Tachycardia Circuit

In the most common form (LPF-VT), the tachycardia circuit incorporates the LPF serving as one limb and abnormal Purkinje tissue with slow, decremental conduction serving as the other limb. The anterograde limb may be associated with longitudinal dissociation within the LPF or contiguous tissue that is directly coupled to the LPF (such as a false tendon) or, alternatively, has ventricular myocardium interposed. The zone of slow conduction appears to depend on the slow inward calcium current because the degree of slowing of tachycardia cycle length (TCL) in response to verapamil is entirely attributed to its negative dromotropic effects on the area of slow conduction.

The entrance site to the slow conduction zone is thought to be located closer to the base of the left ventricle (LV) septum. From there, activation propagates anterogradely (from basal to apical segments along the LV septum) over the abnormal Purkinje tissue with decremental conduction properties and verapamil sensitivity, which serves as the anterograde limb of the circuit and appears to be insulated from the nearby ventricular myocardium. The lower turnaround point of the reentrant circuit is located in the lower third of the septum, where the wavefront captures the fast conduction Purkinje tissue from or contiguous to the LPF, and retrograde activation occurs over the LPF from the apical to basal septum forming the retrograde limb of the reentrant circuit. In addition, at the lower turnaround point, anterograde activation occurs down the septum to break through (at the exit of the tachycardia circuit) in the posterior septal myocardium. The upper turnaround point of the reentrant circuit occurs over a zone of slow conduction located close to the main trunk of the left bundle branch (LB) in the basal interventricular septum ( Fig. 24.1 ). The estimated distance between the entrance and exit of the circuit is approximately 2 cm.

Schematic Illustration of the Reentrant Circuit in Fascicular Ventricular Tachycardia (VT) .

A block of the LV septum is depicted with the left posterior fascicle (LPF) and diastolic pathway (DP) running in parallel until they intersect at the bottom. A 10-pole catheter is shown recording between pathways; electrograms from each pair are shown along with surface electrocardiogram leads and His bundle recordings. (A) Activation sequence is shown during normal sinus rhythm (NSR) , the dashed line denotes QRS onset. Note the direction and speed of propagation over the LPF while the DP is activated after the QRS and in both directions (arrows) . (B) During VT complex, the DP is activated anterogradely and the LPF retrogradely (arrows) . See text for discussion.

Anatomy of the Left Fascicular System

The LB arises from the His bundle (HB) as numerous fine, intermingling fascicles that leave the left margin of the branching HB through most of its course along the crest of the muscular ventricular septum. The predivisional portion of the LB penetrates the membranous portion of the interventricular septum under the aortic ring and then divides under the septal endocardium into two branches: the LAF and the LPF. An estimated 65% of individuals have a third fascicle of the LB, the left median fascicle (LMF). The fascicles cascade down the LV septum in a fan-like configuration with extensive interconnections. Unlike the cord-like right bundle branch, the LB and its divisions are diffuse, fan-like structures that quickly arborize just beyond their origin. The LAF represents the superior (anterior) division of the LB, the LPF represents the inferior (posterior) division, and the LMF represents the septal (median) division.

The LB subdivisions extend to the midportion of the septum before they detach from the underlying endocardium and form free-running false tendons that traverse the ventricular chamber, projecting predominantly toward the papillary muscles. The fascicles become ramified in the ventricular apex and extend back along the ventricular walls toward the cardiac base.

The thin LAF crosses the anterobasal LV region toward the anterolateral papillary muscle and terminates in the Purkinje system of the anterolateral LV wall. The LPF appears as an extension of the main LB and is broad in its initial course. It then fans out extensively toward the posterior papillary muscle and terminates in the Purkinje system of the posteroinferior LV wall. The LMF runs to the interventricular septum; it arises in most cases from the LPF, less frequently from the LAF, or from both fascicles, and in a few cases it has an independent origin from the central part of the main LB at the site of its bifurcation.

