The gap phenomena during retrograde conduction in man

Physiologic Variants of Cardiac Conduction (Aberration, Gap, Supernormal Conduction)

Wide QRS complexes during supraventricular rhythms can be caused by fixed bundle branch block, functional (intermittent) bundle branch block, preexcitation, or toxic/metabolic causes. Functional bundle branch block can be caused by long-short aberrancy (usually physiologic), or acceleration/deceleration dependent aberrancy (usually pathologic). Electrocardiogram criteria have been proposed to differentiate aberration from ventricular tachycardia; they are not always accurate. The gap phenomenon "paradox" is that with increasingly premature extrastimuli, progressive proximal conduction delay allows time for distal recovery of excitability. Supernormal conduction may explain unusual conduction phenomena in patients with abnormal His-Purkinje function or poorly conducting accessory pathways.

Physiologic Variants of Cardiac Conduction (Aberration, Gap, Supernormal Conduction)

Wide QRS complexes during supraventricular rhythms can be caused by fixed bundle branch block, functional (intermittent) bundle branch block, preexcitation, or toxic/metabolic causes. Functional bundle branch block can be caused by long-short aberrancy (usually physiologic), or acceleration/deceleration dependent aberrancy (usually pathologic). Electrocardiogram criteria have been proposed to differentiate aberration from ventricular tachycardia; they are not always accurate. The gap phenomenon "paradox" is that with increasingly premature extrastimuli, progressive proximal conduction delay allows time for distal recovery of excitability. Supernormal conduction may explain unusual conduction phenomena in patients with abnormal His-Purkinje function or poorly conducting accessory pathways.

Human His-Purkinje System: Normal Electrophysiologic Behavior

The His-Purkinje system (HPS) plays a significant role in human pathophysiology, but knowledge is scattered. This article highlights some of the relevant concepts, phenomena, and mechanisms; clarifies, expands, confirms, or modifies commonly encountered clinical events; and adds new information, which is often available but obscure. Also included are the essentials of HPS anatomy and physiology. It is important to abandon inaccurate concepts that are still taught and occasionally appear in text books.

Bundle branch reentry: a mechanism of ventricular tachycardia in the absence of myocardial or valvular dysfunction

OBJECTIVES

The aim of this study was to present bundle branch reentry as the mechanism of sustained ventricular tachycardia in the absence of myocardial or valvular dysfunction.

BACKGROUND

Previous reports have documented the relation between structural heart disease and bundle branch reentrant ventricular tachycardia. Myocardial or valvular dysfunction has thus far been recognized as the only anatomic substrate for the development of this tachycardia.

METHODS

Three patients with a wide QRS complex tachycardia underwent noninvasive and invasive cardiac evaluation and electrophysiologic studies to identify the substrate and mechanism of tachycardia. Catheter ablation of the right bundle branch using radiofrequency current was performed in each patient.

RESULTS

The patients were all men (aged 54, 34 and 72 years) who presented with presyncope, palpitation and cardiac arrest, respectively. Electrocardiography during sinus rhythm revealed nonspecific intraventricular conduction delay in all three patients. Cardiac evaluation revealed no evidence of myocardial or valvular dysfunction in any patient. The baseline HV interval was prolonged in each patient (90, 100 and 75 ms, respectively). Programmed right ventricular stimulation initiated bundle branch reentrant tachycardia with typical left (three patients) and right (one patient) bundle branch block pattern. Catheter ablation of the right bundle branch using radiofrequency current abolished bundle branch reentry in all three patients. After 26-, 13- and 8-month follow-up periods, complete right bundle branch block persisted, and all three patients remained asymptomatic without antiarrhythmic drugs.

CONCLUSIONS

Sustained bundle branch reentry can be a clinical arrhythmia in patients with no identifiable myocardial or valvular dysfunction except for isolated conduction abnormalities in the His-Purkinje system. This mechanism of tachycardia should be recognized during electrophysiologic evaluation, given the seriousness of this arrhythmia and the availability of the effective treatment.

Bundle branch reentrant ventricular tachycardia: cumulative experience in 48 patients

INTRODUCTION

The clinical, electrophysiologic features and follow-up of 48 patients with inducible bundle branch reentrant (BBR) tachycardia are presented.

