epicardial Ventricular Tachycardia Revealed by Entrainment From a Permanent Epicardial Left Ventricular Pacing Lead

Entrainment From Left Ventricular Pacing Lead. Recognizing ventricular tachycardias (VTs) that require epicardial ablation is desirable, but challenging when prior surgery prevents percutaneous epicardial mapping. This patient had cardiomyopathy, prior cardiac surgery, and VT that failed endocardial ablation. Observing that the Bi‐V implantable cardioverter defibrillator (ICD), left ventricular (LV) lead was epicardial to the area of infarct scar, it was used to pace during VT. Entrainment with concealed fusion with long stimulus to QRS interval, consistent with an epicardial VT circuit, was observed. Surgical cryoablation targeting the area around the LV lead eliminated VT. Thus pacing maneuvers from permanent epicardial leads can occasionally help identify an epicardial VT origin. (J Cardiovasc Electrophysiol, Vol. 21, pp. 1293‐1295, November 2010)     

伴右心室出口的左心室起源缺血性室性心动过速的标测和消融

目的折返性的缺血性室性心动过速（VT）绝大多数发生于左心室并表现为右束支阻滞（RBBB）图形。本文报道1组VT折返环位于左心室但出口在右心室且表现为左束支阻滞（LBBB）的病例。方法32例因陈旧性心肌梗死伴VT而接受电生理检查和射频消融的患者,其中4例临床有LBBB形态的VT。使用非接触等电位和虚拟单极标测判断VT起源,结合舒张中期电位（MDP）和拖带标测确定折返关键通路和消融靶点。用盐水冲洗电极导管在折返环的关键峡部行线性消融。结果全部32例患者中,4例临床有LBBB型VT者均成功被诱发,其中1例有两种LBBB型VT,1例同时有RBBB型VT但周长与LBBB型相同;另有1例共有6种形态的VT,包括RBBB和LBBB型。在右心室内的非接触式等电位标测可迅速确定VT在右心室的传出部位,该处的虚拟单极标测显示rS型提示左心室起源。3例在左心室成功拖带并消融成功,靶点均紧邻左心室间隔,其中1例位于下壁,1例在前壁,1例两种LBBB型VT分别在前壁和下壁间隔旁消融成功。随访1～4．2年,未服抗心律失常药无VT发作。而1例诱发出6种单形（包括RBBB和LBBB型）VT患者因巨大室壁瘤及心功能障碍不能耐受而中途放弃消融。结论紧邻室间隔的前壁和下壁心肌梗死后的左心室起源VT可能因在右心室有出口而表现为LBBB型,需要在标测和消融时予以注意。     

Delayed Enhancement on Cardiac Magnetic Resonance and Clinical,Morphological, and Electrocardiographical Features in Hypertrophic Cardiomyopathy

BackgroundThe clinical, morphological, and electrocardiographical relevance of delayed enhancement (DE) in cardiac magnetic resonance (CMR) was studied in patients with hypertrophic cardiomyopathy (HCM).Methods and ResultsA total of 56 patients underwent both gadolinium-enhanced CMR and 12-lead electrocardiogram. The CMR demonstrated DE at the left ventricular (LV) wall in 39 patients. The patients with DE included more cases with dilated phase of HCM, higher New York Heart Association (NYHA) classes and incidence of ventricular tachyarrhythmias (VT), lower LV ejection fraction (LVEF) and mean LV wall thickness (WT), and a larger ratio of maximum to minimum LVWT. The QRS duration was prolonged and the QRS axis deviated toward left with increases in the DE volume (r = 0.58 and r = 0.41, P < .01). Abnormal Q waves were present in 5 patients and the location coincided with the DE segments in 4 patients, but the concordance was not significant. The amplitude of T waves correlated with the ratio of the apex to basal LVWT (r = 0.38, P < .01) and was more negative in cases with DE at the apex.ConclusionsIn HCM, the DE was associated with higher NYHA classes and prevalence of VT, impaired global LV function and asymmetrical hypertrophy, and conduction disturbance, abnormal Q waves, and giant negative T waves.     

