Activation patterns in experimental canine atrial flutter produced by right atrial crush injury.

OBJECTIVES. This study was designed to localize and characterize the atrial flutter reentrant circuit and the electrophysiologic effects of right atrial crush injury in a new canine model. BACKGROUND. In previous studies sustained atrial flutter was induced in the canine heart by rapid atrial pacing after a linear crush injury was placed in the right atrial free wall. METHODS. Eight dogs (group 1) with three electrode plaques on the right and left atria and Bachmann's bundle and seven dogs (group 2) with a single high density electrode plaque on the right atrium were studied with use of a 64-channel computerized mapping system. RESULTS. At baseline, during sinus rhythm and right and left atrial pacing, activation spread uniformly without areas of slow conduction. Crush injury produced marked conduction delay or complete block during sinus rhythm, increasing the mean difference in activation times across the injury compared with control values (group 1, 31 +/- 4 vs. 14 +/- 5 ms, p less than 0.01; group 2, 28 +/- 10 vs. 7 +/- 2 ms, p less than 0.01). Rapid atrial pacing (S1S1 200 ms) above and below the crush injury revealed a line of complete block across which adjacent electrodes recorded markedly different activation times (33 +/- 5 and 38 +/- 12 ms difference, respectively) and around which activation wave fronts proceeded, colliding opposite the stimulating electrodes. The mean atrial flutter cycle length of 11 episodes induced in group 1 and 14 episodes in group 2 was 157 +/- 16 and 140 +/- 16 ms, respectively (p = NS). Activation mapping revealed a reentrant circuit in the right atrium around the crush injury in all episodes. Although the reentrant circuit did not contain a discrete area of slow conduction, activation time below was longer than that above the crush injury (92 +/- 14 vs. 66 +/- 8 ms and 82 +/- 12 vs. 59 +/- 9 ms in groups 1 and 2, respectively, p less than 0.01 for both). Rapid atrial pacing or premature stimuli produced progressive conduction delay and unidirectional block between the crush injury and the tricuspid anulus, inducing atrial flutter directly in 9 of 25 episodes. In 16 episodes, atrial flutter developed after transient induction of atrial fibrillation. CONCLUSIONS. 1) Atrial flutter in this model is due to reentry in the right atrium; 2) the crush injury functions as an anatomic obstacle around which reentry may occur; and 3) the reentrant circuit does not contain a discrete area of slow conduction but, rather, generally slower conduction below the crush injury.     

Role of anatomic architecture in sustained atrial reentry and double potentials.

To determine the role of anatomic architecture in atrial flutter, electrophysiologic findings were correlated with anatomic features in a modified model of atrial flutter with ligation of the crista terminalis. Crista ligation in the middle right atrium prolonged intraatrial conduction time in a rate-dependent manner in 12 dogs, particularly in the low right atrium. With burst atrial pacing, unidirectional block occurred either in the low right atrium or in the interatrial septal region near the superior vena cava, leading to initiation of atrial flutter. Atrial activation mapping revealed a slow conduction area in the low right atrium where conduction had been delayed by crista ligation. On the intact tissues between the venae cavae, double potentials were recorded, a finding indicative of functional block in the center of the reentrant circuit. The interdeflection time of double potentials changed with the activation sequence of atrial flutter. This change could be explained by assuming that the functional center of the reentrant circuit leaned on the right atrial free wall side. Anatomic study demonstrated that areas of slow conduction, unidirectional block, and functional block in the center of the reentrant circuit were closely related to the location of the intact crista terminalis. In conclusion, the intact portion of the crista terminalis played an important role in the genesis of atrial flutter after blockage of longitudinal conduction through the crista.     

Multiplexing studies of effects of rapid atrial pacing on the area of slow conduction during atrial flutter in canine pericarditis model