METHODS AND RESULTS

Forty-eight patients were identified in whom a diagnosis of BBR tachycardia was made during electrophysiologic evaluation. The clinical presentation was syncope or sudden death in 38 patients, and sustained palpitations during wide QRS complex tachycardia in 5 patients. Electrophysiologic studies were performed in 5 additional patients for various other reasons. Structural heart disease was present in 45 patients. Idiopathic dilated cardiomyopathy and coronary artery disease were the anatomical substrates in 19 (39%) and 24 (50%) patients, respectively, severe aortic regurgitation was present in 2 patients, and no organic heart disease was identified in 3. All 48 patients had evidence of His-Purkinje system disease. BBR tachycardia with left and right bundle branch block morphologies was induced in 46 and 5 patients, respectively, and interfascicular BBR tachycardia was initiated in 2 patients. Ventricular tachycardia of a myocardial origin was induced in 11 patients. Management of BBR tachycardia included transcatheter bundle branch ablation in 28 patients, and antiarrhythmic drug therapy in 16 patients. Four patients were treated with implantable defibrillators. After a mean follow-up of 15.8 months in 42 patients, there were 13 deaths due to congestive heart failure, 4 sudden cardiac deaths, 3 nonsudden cardiac deaths, and 3 noncardiac related deaths.

CONCLUSION

Sustained BBR, a form of monomorphic ventricular tachycardia, is a highly malignant arrhythmia usually seen in patients with structural heart disease. Three different types of BBR tachycardia are described. If distinguished from ventricular tachycardia of a myocardial origin, catheter ablation of the right bundle branch can be easily performed and effectively eliminates BBR. During follow-up, congestive heart failure is the most common cause of death in this population.

Three-dimensional computer model of the entire human heart for simulation of reentry and tachycardia: gap phenomenon and Wolff-Parkinson-White syndrome

A computer model of the entire human heart has been developed for simulation of the excitation and repolarization process. Spatial distribution of refractory periods and conduction velocities in the different cardiac tissues, the anisotropy of conduction in the ventricles, and the cycle length dependence of refractory periods and conduction velocities are taken into account. The algorithm calculating the activation process is based on a modified version of Huygen's principle for constructing wavefronts. This study presents simulations concerning the gap phenomenon of the conduction system and the initiation of tachycardias in a heart with Wolff-Parkinson-White syndrome. Results are compared for different basic cycle lengths and for normal and prolonged refractory periods in the His-Purkinje system. The gap phenomenon was found to be present only when using the prolonged refractory periods in the His-Purkinje-system at a cycle length of 700 ms. Induction of tachycardia by a single extrastimulus in the high right atrium in a heart with a bidirectionally conducting accessory pathway is possible by properly timed extrastimuli. The coupling interval of the stimulus for initiating a reentrant tachycardia depends on the cycle length, the conduction velocities and the set of refractory periods used. The same parameters determine whether or not a gap phenomenon in atrioventricular conduction occurs. The model may be useful for investigating similar questions concerning the reentry phenomena of tachycardia.

Linking by collision initiated in the absence of preexisting reentrant tachycardia

Dynamic functional block in 1 limb of a reentrant circuit ("linking") can be maintained by either repetitive interference or collision of successive impulses entering the circuit. Occurrence of linking by collision during attempted overdrive pacing of reentrant tachycardias accounts for the entrainment phenomenon. To investigate whether linking by collision can be initiated in the absence of preexisting tachycardia, a human reentrant circuit model was studied. The model consisted of the atrioventricular node and His-Purkinje system as anterograde limb and an electronic stimulator that served as "retrograde limb" by initiating a paced atrial impulse at a predetermined ventriculoatrial interval following each sensed ventricular depolarization. In 3 patients with intact ventriculoatrial conduction, "reentrant tachycardia" was initiated by a ventricular extra-stimulus (V2), which retrogradely blocked bilaterally below the His bundle. When this same V2 was followed, instead, by a paced V2V2 train at a cycle length equal to the programmed ventriculoatrial interval of the "tachycardia," it could be shown that each beat of the train not only "traversed" the simulated "retrograde limb" but also retrogradely collided with a prior circulating impulse in the anterograde limb of the circuit, thereby constituting linking by collision at a supra-Hisian level with inability of even a single "reentrant cycle" to be completed; "tachycardia" became manifest only after termination of the V2V2 train. The findings suggest the existence of a unique mechanism for initiation of certain clinical reentrant tachycardias during incremental pacing.

