Analysis of the interpolation phenomenon in man evaluated by premature atrial stimulation.

After early premature atrial stimulations, returning cycles shorter than the basic cycle were observed in 25 patients. In 4 of them sinus echoes were seen to occur after premature atrial stimulation coupling intervals shorter than those able to induce completely interpolated beats. Such a sequence is unexpected if we suggest a sino-atrial entrance block for explaining the interpolation phenomenon. An alternative explanation can be postulated assuming that all these early premature beats are sinus node re-entries and that the completely interpolated beat is only a sinus re-entry fortuitously occurring at an appropriate interval.     

Electrophysiologic effects and mechanisms of termination of supraventricular tachycardia by intravenous amiodarone

Electrophysiologic studies were performed in nine patients with reentrant paroxysmal supraventricular tachycardia (PSVT) during a control period and following 5 mg/kg body weight of intravenous amiodarone (Cordarone, Labaz) administered as a slow continuous infusion over 15 to 20 minutes. All nine patients had induction of sustained PSVT during control studies. In seven of nine patients (group 1) the tachycardia was due to atrioventricular (AV) nodal reentry, and in two of nine patients (group 2) a concealed retrograde bypass tract was incorporated in the reentrant process. In group 1, following amiodarone, all seven patients lost the ability to sustain PSVT with either absence of atrial echoes (one patient) or induction of ≤3 echo beats (six patients) with termination of PSVT in the antegrade pathway (three patients) or retrograde pathway (two patients) or both (one patient). In group 2, following amiodarone, both patients lost the ability to sustain PSVT with absence of atrial echoes (one patient) on induction of a single echo beat (one patient) with block in the retrograde pathway (i.e., the concealed retrograde bypass tract). Amiodarone significantly increased (1) atrial cycle length for AV nodal Wenckebach block, (2) antegrade functional refractory period of the AV node, (3) antegrade effective refractory period of the AV node, (4) ventricular paced cycle length for ventricular atrial block, and (5) the retrograde functional refractory period of the ventricular-atrial conducting system. Thus intravenous-amiodarone inhibited induction of sustained reentrant PSVT by inducing block in the antegrade or retrograde or both limbs of the reentrant circuit and was shown to have significant depressant effects on both antegrade and retrograde AV nodal conduction and refractory periods.     

Pacing techniques in the management of supraventricular tachycardias. Part 2. An implanted atrial synchronous pacemaker with a short atrioventricular delay for the prevention of paroxysmal supraventricular tachycardias.

An implanted atrial synchronous pacemaker with an atrioventricular delay of 30 msec is described. This pacemaker was implanted into a patient with paroxysmal supraventricular tachycardia due to an intra AV nodal reciprocal mechanism. The pacemaker was able to trigger from atrial potentials following atrial premature beats down to a coupling time of 300 msec. Following each triggering atrial potential, a ventricular stimulus was applied 30 msec later thereby producing a ventricular premature beat in response to each sinus beat or each atrial premature beat. Retrograde conduction from this atrial premature beat blocked the re-entry mechanism within the AV node and prevented the initiation of tachycardia. A detailed discussion on all parameters of function of this pacemaker is presented.     

Limitation of tachycardia zone resulting from longitudinal dissociation of the atrioventricular node in concealed pre-excitation.

Two cases with a concealed left-sided accessory atrioventricular bypass tract are described. In both, functional longitudinal dissociation of the atrioventricular node narrowed the range of atrial premature beat coupling intervals which could initiate re-entry using the accessory pathway. In case 1 early premature atrial beats were followed by an atrioventricular nodal re-entrant echo. The atrial echo pre-empted retrograde conduction over the Kent bundle and thus limited the development of paroxysmal supraventricular tachycardia. In case 2 atrioventricular nodal conduction showed typical features ascribed to dual atrioventricular nodal pathways. In addition there was a bradycardia-related retrograde block in the concealed accessory pathway. Early premature atrial beats, because of exclusive "slow pathway" anterograde conduction, arrived at the ventricles during the period of bradycardia-dependent retrograde block and failed to initiate a macro re-entrant tachycardia. This study shows that (1) longitudinal dissociation within the atrioventricular node may limit the ability to initiate tachycardia in patients with concealed pre-excitation; and (2) discontinuous atrioventricular nodal conduction curves occasionally help to reveal bradycardia-related retrograde block in a concealed accessory pathway.     

