Rehan Mahmud

Facilitation of ventricular tachycardia induction with abrupt changes in ventricular cycle length

The effect of abrupt short-to-long changes in cycle length (CL) on the postulated reentrant circuit of ventricular tachycardia (VT) was evaluated. This was performed using single and double ventricular extrastimuli in a group of 21 patients clinically suspected of having VT in whom VT could not be induced at comparable or shorter constant CLs. A second group of 10 patients without suspected VT was similarly studied. Compared with constant CLs of equal or shorter duration preceding the single or double ventricular extrastimuli, abrupt short-to-long CL changes resulted in (1) initiation of sustained VT in 13 of 21 patients in whom VT could not be induced at constant CLs despite the use of shorter S1S3 by 66 +/- 17 ms; (2) increased incidence of initiation of sustained VT after the V3 phenomenon resulting from macroreentry within the His-Purkinje system (Re-HPS); (3) a small but higher incidence of sustained VT due to sustained Re-HPS; and (4) no induction of sustained or nonsustained VT with either method in the second group of patients. These results provide additional support for reentry as the basis for sustained ventricular tachyarrhythmias. Abrupt short-to-long CL changes may be effective for initiating sustained VT in patients at risk for these arrhythmias.

Linking: a dynamic electrophysiologic phenomenon in macroreentry circuits.

The term linking has been used specifically to describe the mechanism for perpetuation of functional anterograde bundle branch block: namely, repetitive transseptal retrograde concealed penetration by impulses propagating along the contralateral bundle. We present selected examples that demonstrate tht linking-type phenomena actually have a wide spectrum of expression in human macroreentry circuits, particularly those incorporating either the bundle branches and His bundle or the normal pathway and Kent bundle. The examples presented are as follows: (1) persistent retrograde functional conduction delays in the His-Purkinje system during right ventricular pacing, (2) anterograde Kent bundle condution at rapid rates, dependent on prior block in the normal pathway, (3) persistent anterograde functional infra-His block of atrial impulses during rapid ventricular pacing in the presence of a retrogradely conducting accessory pathway, and (4) transient advancement of His activation with ventricular fusion complexes during overdrive ventricular pacing of bundle branch reentrant tachycardia. Based on these examples, we characterize linking as a generalized electrophysiologic phenomenon in which each successive impulse entering a macroreentry circuit propagates preferentially along one limb because of functional block in the contralateral limb resulting from the effects of the prior impulse. It is proposed that such functional block may be dynamically maintained either by repetitive impulse interference, which perpetuates local refractoriness (examples No. 1 to 3), or by repetitive impulse collision (example No. 4). The general conceptual scheme outlined can be applied to specific electrophysiologic phenomena associated with a wide variety of reentry circuits in man.

Useful clinical criteria for the diagnosis of ventricular tachycardia

Misdiagnosis occurs upon initial presentation to medical attention in a considerable number of patients referred for evaluation of wide QRS tachycardia. In order to improve diagnostic accuracy (ventricular versus supraventricular tachycardia), the answers to two key bedside questions were prospectively evaluated: (1) Had the patient experienced a prior myocardial infarction? (2) Did symptoms of tachyarrhythmia start only after the infarction? A patient presenting with a wide QRS tachycardia was considered to have ventricular tachycardia if he or she answered in the affirmative to both of these questions. Of 31 consecutive patients referred with electrocardiographically documented sustained wide QRS tachycardia that was reproduced in the electrophysiology laboratory, the diagnoses made when the patients first presented to medical attention were ventricular tachycardias in 17 patients and supraventricular tachycardias in 14 patients. Following electrophysiologic evaluation, 29 were diagnosed as having ventricular tachycardia and two as supraventricular tachycardia. If the diagnoses were made solely on the basis of responses to the bedside questions mentioned earlier, 28 of the 29 patients having a final diagnosis of ventricular tachycardia would have been correctly identified. It is concluded that the use of these two questions can be very helpful in improving the clinical diagnosis of ventricular tachycardia.