Acute Management

Electrical cardioversion is required for VT termination in hemodynamically unstable patients. For stable patients with an established diagnosis of verapamil-sensitive fascicular VT, intravenous verapamil is the first-line treatment and is very successful in acutely terminating the VT. Intravenous verapamil slows the rate of VT progressively and then terminates it. Diltiazem is equally effective. Nonsustained VT may continue to occur for a while after termination.

Response of VT to lidocaine, procainamide, amiodarone, sotalol, and beta-blockers is less consistent, and these drugs are usually ineffective. Carotid sinus massage and Valsalva maneuvers have no effect on the VT. Fascicular VT is generally unresponsive to adenosine; however, when catecholamine stimulation (isoproterenol infusion) is required for the initiation of VT (in the EP laboratory), the VT can become adenosine sensitive.

Chronic Management

Oral verapamil or diltiazem is useful in mild cases; however, long-term efficacy is variable and the benefit of these drugs in management of patients with severe symptoms is often limited. Catheter ablation is highly effective (success rate of 85% to 90%) and is recommended for patients in whom drug therapy is not successful, not tolerated, or not preferred.

Electrocardiogram During Normal Sinus Rhythm

The resting ECG is usually normal. Symmetrical inferolateral T wave inversion can be observed after termination of the VT (cardiac memory).

Electrocardiogram During Ventricular Tachycardia

Fascicular VT is characterized by relatively narrow QRS duration (127 ± 11 milliseconds) and short RS interval (the duration from the beginning of the QRS to the nadir of the S wave) in the precordial leads (60 to 80 milliseconds). The shorter QRS duration reflects the proximal exit of fascicular VTs from the His-Purkinje system (HPS). In addition, during fascicular VT, the interventricular septum is activated early with a left-to-right direction, resulting in an initial “r” waves in lead V ₁ and small “q” waves in leads I and aV _L (similar to classic RBBB pattern). In addition, the rapid activation of the LV via the Purkinje system results in unopposed late activation of the right ventricular outflow tract (RVOT), leading to a large R′ amplitude in lead V ₁ (and r < R′).

The VT rate is approximately 150 to 200 beats/min (range, 120 to 250 beats/min). Alternans in the TCL is frequently noted; otherwise, the VT rate is stable.

According to the fascicular territory involved and, consequently, the QRS morphology, fascicular VTs are classified into three subtypes: (1) LPF VT (with the reentrant circuit exit in the inferoposterior septum) exhibits an RBBB and superior axis configuration (most common form); (2) LAF VT (with the reentrant circuit exit in the anterolateral wall of the LV) exhibits RBBB and right-axis deviation configuration; and (3) upper septal fascicular VT with a narrow QRS and normal axis configuration (rare form). In the most common form (LPF-VT), the QRS during VT typically has RBBB with LAF block configuration. The R/S ratio is less than 1 in leads V ₅ and V ₆ ( Fig. 24.2 ). VTs arising more toward the middle at the region of the posterior papillary muscle have a left superior axis and RS in leads V ₅ and V ₆ , whereas those arising closer to the apex have a right superior axis with a small “r” and deep S (or even QS) in leads V ₅ and V ₆ .

Surface Electrocardiogram of Fascicular Ventricular Tachycardia (VT).

Note the right bundle branch block and left anterior fascicle block pattern characteristic of these VTs.

Induction of Tachycardia

Given the reentrant mechanism of fascicular VT, the arrhythmia is usually inducible by programmed electrical stimulation. In fact, fascicular VT is characterized by its reproducible initiation and termination not just by ventricular stimulation but also by atrial pacing. Often, isoproterenol infusion facilitates VT induction. Consistent with a reentry mechanism, an inverse relationship is observed between the coupling interval of the initiating ventricular extrastimulation (VES) or ventricular pacing cycle length (PCL) and the first VT beat.

Diagnostic Maneuvers During Tachycardia

Exclusion of Other Arrhythmia Mechanisms

The differential diagnosis of fascicular VT includes interfascicular VT, supraventricular tachycardia (SVT) with aberrant conduction, and VT originating from the LV papillary muscles.