Ventricular Echo Beats and Retrograde Atrioventricular Nodal Exits in the Dog Heart: Multiplicity in Their Electrophysiologic and Anatomic Characteristics

INTRODUCTION: A single ventricular echo beat frequently is induced in the dog heart by ventricular pacing, but it has not been investigated using a concomitant ablative technique. We studied the effects of ablating the anterior atrial input to the AV node on ventricular echo beats induced in the dog heart to evaluate their electrophysiologic characteristics, the anatomic reentrant circuit, and the retrograde AV nodal exits. METHODS AND RESULTS: In 20 dogs, an epicardial radiofrequency current was applied to the right anterior septum in an attempt to ablate the anterior input to the AV node. Ventricular programmed stimulation was performed to evaluate the ventricular echo beat and the retrograde AV nodal exit before and after ablation. The AV junction was examined with light microscopy. Seventeen dogs in which the PR interval was prolonged significantly from 108+/-17 msec to 153+/-19 msec (P < 0.001) were selected for ventricular echo evaluation; 3 dogs in which persistent second- or third-degree AV block was induced by ablation were excluded. Ventricular echo beats, which were induced in 13 of 17 dogs, were classified into the anterior type (n = 6) or posterior type (n = 7) according to the earliest atrial activation site during the echo beat. The retrograde AV nodal exit site showed anterior-exit only (n = 10), posterior-exit only (n = 2), and dual-exit (n = 5) patterns. After ablation, the anterior-type ventricular echo beat was noninducible in all 6 dogs, whereas the posterior-type ventricular echo beat was noninducible in only 3 of 7 dogs. In 17 dogs, VA conduction was not demonstrated after ablation in 3 dogs, all of which showed the anterior-exit only pattern. CONCLUSION: The effect of ablation on the ventricular echo beats and retrograde AV nodal exit site suggests multiplicity in their electrophysiologic and anatomic characteristics in the dog heart.     

Sinus nodal responses to atrial extrastimuli in patients without apparent sinus node disease.

In 36 patients without sinus node disease scanning with an atrial extrastimulus (A2) was performed during sinus rhythm with the sinus cycle length measured in milliseconds. Zones of nonreset due to interference, reset, interpolation and sinus echoes were defined by noting the timing of the first response after A2. Zones were defined in terms of their longest and shortest A1-A2 coupling intervals (in milliseconds). A zone of nonreset was found in 12 of 12 patients in whom A2 was delivered late. The mean cycle length in these 12 patients was 779 msec, with a mean zone of nonreset of 779 to 585 msec (25 percent of cycle length). All 36 patients (100 percent) had a zone of reset. The mean cycle length in these 36 patients was 803 msec with a zone of reset from 692 to 319 msec (46 percent of cycle length). Seven of 36 patients (19 percent) had a zone of interpolation. The mean cycle length in these seven patients was 754 msec, with a mean zone of interpolation of 344 to 279 (9 percent of cycle length). Four of 36 patients (11 percent) had a zone of sinus echoes. The mean cycle length in these four patients was 870 msec, with a mean zone of echoes from 350 to 313 msec (4 percent of cycle length). Calculated sinoatrial conduction time ranged from 40 to 153 msec (mean +/- standard deviation 92 +/- 30 msec). Shortening of the cycle length with atrial pacing increased the number of patients with zones of interpolation and echoes. In conclusion, zones of nonreset and reset are found in all patients with normal sinus nodal function, whereas zones of interpolation and echoes are much less common. Sinoatrial conduction time is surprisingly long in patients without apparent sinus node disease.     

Improved sinus node sensing after atropine.