BACKGROUND. We report that rapid atrial pacing interrupts atrial flutter when the orthodromic wave front from the pacing impulse is blocked in an area of slow conduction in the reentry circuit. To characterize the area of slow conduction during atrial flutter and rapid pacing, we studied 11 episodes of induced atrial flutter, mean cycle length 157 +/- 20 msec, in eight dogs with sterile pericarditis. METHODS AND RESULTS. Atrial electrograms were recorded simultaneously from 95 pairs of right atrial electrodes during the interruption of atrial flutter by rapid atrial pacing, mean cycle length 139 +/- 21 msec. Areas of slow conduction during atrial flutter were demonstrated at one to three sites in the reentry circuit. After rapid pacing captured the reentry circuit, one area of slow conduction either disappeared (10 episodes) or the degree of slow conduction in an area of slow conduction decreased (one episode). Both changes were in association with activation of the region by a wave front from the pacing impulse that arrived from a direction different than that during the induced atrial flutter. Interruption of atrial flutter during rapid pacing occurred when the orthodromic wave front from the pacing impulse blocked in an area of slow conduction that had either newly evolved during rapid pacing (seven episodes) or that was previously present (four episodes). CONCLUSIONS. Areas of slow conduction present during atrial flutter and rapid pacing of atrial flutter are functional and depend on both the atrial rate and the direction of the circulating wave fronts. Interruption of atrial flutter by rapid pacing results from block of the orthodromic wave front of the pacing impulse in an area of slow conduction in the reentry circuit.     

Further observations on entrainment of atrial flutter in the dog

To determine whether the first postpacing interval after entrainment was affected by recording and pacing sites, overdrive atrial pacing was undertaken in 13 episodes of atrial flutter with a mean flutter cycle length (FCL) of 140 +/- 8 msec induced in seven dogs. Atrial flutter was induced by means of an anatomic obstacle. Seven recording sites, four in the right atrium and three in the left atrium, and three pacing sites, two in the right atrium and one in the left atrium, were selected. After entrainment from the right atrium at pacing cycle lengths that were 94% of the FCL, the first postpacing interval was not significantly different from the intrinsic FCL at each recording site, but it tended to be shorter than the FCL at the recording sites near pacing sites. For entrainment from the left atrium, the first postpacing interval was longer than the FCL at recording sites in the left atrium (p less than 0.001), but it was not different from the FCL at recording sites in the right atrium. These results are due to differences in placement of recording and pacing electrodes relative to the reentrant circuit. Also we observed that activation sequences involving three appropriately selected recording sites were always identical when paced from two different pacing sites at a single constant pacing cycle length. This new phenomenon may best be explained by postulating reentry as the mechanism for atrial flutter.     

Circus movement in the canine atrium around the tricuspid ring during experimental atrial flutter and during reentry in vitro

A Y-shaped lesion in the right atrium allows induction of atrial flutter in dogs. We recorded the activation sequence during this tachycardia from 96 endocardial bipolar electrodes using intracavitary electrode arrays during 12 separate episodes in three isolated perfused hearts. In each case a reentrant impulse circulated around the tricuspid valve orifice in either a clockwise or counter-clockwise direction. Cutting the pathway terminated the rhythm and prevented its reinduction. There was no discrete segment of markedly slow conduction in the reentrant circuit. The tachycardia cycle length was decreased by methacholine and increased by lidocaine. Reentry was also induced in atrial tissue around the tricuspid orifice when this structure was isolated and superfused in vitro. Tachycardia cycle lengths varied from 205 to 399 msec, depending on the circumference of the ring and temperature. Induction of tachycardia by premature stimulation depended on differences in the duration of the effective refractory period among parts of the ring. Conduction velocity was relatively uniform and was slower during tachycardias than during pacing at long cycle lengths. Analysis of the response to premature stimuli that reset the tachycardia provided evidence for incomplete recovery of excitability between depolarizations during the tachycardia. Fast-response action potentials were recorded throughout the pathway and up to six to eight cell layers deep. Histologic studies showed the supravalvular lamina, a circumferential band of fibers several cell layers below the endocardial surface, to be continuous around the tricuspid orifice. Propagation through this layer best explains the conduction velocities observed in the intact heart during flutter in this preparation.     

Conduction Properties of the Crista Terminalis in Patients with Typical Atrial Flutter: Basis for a Line of Block in the Reentrant Circuit