Cure of Interfascicular Reentrant Ventricular Tachycardia by Ablation of the Anterior Fascicle of the Left Bundle Branch

Ablation of Interfascicular Reentrant Tachycardia. Introduction: Fascicular reentrant ventricular tachycardia (VT) using the anterior fascicle of the left bundle anterogradely is rare and may produce identical QRS morphology during sinus rhythm and VT. Catheter ablation of this type of VT has not been described in detail.
Methods and Results: In a postinfarct patient with dilated left ventricle and recurrent VT (showing a QRS configuration of right bundle branch, left posterior fascicular block), endocardial recordings from the His-Purkinje system showed that VT was due to interfascicular reentry. Induction of VT occurred after progressive retrograde conduction delay on increasing the prematurity of the extrastimulus. Anterograde conduction occurred exclusively over the left anterior fascicle, which caused identical QRS morphology during sinus rhythm and VT. During VT, the left posterior fascicle was used retrogradely. The usual target for bundle branch reentry ablation, the right bundle, did not participate in the reentrant circuit. While performing left ventricular endocardial mapping, VT was interrupted when positioning the catheter on the left anterior fascicle, and "reversed" nonsustained bundle branch reentry occurred with anterograde conduction over the posterior fascicle and retrograde conduction over the anterior fascicle. Ablation of conduction in the anterior fascicle led to cure of the VT.
Conclusion: Interfascicular reentrant VT with right bundle branch block, right-axis QRS configuration can be cured by catheter ablation of anterior fascicle conduction.     

Idiopathic sustained left ventricular tachycardia: clinical and electrophysiologic characteristics

Electrophysiologic studies were performed in 16 patients 11 to 45 years old (mean 33 years) with idiopathic sustained (lasting more than 5 min) ventricular tachycardia (VT) originating from the left ventricle. Endocardial mapping during VT showed that the earliest site of activation was at the apical inferior portion of the left ventricle in 14 patients whose QRS morphology during VT showed a right bundle branch block pattern and left-axis deviation, but at the apical anterosuperior portion of the left ventricle in two patients whose QRS morphology during VT showed a right bundle branch block and right-axis deviation. Single programmed ventricular stimulation induced VT in 13 patients, and rapid ventricular pacing induced VT in the remaining three patients. Rapid ventricular pacing terminated VT in all patients. The relationship between the coupling interval and the echo interval was inverse in all eight patients with a wide VT inducible zone. Entrainment was recognized in three of six patients. The initiation of VT by constant pacing depended on the number of pacing beats but not the duration of pacing in all four patients tested. Intravenous verapamil terminated the VT in 13 of 14 patients. Long-term oral verapamil was also effective in all five patients who required long-term oral therapy for their symptoms associated with VT. In conclusion (1) idiopathic left ventricular tachycardia has unique electrocardiographic, electrophysiologic, and electropharmacological properties, (2) the electrophysiologic characteristics suggest that the mechanism is reentry, and (3) verapamil is effective in both the short- and long-term treatment of VT.     

Randomized, placebo-controlled evaluation of lidoflazine in patients receiving beta-blocker therapy with propranolol: improvement in anginal symptoms and exercise tolerance with combined drug therapy

To evaluate the timing of the right ventricular (RV) apical electrogram in relation to the QRS complex during ventricular tachycardia (VT), 94 episodes of sustained uniform VT were analyzed in 56 patients. The timing of the RV apical electrogram varied and could be recorded from 33 ms before to 180 ms (mean 77 +/- 44 ms) after the onset of the QRS complex. The timing of the RV apical electrogram, expressed both as an absolute value and as a percentage of a QRS width, was significantly different when right bundle branch block (BBB) morphology VT (95 +/- 37 ms) and left BBB morphology VT (40 +/- 341) were compared (p less than 0.001). The timing of the RV apical electrogram, expressed as a percentage of the QRS width, was significantly different when VT with different axes were compared in the right BBB VT group (p less than 0.01). A left BBB VT, as compared to a right BBB VT, predicted an RV apical electrogram occurring in the first 35% of the QRS with a sensitivity of 74%, a specificity of 91%, and a positive predictive value of 84%. Right BBB VT with a right and inferior axis were usually associated with the latest occurring RV apical electrogram. A right BBB VT with a right and inferior axis predicted an RV apical electrogram inscribed in the latter half of the QRS with a sensitivity of 65%, a specificity of 84% and a positive predictive value of 80%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Area of left ventricular regional conduction delay and preserved myocardium predict responses to cardiac resynchronization therapy