Although atropine is known to increase sinus rate through its vagolytic effect, the effects of atropine on sinus node sensing are unknown. The purpose of this study was to investigate alterations in sinus node sensing produced by atropine. Measurement of the zone of sinus node reset and sinoatrial conduction time was performed in 10 patients by programmed premature atrial stimulation. The zone of sinus node reset was determined as the transition point where premature atrial stimuli were followed by a less than compensatory pause. Sinoatrial conduction time was calculated from sinus node return cycles in the area where sinus node reset occurred. Atropine administration produced a significant increase in the percentage of the sinus cycle length at which premature atrial contractions penetrated and reset the sinus node. Sinus node reset occurred at a mean percentage of the sinus cycle of 71 +/- 8 per cent before atropine and 83 +/- 5 per cent after atropine (P less 0.01). The sinoatrial conduction time was significantly reduced from 109 +/- 29 to 62 +/- 23 msec. (P less than 0.01) from atropine as sinus cycle length was reduced from 909 +/- 118 to 642 +/- 75 msec. after atropine. Sinus node echoes were observed in two patients. In one patient atropine abolished the appearance of sinus node echoes. In the second patient atropine reduced the coupling interval necessary to produce sinus node echoes but appeared to facilitate sinus node re-entry by the appearance of an additional sinus node echo and a reduction in the echo cycle length. This study demonstrates that atropine produces significant improvement of sinus node sensing in man.     

Initiation of atrioventricular nodal reentrant tachycardia in patients with discontinuous anterograde atrioventricular nodal conduction curves with and without documented supraventricular tachycardia: Observations on the role of a discontinuous retrograde conduction curve

To evaluate factors playing a role in initiation of atrioventricular (AV) nodal reentrant tachycardia utilizing anterogradely a slow and retrogradely a fast conducting AV nodal pathway, 38 patients having no accessory pathways and showing discontinuous anterograde AV nodal conduction curves during atrial stimulation were studied. Twenty-two patients (group A) underwent an electrophysiologic investigation because of recurrent paroxysmal supraventricular tachycardia (SVT) that had been electrocardiographically documented before the study. Sixteen patients (group B) underwent the study because of a history of palpitations (15 patients) or recurrent ventricular tachycardia (one patient); in none of them had SVT ever been electrocardiographically documented before the investigation. Twenty-one of the 22 patients of group A demonstrated continuous retrograde conduction curves during ventricular stimulation. In 20 tachycardia was initiated by either a single atrial premature beat (18 patients) or by two atrial premature beats. Fifteen of the 16 patients of group B had discontinuous retrograde conduction curves during ventricular stimulation, with a long refractory period of their retrograde fast pathway. Tachycardia was initiated by multiple atrial premature beats in one patient. Thirteen out of the remaining 15 patients received atropine. Thereafter tachycardia could be initiated in three patients by a single atrial premature beat, by two atrial premature beats in one patient, and by incremental atrial pacing in another patient. In the remaining eight patients tachycardia could not be initiated. Our observations indicate that the pattern of ventriculoatrial conduction found during ventricular stimulation is a marker for ease of initiation of AV nodal tachycardia in patients with discontinuous anterograde AV nodal conduction curves.     

Observations in patients showing A-V junctional echoes with a shorter P-R than R-P interval: Distinction between intranodal reentry or reentry using an accessory pathway with a long conduction time

Single test stimulation of the ventricle revealed initiation of echoes with a supraventricular QRS complex with a shorter P-R than R-P interval in 28 of 300 patients consecutively studied with programmed electrical stimulation of the heart because of documented or suspected tachycardias. In all 28 the initiation of echoes was related to a discontinuity in the retrograde conduction curve. In 10 patients a different atrial activation sequence in the endocavitary leads was present before and after the discontinuity in the retrograde conduction curve. In five of these a sustained tachycardia with a shorter P-R than R-P interval could be initiated, and in all five patients an accessory pathway with a long conduction time as the retrograde arm of the tachycardia circuit could be demonstrated. In these five patients spontaneous initiation of tachycardia was observed during sinus rhythm or after atrial premature beats. Tachycardia accelerated after the administration of atropine. In the remaining 23 patients the initiation of echoes showing a shorter P-R than R-P interval was nonsustained. In these patients spontaneous initiation of such echoes during sinus rhythm or initiation by atrial premature beats was not observed, and echoes with this relation of the P-R and R-P intervals systematically disappeared after administration of atropine.It is postulated that in these patients a slow atrioventricular (A-V) nodal pathway is used in the retrograde direction during echoes showing a shorter P-R than R-P interval. Sustained A-V junctional tachycardia showing this relation between P-R and R-P intervals favors incorporation of an accessory pathway with slow retrograde conduction in the tachycardia circuit.     