Conduction Properties of the Crista Terminalis . Introduction: Previous mapping studies in patients with typical atrial flutter have demonstrated the crista terminalis to he a posterior harrier of the reentrant circuit forming a line of block. However, the functional role of the crista terminalis in patients with or without a history of atrial flutter is not well known. The aim of this study was to determine whether the conduction properties of the crista terminalis are different between patients with and those without a history of atrial flutter. Methods and Results: The study population consisted of 12 patients with clinically documented atrial flutter (group 1) and 12 patients with paroxysmal supraventricular tachycardia as well as induced atrial flutter (group 2). A 7-French, 20-pole, deflectable Halo catheter was positioned around the tricuspid annulus. A 7-French, 20-pole Crista catheter was placed along the crista terminalis identified by the recording of double potentials with opposite activation sequences during typical atrial flutter. After sinus rhythm was restored, pacing from the low posterior right atrium near the crista terminalis was performed at multiple cycle length to 2:1 atrial capture. No double potentials were recorded along the crista terminalis during sinus rhythm in both groups. In group 1, the longest pacing cycle length that resulted in a line of block with double potentials along the crista terminalis was 638 ± 119 msec. After infusion of propranolol, it was prolonged to 832 ± 93 msec without change of the interdeflection intervals of double potentials. In group 2, the longest pacing cycle length that resulted in a line of block with double potentials along the crista terminalis was 214 ± 23 msec. After infusion of procainamide, it was prolonged to 306 ± 36 msec with increase of interdeflection interval of double potentials. Conclusion: The crista terminalis forms a line of transverse conduction block during typical atrial flutter. Poor transverse conduction property in the crista terminalis may be the requisite substrate for clinical occurrence of typical atrial flutter.     

Characterization of double potentials in human atrial flutter: studies during transient entrainment

Double potentials, defined as atrial electrograms with two discrete deflections per beat separated by an isoelectric interval or a low amplitude baseline, have been observed during right atrial endocardial mapping of human atrial flutter. In this study, bipolar atrial electrograms were recorded during atrial flutter (mean cycle length 235 +/- 27 ms [+/- SEM]) from the high right atrium, the His bundle region, the coronary sinus and at least 30 right atrial endocardial mapping sites in 10 patients. Double potentials were recorded from the right atrium in all patients during atrial flutter. Double potentials were evaluated during transient entrainment of atrial flutter by rapid high right atrial pacing in 5 of the 10 patients. In four of these five patients during such transient entrainment 1) one deflection of the double potential was captured with a relatively short activation time (mean interval 89 +/- 45 ms) and the other deflection was captured with a relatively long activation time (mean interval 233 +/- 24 ms), producing a paradoxical decrease in the short interdeflection interval from a mean of 75 +/- 20 ms to a mean of 59 +/- 24 ms; and 2) the configuration of the double potential remained similar to that observed during spontaneous atrial flutter. On pacing termination 1) the two double potential deflections were found to be associated with two different atrial flutter complexes in the electrocardiogram (ECG); 2) the previous double potential deflection relation resumed; and 3) when sinus rhythm was present, the double potentials were replaced by a broad, low amplitude electrogram recording at the same site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Atrial activation sequence during atrial flutter in the canine pericarditis model and its effects on the polarity of the flutter wave in the electrocardiogram

Stable atrial flutter induced in both conscious and open chest states was studied in 30 mongrel dogs after production of sterile pericarditis. During the conscious state studies, induced atrial flutter (mean cycle length 128 +/- 15 ms) was always sustained greater than 15 min and was stable. Three types of flutter wave polarity were noted in electrocardiogram (ECG) lead II: positive in 16 dogs, negative in 3 and flat or slightly positive in 11. Sequential site atrial mapping during atrial flutter (mean cycle length 133 +/- 18 ms) in the open chest state showed either clockwise (18 dogs) or counterclockwise (12 dogs) circus movement in the right atrium. In 19 of 30 dogs, the circus movement clearly did not require any naturally existing anatomic obstacle; in 11, the orifice of the superior vena cava probably was also involved. Double potentials were recorded from the center of the reentrant circuit during atrial flutter, and fractionated electrograms were recorded from a pivot point of the reentrant wave front. A positive flutter wave in ECG lead II (12 dogs with counterclockwise circus movement) was associated with early activation of the Bachmann's bundle region compared with the posteroinferior left atrium and activation of the left atrium mainly in a superoinferior direction. A negative flutter was associated with the early activation of the posteroinferior left atrium compared with Bachmann's bundle and activation of a considerable portion of the left atrium in an inferosuperior direction. A flat or slightly positive flutter wave (14 of 18 with clockwise circus movement) was associated with activation of the left atrium almost simultaneously by two wave fronts coming from both these sites. In conclusion, atrial flutter in this dog model is due to circus movement in the right atrium, the center of which does not necessarily require an anatomic obstacle. Although atrial flutter is generated by circus movement in the right atrium, the flutter wave polarity in the ECG is determined primarily by the activation sequence of the left atrium.     