Cardiac resynchronization therapy. BACKGROUND: A significant proportion of patients with dilated cardiomyopathy and left bundle branch block (LBBB) do not respond to cardiac resynchronization therapy (CRT). The purpose of this study was to investigate whether the electromechanical properties of the myocardium would predict acute hemodynamic improvement during left ventricular (LV) pacing. METHODS AND RESULTS: We studied 10 patients with idiopathic dilated cardiomyopathy and LBBB (ejection fraction (EF): 27%+/-7%; QRS duration: 166+/-16 msec) using three-dimensional electromechanical endocardial mapping technique to assess endocardial activation time (Endo-AT), unipolar voltage, and local linear shortening during sinus rhythm. LV stimulation was performed in VDD mode at five different sites and three atrioventricular delays within the coronary sinus. LV+dP/dtmax changes from baseline were measured during LV stimulation at each site (%DeltadP/dtmax). There was no significant relationship between maximum %DeltadP/dtmax during LV stimulation at the best coronary sinus site and LV EF, baseline LV+dP/dtmax, total LV Endo-AT, baseline QRS duration nor changes in QRS duration during LV pacing. However, the maximum %DeltadP/dtmax was significantly positively correlated with percentage area of late Endo-AT (r=0.97, P<0.001) and preserved LV myocardium (r=0.81, P=0.005), respectively. Patients with >20% of LV area with late Endo-AT and >30% of preserved LV myocardium had five times better acute hemodynamic response with LV stimulation. Multivariate analysis showed that only percentage area of late Endo-AT was independently correlated with %DeltadP/dtmax (P<0.05). CONCLUSION: The presence of a larger amount of LV area with late Endo-AT and preserved LV myocardium measured by electromechanical mapping could identify patients who have better acute improvement in systolic performance during LV stimulation.     

Sequential regional phase mapping of radionuclide gated biventriculograms in patients with sustained ventricular tachycardia: Close correlation with electrophysiologic characteristics

Radionuclide (RNA) gated studies were performed during sinus rhythm and during spontaneous or induced sustained ventricular tachycardia (VT) in six patients with clinical VT. Fourier analysis of time-activity variation was used to calculate a RNA phase value for each pixel in the image. Color coding of each pixel according to its calculated phase resulted in a RNA phase map of the ventricles. The following results were considered to be consistent with the known electrophysiology of VT: (1) the phase map correlated with QRS morphology and axis in most but not all tachycardias; (2) earliest phase usually demonstrated the VT origin to be at the border of the ventricular wall motion abnormality; (3) endocardial mapping (available in one patient) showed close correlation with RNA phase mapping; (4) in three patients with ischemic heart disease, VT with left bundle branch block (LBBB) pattern had earliest LV phase along the septum; and (S) tornone patient imaged during two different VT morphologies, the tachycardias had earliest phase at different borders of the same wall motion abnormality with differing progression of phase across the ventricles. RNA phase mapping of VT is feasible and appears to provide data consistent with the electrophysiology of this arrhythmia.     

Successful transseptal catheter electrical ablation of sustained ventricular tachycardia of possible intramuscular origin.

Low-energy electrical ablation at 100 joules was attempted via a catheter in a patient with sustained ventricular tachycardia (VT) refractory to drug therapy. The patient was a 17-year-old woman who had undergone complete surgical correction of a double outlet right ventricle at the age of 9. The first episode of VT appeared at the age of 17. It was refractory to procainamide and lidocaine and it was sustained until termination with direct countershock. Two different QRS morphologies of VT were documented in the electrophysiologic study and one was identical to the VT observed in the clinical course. Conventional drug therapy failed to prevent induction of VT and catheter electrical ablation was attempted. The earliest activation site during the clinical episode of VT was localized to the right ventricular side of the interventricular septum (site 14-15), but pacing from this site resulted in a slightly different QRS morphology from that of VT. At the left ventricular side of this site (site 2), pacing during VT resulted in a QRS morphology identical to that of VT but the electrogram of this site did not precede the onset of the surface QRS complex. From these findings, the origin of VT was considered to be in the muscular layer of the interventricular septum. The method of transseptal shock using two catheters was applied and direct countershock at 100 joules successfully ablated the VT.     