Effect of amiodarone on electric induction, morphology, and rate of ventricular tachycardia and its relation to clinical efficacy

Using His bundle electrograms and programmed ventricular stimulation, the effects of chronic amiodarone treatment on induction, morphology, and the rate of ventricular tachycardia (VT) were studied in 17 consecutive patients treated with amiodarone for control of recurrent sustained VT or ventricular fibrillation. Studies were done before and after treatment with amiodarone for an average duration of 5.3 (range 2 to 18) months. During the control study, sustained VT could be induced in 16 patients. VT was initiated by single or double right ventricular (RV) extrastimuli in 14 patients, by double left ventricular (LV) extrastimuli in 1 patient, and by RV burst pacing in 1 patient. Only one pattern (morphology) of VT similar to that of spontaneous VT was induced in 12 patients and two patterns of VT in 4 patients. The average cycle length (CL) (mean +/- SD) of induced VT was 325.8 +/- 61.2 ms. After amiodarone, VT could be induced in 7 of 17 patients and was initiated by single RV extrastimuli in 5 patients, double RV extrastimuli in 1 patient, and RV burst pacing in 1 patient. In 3 of 5 patients in whom VT could be initiated by single RV extrastimuli, initiation of VT required double RV or double LV extrastimuli in the control study; in 1 of 5 patients VT could not be induced in the control study. Amiodarone induced nonclinical, polymorphic VT in 4 patients in whom only clinical VT could be induced during the control study. Compared to control, the CL of induced VT was significantly longer (322 +/- 65.7 vs 416 +/- 41.5 ms; P less than 0.001).+

A new type of ventriculo-atrial gap phenomenon in man

A new type of ventriculo-atrial (V-A) gap phenomenon was observed in a patient who underwent a cardiac electrophysiology study and had complete antegrade infranodal A-V block but intact V-A conduction. During ventricular extrastimulus testing, a split retrograde His potential emerged from the ventricular electrogram. As the prematurity of the extrastimulus was increased, the later of the two retrograde His deflections disappeared suddenly at a critical coupling interval and V-A conduction was interrupted. More premature extrastimuli resulted in progressive delay in the His-Purkinje system and delayed appearance of the earlier retrograde His deflection. As a result of this delay, conduction through the His bundle eventually resumed, the second (split) retrograde His reappeared and conduction to the atria resumed. Thus, the initial site of block during the V-A gap phenomenon in this patient was located in the His bundle, with proximal delay occurring in the distal His-Purkinje system. The results indicate that the classic mechanism of gap phenomenon is operative. To our knowledge, this type of V-A gap phenomenon has not been previously described in man.

Retrograde gap in fast pathway conduction accentuated by the class I antiarrhythmic agent, flecainide

A case is reported of a patient with functional duality of AV nodal conduction in whom, during ventricular extrastimulus testing, there was a gap in retrograde fast pathway conduction which allowed the temporary expression of retrograde slow pathway conduction. The administration of the antiarrhythmic agent flecainide, which has disparate effects on retrograde fast and slow pathway conduction characteristics, accentuated this phenomenon. The electrophysiological basis of gap phenomena is discussed.

Electrophysiologic effects of chronic amiodarone therapy in patients with ventricular arrhythmias

Detailed electrophysiologic studies were performed in nine patients with chronic refractory ventricular arrhythmias before and after 7 to 20 weeks (mean 11 weeks) of amiodarone therapy. The amiodarone dose at the time of the repeat study ranged from 400 to 800 mg/day. The drug reduced the sinus rate (p less than 0.001) and prolonged the sinoatrial conduction time (p less than 0.05) with some prolongation of the corrected sinus node recovery time. Intra-atrial conduction was slightly prolonged both in sinus rhythm and during atrial pacing. Anterograde conduction through the AV node was significantly prolonged both in sinus rhythm (p = 0.001) and during atrial pacing (p less than 0.005), and Wenckebach AV block was seen at significantly lower atrial pacing rates after the drug (p less than 0.005). The HV interval was prolonged both in sinus rhythm (p less than 0.05) and during atrial pacing (p = 0.001), and so was the QRS width during atrial pacing (p less than 0.005) and the QT interval in sinus rhythm (p less than 0.005) and during atrial pacing (p less than 0.005). Significant prolongation of the refractory periods in the atrium, AV node, and ventricular muscle were also seen following the drug. We concluded that the significant electrophysiologic effects of this drug throughout the heart during chronic oral use attest to its clinical effectiveness in patients with atrial and ventricular arrhythmias. With due care and despite its effects on the HV interval and QRS width, it can be used in patients with intraventricular conduction defects complicating severe organic heart disease.