An Unusual Narrow QRS Complex Tachycardia: What Is the Mechanism?

The electrocardiogram of a 72‐year‐old woman showed episodes of nonsustained narrow QRS complex tachycardia. Tracing analysis suggested that the arrhythmia was due to interpolated atrial extrasystoles occurring in bigeminal rhythm. Interpolation of atrial extrasystoles is a rare phenomenon. In this condition, a premature atrial beat is “sandwiched” between 2 normal sinus beats, and sinus PP interval containing the extrasystole is often longer than unaffected sinus cycles. Alternative mechanisms for the arrhythmia are discussed, such as: (1) sinus node reentry; (2) 1:2 response to atrial ectopy over the fast and the slow atrioventricular nodal pathways; and (3) couplets of atrial extrasystoles.     

Retrograde His bundle deflection in bundle-branch re-entry.

Atrial echo beats resulting from a reciprocating mechanism involving the bundle-branches were produced by premature atrial impulses in a patient with an A-V nodal bypass tract. The mechanism of the arrhythmia was suggested by the presence of a retrograde His bundle deflection which appeared 'sandwiched' in between a QRS complex with complete right bundle-branch morphology and a negative P wave. Though at a shorter cycle length the His bundle was still activated retrogradely echo beats were not seen because the retrograde H deflection occurred too early, when both bypass tract and A-V node were still effectively refractory. At the faster driven rate concealed retrograde activation of the right branch (by the premature impulse) was responsible for the right bundle-branch block patterns shown by the post-premature driven beat.     

Retrograde His bundle deflection in bundle-branch re-entry.

Atrial echo beats resulting from a reciprocating mechanism involving the bundle-branches were produced by premature atrial impulses in a patient with an A-V nodal bypass tract. The mechanism of the arrhythmia was suggested by the presence of a retrograde His bundle deflection which appeared 'sandwiched' in between a QRS complex with complete right bundle-branch morphology and a negative P wave. Though at a shorter cycle length the His bundle was still activated retrogradely echo beats were not seen because the retrograde H deflection occurred too early, when both bypass tract and A-V node were still effectively refractory. At the faster driven rate concealed retrograde activation of the right branch (by the premature impulse) was responsible for the right bundle-branch block patterns shown by the post-premature driven beat.     

Sinus nodal reentry. Effect of quinidine

The recently developed experimental model for sinus nodal reentry was used to assess the effect of quinidine in 20 dogs. Sinus nodal reentry was demonstrated in 19 dogs and was abolished in all dogs when plasma levels of quinidine (average 4.8 mg/liter) were in the therapeutic range after an average infusion time of 7 minutes. Characteristically in 15 dogs, quinidine increased atrial refractoriness and slowed atrial conduction so that the arrival time of the atrial premature beat (A₂) in the region of the sinus node fell outside the reentry zone and sinus nodal reentry was terminated. Conduction delay along the reentrant pathway preceded loss of sinus nodal reentry in 6 of these 15 dogs, thereby suggesting that quinidine-induced conduction delay and block along the reentrant pathway may be another mechanism for abolishing sinus nodal reentry. In the four remaining dogs in which sinus nodal reentry was abolished when the premature beat continued to fall within the reentry zone, the latter mechanism seems likely.     

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.     

Sinus node re-entrant tachycardia in man.