Role of Purkinje fibers in post-infarction ventricular tachycardia.

OBJECTIVES: The objective of this study was to assess the role of Purkinje fibers in monomorphic, post-infarction ventricular tachycardia (VT). BACKGROUND: Ventricular fibrillation and polymorphic VT in the setting of acute myocardial infarction (MI) may be triggered by ectopy arising from Purkinje fibers. METHODS: From among a group of 81 consecutive patients with post-infarction monomorphic VT referred for catheter ablation, 9 patients were identified in whom the clinical VT had a QRS duration < or =145 ms. Mapping was performed focusing on areas with Purkinje potentials. RESULTS: A total of 11 VTs with a QRS duration < or =145 ms were induced and mapped in the 9 patients; 9 of the 11 VTs had a right bundle branch block/left-axis morphology that mimicked left posterior fascicular VT. The mean VT cycle length was 402 +/- 82 ms. Eight of 9 patients had a history of inferior MI involving the left ventricular septum. One patient had an anterior wall MI with septal involvement. Mapping during VT demonstrated re-entry involving the inferior left ventricular wall. In each of the VTs, a Purkinje potential was present at the exit site of the VT re-entry circuit. Single radiofrequency catheter ablation lesions were successful in eliminating these VTs in all patients. CONCLUSIONS: The Purkinje system may be part of the re-entry circuit in patients with post-infarction monomorphic VT, resulting in a type of VT with a relatively narrow QRS complex that mimics fascicular VT.     

Idiopathic verapamil-sensitive sustained left ventricular tachycardia

Idiopathic verapamil-sensitive left ventricular tachycardia (VT) has characteristic QRS configurations during VT: right bundle-branch block with either left axis or right axis (less common) deviation. QRS duration is relatively narrow (0.13-0.16s) and frequently endocardial activation prior to QRS is recorded during VT, which is the basis of its being called fascicular tachycardia. The mechanism is probably reentry, but the nature of the slow conduction necessary for the occurrence of reentry is quite different from that of other sustained monomorphic VT associated with structural heart disease. Chronic oral verapamil therapy is the drug of choice for alleviation of symptoms. Long-term prognosis is good.     

Left bundle branch block-type ventricular tachycardia originating from the left ventricular septum in a patient with cardiac sarcoidosis

This case report describes a left bundle branch block (LBBB)-type ventricular tachycardia (VT) with a unique reentrant circuit in a patient with cardiac sarcoidosis. The VT morphology and pace mapping supported an exit site of the VT from the basal posterior right ventricle (RV) septum. Nonetheless, concealed entrainment was established by pacing from a septal left ventricular (LV) site recording a diastolic potential, opposite site to the RV site. A point ablation at that LV site could successfully terminate the VT, suggesting that a critical isthmus was located on the LV side of the interventricular septum despite the demonstration of an LBBB-type VT.     

射频导管消融治疗的特发性室性心律失常心电图特征分析

目的：探讨不同起源的特发性室性期前收缩（PVCs）和（或）室性心动过速（VT）的心电图特征,提出鉴别流程。方法根据射频导管消融PVCs/VT有效靶点或心室最早激动点的X线胸片进行定位,分析不同起源PVCs/VT的12导联心电图QRS波群。结果828例接受导管消融,580例起源于右心室,248例起源于左心室,左、右心室起源者胸导联移行指数＜0的分别占97.58%及7.24%;左和右心室流出道起源者下壁导联多数呈R型,V1上,多数右心室流出道起源者呈rS型,右室间隔起源呈QS型,主动脉瓣上起源者常呈rS或RS型;下壁导联上,左前分支起源者常呈qR型,左后分支起源者常呈rS型。结论结合体表心电图胸导联移行指数、下壁导联和V1上的QRS波群特征可初步判断特发性PVCs/VT的起源部位。