Role of retrograde His Purkinje block in the initiation of supraventricular tachycardia by ventricular premature stimulation in the Wolff-Parkinson-White syndrome

The precise mechanisms for paroxysmal reentrant supraventricular tachycardia (PSVT) initiation during right ventricular premature stimulation (V(2) method) were analyzed in 14 consecutive patients with Wolff-Parkinson-White Syndrome in whom the PSVT was inducible during retrograde refractory period studies. 9 patients had left-sided and the remaining 5 of 14 had right-sided ventriculo-atrial (VA) accessory pathway (AP). At the basic cycle lengths (V(1)V(1)) ranging from 550 to 900 ms (mean, 657.1+/-139.5), closely coupled V(2) (mean V(1)V(2), 357.3+/-59.2 ms, range 320-500) produced retrograde His bundle (H(2)) activation via the bundle branches and retrograde atrial (A(2)) activation via the AP. As the V(1)V(2) were further shortened, the V(2) showed a retrograde block in the His Purkinje system (HPS) and conducted to the atria via AP in 9 of 14 cases. Subsequently, the A(2) impulse conducted anterograde over the atrioventricular node-HPS to initiate a PSVT or an atrial echo response in all nine cases. In none of the patients was a PSVT induced by V(2) when the latter produced retrograde H(2) activation via the bundle branches. In 10 of 14 cases, however, the retrograde H(2) was followed by a V(3), due to macroreentry in the HPS. The V(3) in turn blocked retrogradely in the HPS while producing A(3) via the AP to initiate a PSVT or an atrial echo response in 9 of 10 cases. Retrograde block of V(2) and/or V(3) in the HPS resulted in PSVT initiation in 13 of 14 cases, whereas in the remaining 1 case the exact mechanism was not clear. In none of the patients in this series was the PSVT initiated with a retrograde block of V(2) in the atrioventricular node with or without concomitant retrograde A(2) activation via the AP. We conclude that within the ranges of cycle lengths tested, a retrograde block of V(2) and/or V(3) in the HPS is the most common mechanism for initiation of PSVT during ventricular premature stimulation in patients with the Wolff-Parkinson-White Syndrome.

Intra His Purkinje gap phenomenon during retrograde conduction in man

Ventricular refractory period studies were performed in 24 patients using the ventricular extrastimulus (V2) method at a basic ventricular drive (V1V1). Gap phenomenon confined to the His-Purkinje system (V-H gap) during retrograde conduction was observed in six of 24 patients. In this form of gap, the premature impulse (V2) is initially blocked in the His-Purkinje system (HPS) as recognized by the absence of retrograde His bundle deflection (H2) and atrial depolarization (A2) following V2. At closer V1V2 intervals, V2 resumed conduction to the bundle of His (H2) but not to the atria. The mechanism of this form of gap is similar to the one proposed for the previously described gap phenomena in ventriculoatrial (V-A) conduction and involves proximal delay allowing more time for distal recovery. At shorter V1V2 intervals, V2 resumes conduction to the bundle of His because it encounters sufficient delay in some region below the His bundle. However, this delay may be insufficient to allow recovery of excitability at the A-V node and hence resumption of conduction to the atria is not an integral part of V-H gap. The relation of V-H gaps to the occurrence of reentry within the HPS (V2 phenomenon) is discussed. V-H gaps also explain the failure of some ventricular premature beats (VPBs) to show the effects of concealed conduction in the A-V node. The similarities and differences between V-A and V-H gaps during retrograde conduction are discussed.