Value of preexisting bundle branch block in the electrocardiographic differentiation of supraventricular from ventricular origin of wide QRS tachycardia

The relation between the morphologic configuration of QRS complexes during wide QRS tachycardia induced during electrophysiologic studies and sinus rhythm was examined in 18 patients who had preexisting left or right bundle branch block. Representative QRS complexes during sinus rhythm and during tachycardia were isolated from each patient and juxtaposed for comparison. The QRS complexes that constituted each pair were judged by 4 observers as being identical, different or, if the decision was equivocal, similar. Nine patients had supraventricular tachycardia (SVT). In 8 of the 9 patients, all 4 observers found the QRS complexes during sinus rhythm and SVT identical in morphologic configuration. In the other patient, 2 observers found the QRS complexes identical and 2 found them similar. In 12 patients ventricular tachycardia (VT) was induced. In 11 of these 12, all 4 observers found the QRS complexes during VT different from their respective sinus beats. In the other patient, 3 observers found the QRS complexes different, whereas the fourth found them similar. During SVT, the QRS duration was unchanged from the corresponding value during sinus rhythm, whereas in patients with VT, QRS width increased by a mean of 56 +/- 20 ms (p less than 0.001). The results of our study suggest that the electrocardiographic differentiation of wide QRS tachycardia in patients with preexisting bundle branch block can be accomplished easily and accurately by comparing the QRS complexes during tachycardia with those during sinus rhythm: If the complexes are identical, the tachycardia is supraventricular, but if they are different, the arrhythmia is ventricular in origin.

Atrioventricular sequential pacing: differential effect on retrograde conduction related to level of impulse collision.

Patients with DDD pacemakers who have intact retrograde conduction are known to be at risk of developing ventricular and endless loop tachycardia. To address this problem, a pacing protocol was designed in which V2A2 conduction was assessed in 16 patients during ventricular pacing alone (standard method) and during paced atrioventricular (AV) sequential drive (AV sequential method); the results were then compared. In eight of 16 patients who had intact retrograde conduction with both methods (group 1), the V2A2 intervals were significantly shorter (by 60 to 340 msec) with the AV sequential method. In the remaining eight patients, who demonstrated V2A2 block with the standard method, no V2A2 block occurred with the AV sequential method. In this study, two sets of AV intervals were programmed to produce collision of the two impulses (atrial and ventricular), either in the AV node or the His-Purkinje system (HPS). The site of V2A2 facilitation was related to the site of impulse collision. These results can be explained by earlier excitation by the atrial impulse (of AV node and/or HPS) during AV sequential pacing. However, in some cases it was evident that antegrade propagation of the atrial impulse was responsible for subsequent facilitation. The data suggest that assessment of retrograde conduction in candidates for DDD pacemakers can be made most accurately by the AV sequential method.

Divergence between refractoriness of His-Purkinje system and ventricular muscle with abrupt changes in cycle length.