Activation mapping of reentry around an anatomic barrier in the canine atrium. Observations during entrainment and termination

We determined total right atrial activation sequences during entrainment and termination of flutter induced in dogs with a surgically induced atrial lesion. This type of atrial flutter is due to circus movement of an impulse around the tricuspid valve orifice. We recorded simultaneously from 96 bipolar intracavity electrodes in the right atrium of the isolated, perfused heart. By constructing isochronal maps, we demonstrated the pattern of atrial activation during atrial pacing protocols that either entrained or entrained and then terminated the reentrant rhythm. We show that during pacing the antidromic wavefront from the paced impulse (An) collides with the orthodromic wavefront from the previous paced impulse (On-1). During entrainment, the site of collision of the orthodromic and antidromic wavefronts was constant during pacing at a fixed rate but shifted in the antidromic direction as the pacing rate increased. Furthermore, the last paced beat was entrained only up to the site of collision of the previous paced beat. During one period of entrainment, termination of the reentrant arrhythmia occurred because On-1 blocked in the reentrant pathway due to refractory tissue left by On-2. However, subsequent An did not collide directly with On as was expected, but rather On blocked by an interaction with tissue left refractory by An. Because On was blocked, no reentry occurred when pacing ended.     

Regional control of atrial fibrillation by rapid pacing in conscious dogs

BACKGROUND. In five chronically instrumented conscious dogs, we studied the effects of rapid pacing on sustained electrically induced atrial fibrillation. METHODS AND RESULTS. Twenty-three unipolar atrial electrograms were recorded simultaneously from the bundle of Bachmann and the lateral wall of the right and left atria. During sustained atrial fibrillation, the surface electrocardiogram showed continuous irregularities of the baseline without P or F waves as well as an irregular ventricular rhythm with narrow QRS complexes. The atrial electrograms showed rapid irregular activity with a median cycle length of 85 +/- 8 msec and a range (P5-95) of 33 +/- 18 msec. Overdrive pacing of atrial fibrillation was performed using symmetric biphasic rectangular stimuli (2-msec duration, sixfold that of threshold) applied to a pair of stimulating electrodes at the left atrial appendage. Stimulation was started at pacing intervals of about 10 msec longer than the local median fibrillation interval and subsequently shortened in steps of 1 msec. At a critical pacing interval slightly shorter than the median fibrillation interval, the atrium around the pacing site was suddenly captured by the electrical stimuli. The area of local capture had a diameter of 6.1 +/- 1.6 cm. The time window of capture was 12 +/- 4 msec. CONCLUSIONS. These observations show that during electrically induced atrial fibrillation in chronically instrumented conscious dogs, a short excitable gap is present, permitting regional control of the fibrillatory process by rapid pacing.     

Activation sequence during atrial flutter in dogs with surgically induced right atrial enlargement: I. Observations during sustained rhythms

The atrial activation sequences during 15 episodes of sustained atrial flutters were determined in the isolated hearts of four dogs with surgically induced right atrial enlargement (TI/PS dogs). These sequences were compared with the activation sequences of six episodes of nonsustained atrial tachyarrhythmias induced in three control hearts. Total endocardial activation of both atria during normal sinus rhythm and during the arrhythmias was determined first by recording simultaneously from 192 pairs of recording electrodes positioned into egg-shaped electrode arrays, and then by determining the moment of activation from each of the recorded electrograms. Isochronal maps of total activation were constructed by computer. Nonsustained atrial rhythms inducible in control hearts were due to circus movement excitation either in the left atrium (two episodes) or in the right atrium (four episodes). On the other hand, all 15 episodes of sustained atrial flutter induced and mapped in the TI/PS dog hearts were due to reentrant excitation in the enlarged right atrium. The reentrant pattern could be in a clockwise or counterclockwise pattern. In these episodes of stable flutter an area of functional block was an essential component to the reentrant excitation.     

Circus movement atrial flutter in the canine sterile pericarditis model. Differential effects of procainamide on the components of the reentrant pathway