Sinus node re-entry (SNR) usually appears as a single beat. Tachycardias (SNRT) consistent with sustained SNR were seen in six patients and were initiated by premature stimulation of the high right atrium (six patients) and coronary sinus (four patients), and after continuous pacing from the high right atrium (four patients) or right ventricle (one patient) at rates of 130 to 200 per minute. During SNRT: (1) atrial beats exhibited a high-to-low atrial activation sequence, (2) the P-waves were similar in morphology to P-waves during sinus rhythm, and (3) re-entry in the A-V node or at the site of stimulation could be excluded. The cycle length of SNRT ranged from 625 to 320 msec. and SNRT either terminated spontaneously (six patients) or after premature atrial capture and/or vagal maneuvers (two patients). The electrophysiologic characteristics of SNRT and differentiation of SNRT from A-V nodal re-entry are discussed.     

Facilitation of A-V nodal reciprocation by procainamide.

Procainamide is known to depress conduction through the A-V node, and this property may facilitate the development of ventricular reciprocal beats or echoes. The occurrence of ventricular reciprocal beats was studied in 20 open-chest dogs before and after the administration of procainamide. While the ventricle was paced by basic stimuli, early ventricular premature beats were introduced at various coupling intervals to induce ventricular echoes. When ventricular echoes could be induced in a given heart, there was a continuous range of coupling intervals (or echo zone) within which ventricular echoes occurred. In the control state, no echo occurred in eight dogs and the echoes developed in 12 dogs with the mean echo zone of 38.3 msec. The effect of procainamide was studied at its therapeutic blood levels about 25 minutes after an intravenous injection of the drug in a dose of 10 mg. per kilogram. Of the first group of eight dogs, in which no echo occurred in the control state, four dogs developed ventricular echoes after the administration of procainamide with the mean echo zone of 29.3 msec. for the group. Of the second group of 12 dogs, in which ventricular echoes were induced in the control state, the administration of procainamide increased the echo zone in 10 dogs with the mean echo zone of 67.8 msec. for the group. Ventricular reciprocal beats were often sustained to produce short runs of supraventricular tachycardia in five dogs after the administration of procainamide. The results demonstrated a potentially deleterious effect of procainamide in facilitating the inducation of A-V nodal reciprocation by closely coupled ventricular premature beats.     

Electrophysiologic studies after mustard's operation for d-transposition of the great vessels

Electrophysiologic studies were performed in 16 patients after Mustard's operation for d-transposition of the great vessels. Standard 12 lead electrocardiograms showed the following rhythms: “sinus” (10 patients), junctional (4 patients), atrial flutter (1 patient) and alternating sinus and junctional (1 patient). Overdrive atrial stimulation was used to determine sinus nodal recovery time in the 16 patients. Atrial and atrioventricular (A-V) nodal effective refractory periods were determined in 12 patients utilizing the atrial extrastimulus technique. Twenty-four hour Holter electrocardiographic monitoring was performed in 15 patients. Ten (63 percent) of the 16 patients had abnormal sinus nodal recovery time. The atrial effective refractory period was prolonged in 4 (33 percent) of the 12 patients in whom it was measured. All 12 patients had a normal A-V nodal effective refractory period. Previously undetected arrhythmias were found in all patients when the 24 hour Holter electrocardiogram was compared with the standard electrocardiogram. Atropine shortened the sinus nodal recovery time, atrial effective refractory period and A-V nodal effective refractory period in all patients studied. One patient, whose junctional pacemaker was first to recover after termination of atrial pacing, had conversion to sinus rhythm and normal sinus nodal recovery time after administration of atropine.This study indicates (1) that a diseased sinus node and interrupted atrial pathways are involved in the genesis of arrhythmias after Mustard's operation, and (2) that adequate evaluation of arrhythmias in patients after this operation requires not only the standard electrocardiogram, but also a 24 hour Holter monitor, His bundle electrograms and determination of sinus nodal recovery time and atrial and A-V nodal effective refractory periods.     