The concept that refractoriness of the His-Purkinje system (HPS) and ventricular muscle both vary directly with cycle length is based on observations during the use of constant cycle length. During abrupt changes in ventricular cycle length, refractoriness of the ventricular muscle is known to reflect the cumulative durations of preceding cycle lengths. The effect of such changes on retrograde refractoriness of the HPS is not known. In this study refractoriness of ventricular muscle and of the HPS was evaluated in 30 patients with normal intraventricular conduction by the ventricular extrastimulus (V2) technique during constant cycle length (method I) and during abrupt cycle length changes (method II). During method II the cycle length immediately before V2 was identical to the constant cycle length of method I and therefore was designated as the reference cycle length (CLR); however, the cycle length preceding (CLP) CLR was either longer than CLR (method IIA) by 100 to 300 msec in 11 patients or shorter than CLR (method IIB) by 100 to 300 msec in 30 patients. Results showed that compared with method I, method IIA shortened the relative refractory period (RRP) of the HPS from 350 +/- 29 to 344 +/- 29 msec (p less than .04), whereas the effective refractory period (ERP) of the ventricular muscle increased from 225 +/- 21 to 233 +/- 20 msec (p less than .0001). In contrast, compared with method I, method IIB lengthened the RRP of the HPS from 335 +/- 30 to 351 +/- 35 msec (p less than .0001), whereas ERP of the ventricular muscle decreased from 223 +/- 23 to 213 +/- 22 msec (p less than .0001). Similar to the inverse relationship between CLP and RRP of the HPS, ERP of the HPS was prolonged with short CLP (method IIB) compared with long CLP (method IIA). The results indicate a marked divergence between refractoriness of the HPS and of ventricular muscle during abrupt cycle length changes; these results were not previously anticipated. Whereas ventricular muscle responded to cumulative effects of preceding cycle lengths and varied directly with CLP, the HPS appeared to respond to directional and/or dynamic changes in cycle length and varied inversely with CLP. Moreover, in contrast to ventricular muscle, the HPS appeared to be responsive to rate of change in cycle length whereby short-to-long change in cycle length had a greater effect than long-to-short change in cycle length.

Facilitation of macroreentry within the His-Purkinje system with abrupt changes in cycle length.

We have recently described the ability of abrupt short-to-long changes in atrial cycle length (CL) to prolong refractoriness of the His-Purkinje system (HPS) and increase the likelihood of aberrant ventricular conduction. We have also shown similar functional behavior in retrograde refractoriness of the HPS during changes in ventricular CL. To further assess these characteristics we evaluated the effect of abrupt short-to-long change in ventricular CL on the phenomenon of macroreentry within the HPS (Re-HPS) in 20 patients in whom Re-HPS occurred during application of a ventricular extrastimulus (V2) at a constant ventricular CL (method I) and/or with abrupt short-to-long change in CL (method II). For both methods V2 was coupled to a CL of identical duration, designated the reference CL (CLR). In method I the CLs preceding (CLP) the CLR equaled CLR, whereas in method II CLP was less than CLR. The results showed a dramatic increase in occurrence of Re-HPS with abrupt short-to-long change in CL with Re-HPS occurring in 19 patients with this method compared with in 11 patients during constant CL. In 10 patients manifesting Re-HPS with both methods the associated retrograde conduction (V2H2) delays were equal or less during abrupt short-to-long changes in CL and, remarkably, there were concomitantly shorter antegrade conduction (H2V3) delays compared with at a constant CL. Moreover, despite the resulting shorter V2V3, additional Re-HPS beats were also more likely to occur with abrupt short-to-long change in CL compared with at a constant CL.(ABSTRACT TRUNCATED AT 250 WORDS)

Patterns of human atrioventricular nodal accommodation to a sudden acceleration of atrial rate

Atrioventricular nodal (AVN) accommodation to an abrupt increase in atrial rate was systematically studied in 10 patients using a pacing protocol incorporating a programmable pause (S1S2) between the last beat of basic atrial drive (S1S1) and the onset of an 18-beat paced atrial train (S2S2) of shorter constant cycle length (CL) than that of S1S1. Pacing was repeated, varying S1S2 while keeping S1S1 and S2S2 CLs fixed. In all patients there existed a zone of 1 or more critical S1S2 intervals for which the new steady-state AVN conduction time (S2H2) was attained instantaneously, that is, with the first beat, and maintained for subsequent beats of the S2S2 train. At S1S2 intervals that exceeded or were less than critical values, S2H2 progressively increased (crescendo pattern) or decreased (decrescendo pattern), respectively, until the steady-state value was achieved. The zone of S1S2 intervals that resulted in decrescendo or instantaneous AVN accommodation contracted when either the S1S1 CL was increased or the S2S2 CL was shortened. These findings have relevance to the interpretation of electrophysiologic studies and explain the spectrum of AVN accommodation patterns observed at the onset of supraventricular tachycardia.