To evaluate the mechanisms of action of procainamide on the components of the reentrant pathway, drug-induced changes in activation patterns, effective refractory periods (ERPs), and stimulation thresholds were analyzed in nine dogs with sterile pericarditis and sustained atrial flutter. Activation maps were based on 127 close bipolar recordings from a special "jacket" electrode. From the control map, 22 +/- 2 sites covering the slow zone and the normal zone of the reentrant circuit were selected to measure ERPs and thresholds. The excitable gap was estimated from the longest ERP during pacing at the tachycardia cycle length. During atrial flutter, epicardial activation proceeded as a single wave around an arc of functional conduction block in the proximity of the atrioventricular (AV) ring or around a combined functional/anatomic obstacle, with the arc being contiguous with one of the venae cavae. An area of slow conduction, which accounted for 53 +/- 15% of the revolution time within 35 +/- 15% of the total length of the reentrant pathway, was bordered by the arc of block and the AV ring or a caval vein and the AV ring, respectively. Procainamide (5-10 mg/kg i.v.) prolonged the cycle length of atrial flutter from 144 +/- 17 to 190 +/- 24 msec (p less than 0.05) and then terminated the arrhythmia in all studies. The increase in cycle length was due to an increase in conduction time in the slow zone by 37 +/- 11 msec (86 +/- 17% of the total cycle length increase). During the last reentrant beat, conduction failed in the slow zone, with the arc of block joining the AV ring. At termination, procainamide had prolonged conduction time, stimulation threshold, and ERP in the normal zone by 11 +/- 18%, 40 +/- 80%, and 5 +/- 15%, respectively, compared with 51 +/- 16%, 86 +/- 93%, and 14 +/- 21%, respectively, in the slow zone (p less than 0.05 for all three parameters). The duration of the excitable gap did not change significantly. We conclude that procainamide preferentially affected the slow zone of single loop reentrant circuits. The drug terminated circus movement atrial flutter without abolishing the excitable gap, and its effect on conduction seemed the major determinant of the antiarrhythmic action.     

Dispersion of ventricular repolarization and arrhythmia: study of two consecutive ventricular premature complexes

The effect of two consecutive ventricular premature stimuli (S1S2) during atrial pacing on dispersion of repolarization and inducibility of ventricular arrhythmias was studied in 16 dogs under control conditions and in four dogs in the presence of an increased dispersion of repolarization during atrial pacing induced by general hypothermia and regional warm blood perfusion via selective cannulation of the distal branch of left anterior decending coronary artery. Dispersion of repolarization was measured as the maximal difference between the ends of six simultaneously recorded monophasic action potentials (MAPs) from anterior ventricular surface, and consisted of MAP duration difference and activation time difference. Dispersion of repolarization during atrial pacing at control was 29 +/- 7 msec (activation time difference 4 +/- 6 msec, MAP duration difference 25 +/- 8 msec), that after S1 at paraseptal the site was 81 +/- 8 msec (activation time difference 73 +/- 12 msec, MAP duration difference 8 +/- 5 msec), and that after S1S2 was 148 +/- 27 msec (activation time difference 103 +/- 21, MAP duration difference 44 +/- 26 msec). Neither S1 nor S1S2 induced ventricular arrhythmia. Hypothermia and regional warm blood reperfusion increased dispersion of repolarization during atrial pacing to 70 +/- 22 msec (activation time difference 9 +/- 3 msec, MAP duration difference 61 +/- 19 msec). During hypothermia and regional warm blood reperfusion, S1 produced a dispersion of repolarization of 149 +/- 29 msec (activation time difference 85 +/- 8 msec, MAP duration difference 64 +/- 23 msec) and did not induce ventricular arrhythmia.(ABSTRACT TRUNCATED AT 250 WORDS)     

Circus movement atrial flutter in canine sterile pericarditis model. Activation patterns during entrainment and termination of single-loop reentry in vivo

BACKGROUND. Recently, we used a custom designed "jacket" electrode with 127 bipolar electrodes in a flexible nylon matrix to map the total atrial epicardial surface in the in situ canine heart. Atrial flutter in dogs with sterile pericarditis was shown to be due to a single wave front circulating around a combined functional/anatomic obstacle, with the arc of functional conduction block contiguous with one or more of the atrial vessels. METHODS AND RESULTS. In the present study, this model was used to analyze the activation pattern during pacing-induced entrainment and termination of single reentrant loops in a syncytium without anatomically predetermined pathways. Sustained atrial flutter was induced in five dogs with 3-5-day-old sterile pericarditis. Atrial pacing at a cycle length 5-30 msec shorter than the spontaneous cycle length entrained the arrhythmia and could result in a "classical" activation pattern, characterized by an antidromic stimulated wave that collided with the reentrant orthodromic wave front of the previous beat at a constant site. However, two variations of this classical activation pattern were also observed: 1) Pacing at short cycle lengths could lead to localized conduction block in antidromic direction, forcing a change in the pathway of the antidromic wave front. This could prevent the expected shift of the site of collision in antidromic direction. 2) The stimulated orthodromic wave front could also use a pathway different from that of the original reentrant impulse, so that a different circuit was active during the pacing period. Termination of atrial flutter by rapid atrial stimulation was associated with progressive slowing and finally blocking of the paced orthodromic wave front and a progressive shift of the site of collision in antidromic direction. The occurrence of conduction block was determined by the cycle length of stimulation and the number of stimulated beats. A longer train at the critical cycle length or the critical number of beats at a shorter cycle length could reinduce the same reentrant circuit or a different reentrant circuit, respectively, during stimulated cycles following the beat that terminated reentry. CONCLUSIONS. The epicardial activation sequence during entrainment of reentrant arrhythmias does not necessarily follow a standard activation pattern. Instead, the stimulated orthodromic as well as the antidromic wave front might use a pathway different from that of the original reentrant wave front. The mechanisms of termination, failure of termination, and reinitiation of single-loop reentry are similar to those in the "figure-eight" reentrant circuit.     