Patterns of atrial activation during right ventricular pacing in patients with concealed left-sided Kent pathways

A 'concealed' accessory pathway was suspected in 12 patients because of eccentric left atrial activation during tachycardia. Retrograde conduction during ventricular pacing may occur over the atrioventricular node, the accessory pathway, or both. There were 4 patterns of ventriculoatrial conduction in response to ventricular extrastimuli (V2) at various coupling intervals: (1) exclusive accessory pathway conduction throughout the cardiac cycle in 2 patients; (2) exclusive accessory pathway conduction at long coupling intervals and exclusive atrioventricular node conduction at short coupling intervals in 2 patients; (3) variably fused accessory pathway/atrioventricular node conduction at long coupling intervals but exclusive accessory pathway conduction at short coupling intervals in 4 patients; (4) fused accessory pathway/atrioventricular node conduction at long coupling intervals but exclusive atrioventricular node conduction at short coupling intervals in 4 patients. With increased prematurity of V2 the ventricle to right atrial interval prolonged conspicuously in 11 of 12 patients whereas the ventricle to left atrial interval remained constant until the refractory period of the accessory pathway in all but 2 instances where intraventricular delay occurred. This study emphasises the importance of left atrial recordings in these patients.

Gap phenomenon in "the right and left bundle branch systems" during retrograde conduction in man

Gap phenomenon in right and left bundle branch systems during retrograde conduction is described in two patients with manifest reentry within the His-Purkinje System (V3 phenomenon). In this form of gap the premature impulse (S2) initially blocked in the right bundle branch system and conducted retrogradely via the left bundle branch system as manifested by sudden prolongation of S2H2 interval and appearance of V3. At close coupling intervals S2 impulse encountered retrograde block in the left bundle branch system and resumed retrograde conduction via the right bundle branch system with S2H2 intervals shorter than critical value and was not followed by V3. However, on further shortening the S1S2 intervals S2 impulse blocked again in right bundle branch system and resumed conduction via the left bundle branch system with S2H2 intervals longer than critical values and V3 reappeared. The mechanism of these gaps is not clear but we believe is similar to the one proposed in Types I and II gaps in antegrade bundle branch conduction and involves proximal delay allowing distal recovery. The similarities and differences between the gap phenomenon in bundle branches during antegrade and retrograde conduction are discussed.

Gaps in anterograde conduction in patients with the short PR interval, normal QRS complex syndrome

Of 8 patients with the short PR interval, normal QRS complex syndrome studied recently, 3 reported here displayed gaps in anterograde conduction. Atrial premature beats at decreasing coupling intervals conducted with minimal AH prolongation until a zone within the cardiac cycle was reached where conduction failed at a supra-Hisian level. Conduction resumed at earlier atrial coupling intervals and was associated with a sudden increase in the AH interval and the appearance of atrial echo beats with earliest atrial activation on the proximal coronary sinus electrogram. It is suggested that the failure of anterograde conduction at relatively late atrial coupling intervals was caused by a short AH functional refractoriness produced by the pre-excitation of the lower AV junction by a partial AV nodal bypass. Conduction resumed only when early atrial premature beats found the extranodal pathway refractory and were transmitted with decremental delay through the AV node.

His-Purkinje conduction during retrograde stress

The pattern of retrograde His-Purkinje conduction was evaluated in 28 patients using ventricular extrastimuli. In each patient progressive prolongations of His-Purkinje conduction (S2H2) which appeared as ventricular extrastimuli were induced at closer coupling intervals (S1S2). There was an inverse linear relationship of S2H2 to S1S2 which was cycle length-dependent: i.e., at any S1S2 interval the resultant S2H2 was less at shorter drive cycle lengths. The degree of S2H2 delay varied widely (from 30 to 340 ms) and was unrelated to the presence of bundle branch block, H-V intervals, or capability of ventriculoatrial conduction. Prolongation of S2H2 was independent of intraventricular (muscle) conduction delay; such delay was usually absent at most, and occasionally all, S1S2 coupling intervals during which S2H2 was lengthening. Furthermore, in two patients both left and right ventricles were activated before the timed depolarization of the His bundle occurred, demonstrating that under the stress of extrastimuli, the impulse conducts through ventricular muscle with less delay than through the His-Purkinje system. We conclude that the His-Purkinje system typically displays slow conduction response to ventricular stress. The site of this conduction delay is probably at the distal "gate".