Right atrial versus left atrial echo zones: A proposed new criterion for determining the atrial site of retrograde preexcitation

In a patient whose electrocardiogram (ECG) initially (1966) showed a Type A Wolff-Parkinson-White pattern, recurrent supraventricular tachycardia (SVT) developed but never subsequently showed antegrade bypass conduction. Intracardiac pacing studies (1975) revealed that premature high right atrial (induced 250–450 msec after atrial depolarization) or coronary sinus depolarization (250–550 msec) resulted in SVT. Late coronary sinus depolarization resulted in SVT without A-H prolongation. During SVT, P wave morphology changed and the coronary sinus atrial electrogram preceded that from the low right atrium; retrograde ventriculoatrial conduction time was 240 msec. Neither pacing the high right atrium or coronary sinus up to rates of 200 beats/min nor progressive atrial premature depolarizations from the high right atrium or coronary sinus resulted in antegrade bypass conduction. Failure of antegrade bypass conduction does not preclude SVT due to retrograde pre-excitation and must be distinguished from atrioventricular (A-V) nodal reentry. Atrial effective refractory period (200 msec) was shorter than the minimal time required for an atrial impulse to return to the atrium (380 msec), suggesting concealed antegrade bypass conduction. Stimulation of the atrium linked to the A-V bypass results in earlier bypass activation and recovery and explains the differing high right atrial vs coronary sinus echo zones.     

A second zone of compensation during atrial premature stimulation: Evidence for decremental conduction in the sinoatrial junction

125 consecutive patients with premature atrial stimulation were studied. Three demonstrated sinus node return cycles that were fully compensatory following premature atrial stimuli delivered early in diastole. This second zone of compensation was unaccompanied by significant alterations in the post-return cycle lengths or in P-wave morphology of the return cycle. To account for the occurrence of a complete compensatory pause following very early premature atrial depolarizations, we consider the possibility that retrograde conduction of the early atrial premature depolarization (APD) in the sinoatrial junction was delayed for a sufficient length of time to allow the sinus node to depolarize spontaneously on schedule. Collision between the APD and sinus beat would then occur despite the marked prematurity of the APD. Thus, the early APD had encountered the relative refractory period of the sinoatrial junction, suggesting that decrementai conduction takes place within the sinoatrial region in man. These findings imply that there is the potential for reentry in the region of the human sinoatrial junction.     

Initiation of two distinct forms of atrioventricular nodal reentrant tachycardia during programmed ventricular stimulation in man

Of 42 patients with supraventricular tachycardia related to dual atrioventricular (A-V) nodal pathway conduction, 8 had sustained tachycardia induced during programmed ventricular stimulation. The characteristics of the tachycardia in three patients suggested that the A-V nodal reentrant tachycardia used a slow pathway for anterograde conduction and a fast pathway for retrograde conduction (slow-fast form). In these patients, the retrograde effective refractory period was longer in the slow than in the fast pathway. Ventriculoatrial (V-A) conduction curves (V₁-V₂, A₁-A₂) were smooth. Ventricular premature beats, being conducted retrograde over the fast pathway, could activate the slow pathway in an anterograde direction, initiating the slow-fast form of A-V nodal reentrant tachycardia. In the remaining five patients, the tachycardia used a fast pathway for anterograde conduction and a slow pathway for retrograde conduction (fast-slow form). In these patients, the retrograde effective refractory period was longer in the fast than in the slow pathway. V-A conduction curves (V₁-V₂, A₁-A₂) could be either smooth or discontinuous if there was a sudden increase in V-A conduction time. Ventricular premature beats, conducted retrograde over the slow pathway, could activate the fast pathway in an anterograde direction, establishing a tachycardia circuit in reverse of the slow-fast form. In both groups of patients, the ventricular pacing cycle length appeared to be a crucial factor in the ability to expose functional discordance between the two A-V nodal pathways during retrograde conduction.The fast-slow form of A-V nodal reentrant tachycardia, similar to the slow-fast form, could also be induced during atrial premature stimulation in two patients. In this situation, the slow pathway having an anterograde effective refractory period longer, than that of the fast pathway was a requisite condition; anterograde A-V nodal conduction curves (A₁-A₂, H₁-H₂) were smooth. Atrial premature beats, conducted anterograde over the fast pathway, could activate the slow pathway in a retrograde direction resulting In an atrial echo or sustained fast-slow form of A-V nodal reentrant tachycardia.