Electrophysiologic Effects of the New Class III Antiarrhythmic Drug Dofetilide Compared to the Class IA Antiarrhythmic Drug Quinidine in Experimental Canine Atrial Flutter:

Effects of Dofetilide in Canine Atrial Flutter. Introduction: Previous studios that Class III antiarrhythmic drugs are more effective in reentrant arrhythmias because they prolong refractoriness (ERP) and wavelength and reduce dispersion of refractoriness compared to Class IA antiarrhythmic drugs, which slow conduction velocity (CV) in addition to their effects on refractoriness. Methods and Results: To test this hypothesis, the Class III drug dofetilide and the Class IA drug quinidine were studied in the experimental canine crush-injury model of atrial flutter, utilizing right atrial multipoint programmed stimulation and activation mapping. In seven dogs dofetilide prolonged ERP by 23%, slowed CV by 9% at 200-msec cycle length (P < 0.001) and by 39% at 150-msec cycle length (P < 0.001), and increased wavelength by 11% (P < 0.02). Dofetilide reduced dispersion of ERP by 20% (P = 0.003) and adjacent electrodes with ERP difference ≥: 20 msec by 76% (P < 0.001). Dofetilide slowed atrial flutter by 37% (P = 0.003) prior to terminating and suppressing it in all dogs. In eight dogs quinidine prolonged ERP by 14% (P < 0.001), slowed CV by 14% at 200-msec cycle length (P < 0.00) and by 19% at 150-msec cycle length (P < 0.001), and reduced wavelength by 2% (P = NS). Quinidine did not reduce dispersion of refractoriness. Quinidine slowed atrial flutter by 57% (P < 0.001), terminating and suppressing it in only three dogs. Efficacy of dofetilide was greater than quinidine (P = 0.026) and correlated with reduced dispersion of ERP (r = -0.653, P = 0.01), reduced adjacent electrodes with ERP difference ≥ 20 msec (r = -0.637, P = 0.012), and prolonged wavelength (r = 0.61, P = 0.018). Dofetilide and quinidine terminated atrial flutter by similar mechanisms. Myocardial fiber orientation was nonuniform around the crush injury. Conclusions: Antiarrhythmic efficacy of dofetilide was greater than that of quinidine and correlated with drug-induced prolongation of wavelength and reduction in dispersion of refractoriness, effects produced only by dofetilide.     

Onset of induced atrial flutter in the canine pericarditis model

To test the hypothesis that induced atrial flutter evolves from a transitional rhythm, the onset of 99 episodes of induced atrial flutter (mean cycle length 135 +/- 18 ms) lasting greater than 5 min in 40 dogs with sterile pericarditis was first characterized. In 85 (86%) of the 99 episodes, atrial flutter was preceded by a brief period (mean 1.4 +/- 0.9 s, range 0.4 to 42) of atrial fibrillation. Then, in 11 open chest studies, atrial electrograms were recorded simultaneously from 95 pairs of right atrial electrodes during the onset of 18 episodes of induced atrial flutter (mean cycle length 136 +/- 16 ms). Atrial flutter was induced by a train of eight paced atrial beats, followed by one or two premature atrial beats (7 episodes) or rapid atrial pacing (11 episodes). A short period of atrial fibrillation (mean cycle length 110 +/- 7 ms) induced by atrial pacing activated the right atrium through wave fronts, which produced a localized area of slow conduction. Then unidirectional conduction block of the wave front occurred for one beat in all or a portion of the area of slow conduction. This permitted the unblocked wave front to turn around an area of functional block and return through the area of slow conduction that had developed the unidirectional conduction block, thereby initiating the reentrant circuit. The location of the unidirectional block relative to the direction of the circulating wave fronts determined whether the circus movement was clockwise or counterclockwise. The area of slow conduction and unidirectional conduction block occurred where the wave front crossed perpendicular to the orientation of the atrial muscle fibers, suggesting a role for anisotropic conduction. These areas included the high right atrial portion of the sulcus terminalis (10 episodes), the low right atrial portion of the sulcus terminalis (4 episodes) and the pectinate muscle region (4 episodes). It is concluded that the development of a localized area of slow conduction in the right atrium followed by unidirectional conduction block in this area produced during a short period of atrial fibrillation or rapid atrial pacing is necessary for atrial flutter to occur in this model.     