Spontaneous gap phenomenon in atrioventricular conduction produced by His bundle extrasystoles

A gap in atrioventricular conduction is a zone within the cardiac cycle during which premature impulses are blocked in the conduction system, while impulses of greater or lesser prematurity are conducted. This has previously been produced only by atrial or ventricular stimulation techniques. This report demonstrates a spontaneous gap produced by His extrasystoles.

Characteristics and coexistence of two forms of ventricular echo phenomena

During the scanning of paced basic ventricular cycle lengths (V1V1) with extrastimulus method (V2) two forms of ventricular echo phenomena (Ve) were recognized. The Ve resulting from A-V nodal re-entry (VeAVN) occurred in 12 of 45 patients, from re-entry in the His-Purkinje system (Ve-HPS) in 20 of 45 patients, and simultaneous dual re-entry (Ve-AVN and Ve-HPS) occurred in five of 45 patients. The Ve-AVN (1) appeared at longer V1V2 intervals, (2) was dependent on retrograde A-V nodal conduction delay, (3) had normal QRS complexes and H-V intervals, and (4) did not occur when V2 blocked in the A-V node. (5) Ve-AVN had aberrant QRS complexes when preceded by Ve-HPS. The Ve-HPS (1) appeared at shorter V1V2 intervals, (2) was dependent upon retrograde conduction delay in the HPS, (3) its QRS morphology and axis orientation resembled V2, i.e., left bundle branch block pattern, when right ventricular apex was the site of stimulation, (4) persisted when V2 blocked in the A-V node and was abolished when V2 blocked below the bundle of His, and (5) rarely occurred in patients with pre-existing right bundle branch block. It is concluded that (1) at least two forms of Ve can result from induced premature ventricular beats, (2) Ve-HPS is more common than Ve-AVN in the presence of normal QRS complexes, and (3) coexistence of Ve-AVN and Ve-HPS can give rise to complex ECG pattern mimicking multiple multifocal premature ventricular beats.

Electrophysiologic effects of tolamolol on atrioventricular conduction in man

The electrophysiologic effects of tolamolol (UK-6558-01), a beta-adrenergic blocking agent, were studied in 13 patients by means of intracardiac electrograms and the extrastimulus method. Tolamolol (4 to 30 mg. intravenously) resulted in : (1) prolongation of sinus cycle length (SCL) in all patients (p less than 0.01); (2) prolongation of sinus escape time (SET) in 11 of 13 patients (p less than 0.001); (3) prolongation of A-V nodal conduction time during sinus rhythm in 1i of 13 patients (p less than 0.001); (4) onset of A-V nodal Wenckebach block at longer paced cycle lengths in 10 of 11 patients (p less than 0.001); (5) prolongation of the functional refractory period (FRP) of the A-V node in 11 of 11 patients (p less than 0.001); and (6) prolongation of the effective refractory period (ERP) of the A-V node in 10 of 10 patients (P less than 0.001). Tolamolol had no effect on His-Purkinje system (HPS) conduction time in any patient, including 3 patients with abnormal H-V intervals. Because of the marked increase in A-V nodal conduction time encountered by premature atrial depolarizations, the relative and effective refractory periods of the HPS could not be determined in any patient after tolamolol. Atropine (0.5 or 1.0 mg. intravenously) significantly reversed the effects of tolamolol on: sinus cycle length (4 of 5 patients); sinus escape time (3 of 3 patients); A-V nodal conduction time (4 of 5 patients); and A-V nodal refractioriness (5 of 5 patients).

Induction of atrioventricular nodal reentrant tachycardia after atropine. Report of five cases

After intravenous administration of 0.5 mg of atropine sustained atrioventricular (A-V) nodal reentrant tachycardia could be produced in five patients who had no prior historical or electrocardiographic evidence of supraventricular tachycardia. During the control period single atrial echo beats could be demonstrated in four of the five patients, but no instance of sustained tachycardia occurred. Atropine, known to enhance A-V nodal conduction, allowed achievement of longer A-H intervals (Case 1) and provided the necessary balance of conduction and refractoriness within the A-V nodal reentrant pathways (Cases 1 to 5) to sustain A-V nodal reentry in these patients.