Atrioventricular nodal conduction and refractoriness after intranodal collision from antegrade and retrograde impulses.

Animal studies have suggested that spontaneous or programmed ventricular beats that occur simultaneously with atrial activation may facilitate atrioventricular (AV) nodal conduction during subsequent atrial impulses. However, this possibility has not been systematically studied in the human heart. In the present study the AV nodal conduction during a programmed atrial premature beat (S2) was analyzed. The S2 was delivered after a series of atrial drive beats (SjSj) of constant duration; this was termed stimulation method I. The results were compared with stimulation method II, which was similar to method I except that a single ventricular beat (Vs) was introduced simultaneously with the last Sl. The longest and shortest possible paced atrial cycle lengths (CLs) were scanned during both methods. Twenty-six patients were studied: 14 with a normal PR and normal intraventricular conduction (NIVC), four with first-degree AV nodal block and NIVC, three with a complete left bundle branch block (LBBB) pattern, three with a complete right bundle branch block (RBBB) pattern, and two with an incomplete RBBB pattern.At the same SlS2 intervals, the AV nodal conduction times (S2112 intervals) were consistently shorter with method II than with method I except in three patients, two with complete RBBB and one with complete LBBB. The magnitude of S2H2 shortening with method II was more pronounced at the shorter basic CLs and shorter SlS2 intervals. During method I, the effective refractory period (ERP) of the AV node was measured in 13 patients, eight with NIVC and five with preexisting bundle branch block. With method II, the ERP of the AV node shortened in all but three patients (one with complete RBBB, one with incomplete RBBB and one with complete LBBB pattern), in whom this variable did not change. The findings suggest that intranodal collison from antegrade and retrograde impulses facilitates AV nodal conduction and shortens the ERP. The magnitude of this change is greater at shorter atrial CLs and is probably related to deeper intranodal penetration of a Vs. The shortening in AV nodal conduction and refractoriness is not noted in patients with bundle branch block when retrograde conduction delay or block in the bundle branches coexists with the antegrade counterpart producing delayed or ineffective input of Vs into the AVnode.

Effect of sudden rate acceleration on the human His-Purkinje system: adaptation of refractoriness in a dampened oscillatory pattern.

Although the refractoriness of the human His-Purkinje system (HPS) during constant-cycle length pacing appears to be closely related to the cycle length of the stimulation, the mode of adaptation of this refractoriness with sudden rate acceleration is not well understood. A systematic evaluation of this adaptation was performed in 14 patients with normal QRS durations and HV intervals referred for electrophysiologic evaluation. The relative refractory period of the HPS (HPS-RRP) was evaluated by the extrastimulus (S2) method during a constant ventricular drive (S1) having a cycle length as close to sinus rhythm as possible. An accelerated train of 6 ventricular beats (S1) was then added to the constant drive and the HPS-RRP of each successive beat of this train was similarly determined. Mean S1 cycle length was 750 +/- 164 msec (range 600 to 1000). Mean S1 cycle length was 475 +/- 55 msec (range 400 to 600). The HPS-RRP of each successive beat of the accelerated train was significantly shorter than that during the S1 drive and behaved in a dampened oscillatory fashion alternating from a lower value on the odd-numbered beats to a higher value on the even-numbered beats. In contrast, the effective and relative refractory periods of the ventricular myocardium during the accelerated train behaved in a cumulative manner, decreasing progressively with the first 2 beats of the train before reaching a plateau value. In conclusion, the data reported here present a new and intriguing picture of the mode of adaptation of the HPS refractoriness to sudden rate acceleration. At least in the range of the cycle lengths used in this study, the refractoriness of the HPS behaves in a dampened oscillatory manner that is radically different from the behavior of the ventricular myocardial refractoriness.