Conduction Properties of the Inferior Vena Cava-Tricuspid Annular Isthmus in Patients with Typical Atrial Flutter

Conduction Properties of the Annular Isthmus. Introduction : A functional region of slow conduction located in the inferior right atrium has been postulated to be critical to the induction and maintenance of typical human atrial flutter. We reexamined the potential role of functional conduction delay in the annular isthmus between the tricuspid valve and the inferior vena cava; it is within this region that such delays have been postulated to occur, and where interruption of conduction by radiofrequency energy application has been shown to eliminate typical flutter.
Methods and Results : Thirty patients with type I atrial flutter (30 counterclockwise, 14 clockwise) were studied. Counterclockwise and clockwise isthmus activation times adjacent and parallel to the tricuspid valve were measured during three conditions: (1) atrial pacing in sinus rhythm, (2) atrial flutter, and (3) entrainment of atrial flutter. During pacing in sinus rhythm at progressively shorter cycle lengths, both counterclockwise and clockwise isthmus activation times remained unchanged; decremental conduction prior to flutter induction or loss of capture was not observed. Counterclockwise isthmus activation time did not significantly differ during flutter (68 ± 23 msec), inferolateral tricuspid annulus pacing (71 ± 23 msec), or entrainment of flutter (72 ± 23 msec). Similarly, clockwise isthmus activation times did not significantly differ between flutter (65 ± 22 msec), proximal coronary sinus pacing (73 ± 21 msec), or entrainment of flutter (64 ± 15 msec).
Conclusion : Decremental conduction is not characteristic of activation through the isthmus when activation is assessed parallel and adjacent to the tricuspid annulus. Functional slowing or conduction delay does not develop in this region during typical atrial flutter.     

Electrogram polarity and cavotricuspid isthmus block during ablation of typical atrial flutter

INTRODUCTION: The atrial activation sequence around the tricuspid annulus has been used to assess whether complete block has been achieved across the cavotricuspid isthmus during radiofrequency ablation of typical atrial flutter. However, sometimes the atrial activation sequence does not clearly establish the presence or absence of complete block. The purpose of this study was to determine whether a change in the polarity of atrial electrograms recorded near the ablation line is an accurate indicator of complete isthmus block. METHODS AND RESULTS: Radiofrequency ablation was performed in 34 men and 10 women (age 60 +/- 13 years [mean +/- SD]) with isthmus-dependent, counterclockwise atrial flutter. Electrograms were recorded around the tricuspid annulus using a duodecapolar halo catheter. Electrograms recorded from two distal electrode pairs (E1 and E2) positioned just anterior to the ablation line were analyzed during atrial flutter and during coronary sinus pacing, before and after ablation. Complete isthmus block was verified by the presence of widely split double electrograms along the entire ablation line. Complete bidirectional isthmus block was achieved in 39 (89%) of 44 patients. Before ablation, the initial polarity of E1 and E2 was predominantly negative during atrial flutter and predominantly positive during coronary sinus pacing. During incomplete isthmus block, the electrogram polarity became reversed either only at E2, or at neither E1 nor E2. In every patient, the polarity of E1 and E2 became negative during coronary sinus pacing only after complete isthmus block was achieved. In 4 patients (10%), the atrial activation sequence recorded with the halo catheter was consistent with complete isthmus block, but the presence of incomplete block was accurately detected by inspection of the polarity of E1 and E2. CONCLUSION: Reversal of polarity in bipolar electrograms recorded just anterior to the line of isthmus block during coronary sinus pacing after ablation of atrial flutter is a simple, quick, and accurate indicator of complete isthmus block.     

Radiofrequency catheter ablation for the treatment of human type 1 atrial flutter. Identification of a critical zone in the reentrant circuit by endocardial mapping techniques.

BACKGROUND. Recent studies of human type 1 atrial flutter demonstrated reentry in the right atrium and an area of slow conduction in the low posteroseptal right atrium. Direct-current catheter ablation of this area has been only moderately successful in preventing recurrence. Therefore, we performed endocardial activation mapping and entrainment pace mapping during atrial flutter to determine the critical site for radiofrequency ablation of this arrhythmia. METHODS AND RESULTS. Twelve consecutive patients (seven men and five women; age, 21-73 years) with type 1 atrial flutter (mean cycle length, 253 +/- 39 msec) underwent right atrial endocardial activation and entrainment pace mapping using standard transvenous catheter techniques to localize the atrial flutter reentrant circuit, the area of slow conduction, and the exit site from the area of slow conduction. Upon identifying appropriate sites, radiofrequency energy (16-29 W) was applied via a 4-mm tipped catheter. Activation mapping of atrial flutter revealed a counterclockwise reentrant wave front originating just inferior or posterior to the coronary sinus ostium, proceeding superiorly in the atrial septum to the right atrial free wall, then inferiorly toward the tricuspid annulus and finally medially between the inferior vena cava and the tricuspid annulus, where low-amplitude fragmented electrical activity was noted. Entrainment pace mapping from this area produced an exact P wave match to atrial flutter on 12-lead ECG with a long (greater than 40 msec) stimulus-to-P interval indicating slow conduction, whereas pacing just inferior or posterior to the coronary sinus ostium produced an exact P wave match with a short stimulus-to-P interval (less than 40 msec), presumably identifying the exit site from the area of slow conduction. Radiofrequency energy (one to 14 applications) was effective in terminating and preventing reinduction of atrial flutter in 10 patients. In two patients, atrial flutter was not terminated during radiofrequency energy application but during subsequent pacing attempts. Sites where ablation was successful, located just inferior or posterior to the coronary sinus ostium, were characterized by discrete electrograms with activation times of -20 to -50 msec before P wave onset and exact entrainment pace maps with a stimulus-to-P interval of 20 to 40 msec, consistent with the exit site from the area of slow conduction. Follow-up (mean, 16 +/- 9 weeks; range, 2-31 weeks) revealed recurrence of the original atrial flutter in two patients, one of whom underwent repeat ablation without further recurrence, self-limited infrequent recurrence of a new atrial flutter or atrial fibrillation in three suppressed by beta-blocker or digoxin, and no recurrence in seven. CONCLUSIONS. 1) Radiofrequency energy applied to a critical area in the atrial flutter reentrant circuit, inferior or posterior to the coronary sinus ostium, will terminate and prevent arrhythmia reinduction. 2) Long-term follow-up in a larger series of patients will be required to confirm efficacy of this technique, although short-term results look promising.     

Short-term rapid atrial pacing produces electrical remodeling of sinus node function in humans

INTRODUCTION: Depression of sinus node function occurs in dogs and in patients after cessation of atrial flutter and fibrillation. We tested whether transient atrial pacing might produce similar changes in humans. METHODS AND RESULTS: We studied the impact of short-term rapid atrial pacing, simulating atrial tachyarrhythmias, on sinoatrial conduction time (SACT) and corrected sinus node recovery time (CS-NRT) in 10 patients undergoing electrophysiologic study. None had recognizable structural heart disease, history of atrial fibrillation or flutter, autonomic dysfunction, or any tachycardia for at least 24 hours before study. All cardiac drugs were discontinued >5 half-lives prior to study. No patient had significant hypotension during atrial stimulation. SACT and CSNRT were measured at baseline, and sinus node reset zone was determined. Right atrial pacing was performed for 10 to 15 minutes, after which SACT and CSNRT were measured again. Both parameters increased significantly, from 423+/-208 msec to 491+/-214 msec and from 80+/-50 msec to 96+/-53 msec, respectively (P = 0.02 and P < 0.001, respectively). CONCLUSION: Rapid atrial pacing for only 10 to 15 minutes, simulating transient atrial tachyarrhythmias, alters sinus node function in humans. Additional studies are needed to evaluate the mechanism, but the clinical implication is that even transient episodes of atrial tachyarrhythmias can cause sinus node remodeling in patients.