Celeen M. Khrestian

Simultaneous Multisite Mapping Studies During Induced Atrial Fibrillation in the Sterile Pericarditis Model: Insights Into the Mechanism of its Maintenance

BACKGROUNDnChronic atrial fibrillation (AF) is thought to be due to multiple, simultaneously circulating wavelets. In the canine sterile pericarditis model, the mechanisms of maintenance of AF are not yet understood.nnnMETHODS AND RESULTSnDuring six induced AF episodes in six dogs with sterile pericarditis, 372 unipolar electrograms were recorded simultaneously from an electrode array placed around both atrial free walls, along with 10 to 24 electrodes from the atrial septum, by use of a multiplexing system. Activation maps during 12 consecutive 100-ms windows were analyzed from an episode of sustained AF in each dog (mean duration, 32 +/- 24 minutes). In two dogs, two such activation maps during the same episode of AF were analyzed. During AF, multiple unstable reentrant circuits (mean number, 1.4 +/- 0.1 per 100-ms analysis window) with very short cycle lengths (mean, 111 +/- 8 ms) present primarily in the atrial septum and right atrium were responsible for maintenance of AF. The unstable reentrant circuits frequently disappeared and re-formed. Wave fronts traveling from one atrium to the other and/or from the atrial septum play an important role in re-formation of unstable reentrant wave fronts.nnnCONCLUSIONSnIn this model of paroxysmal AF, unstable reentrant circuits of very short cycle length principally involving the atrial septum appear to be critical for maintenance of AF. Some reentrant circuits disappear as others re-form, so that at least one reentrant circuit is always present. Because the atria cannot follow their very short cycle lengths in a 1:1 manner, AF is maintained.

Mapping of Atrial Activation During Sustained Atrial Fibrillation in Dogs with Rapid Ventricular Pacing Induced Heart Failure: Evidence for a Role of Driver Regions

Introduction: Dogs with rapid ventricular pacing (RVP)‐induced congestive heart failure (CHF) have inducible atrial tachycardia, flutter, and fibrillation (AF). We tested the hypothesis that rapid atrial activation in multiple regions and at different rates is responsible for sustained AF in this CHF model.

Single site radiofrequency catheter ablation of atrial fibrillation: Studies guided by simultaneous multisite mapping in the canine sterile pericarditis model

OBJECTIVESnTo test the hypothesis that when activation of Bachmanns bundle (BB) is critical to the unstable reentrant circuits that maintain atrial fibrillation (AF) in the sterile pericarditis canine model, a lesion in BB would prevent induction of stable AF.nnnBACKGROUNDnOne mechanism of induced AF in this model is multiple unstable reentrant circuits, which frequently include BB as part of the reentrant pathway.nnnMETHODSnSimultaneous multisite mapping studies during AF and after ablation of BB were performed by recording (384 to 396 electrodes) from both atria and the atrial septum during six induced AF episodes in six dogs with sterile pericarditis. Activation maps of AF (mean duration, 24 +/- 28 min) during 12 consecutive 100-ms windows were analyzed.nnnRESULTSnDuring AF, multiple unstable reentrant circuits (mean, 1.2 +/- 0.2 per window; range, 1 to 4) were observed, 68% involving BB. Nonactivation zones (mean duration, 57 +/- 16 ms in the right atrium and 53 +/- 23 ms in the left atrium) observed during AF were reactivated by a wave front most often coming from the atrial septum via BB (right atrium, 62%; left atrium, 67%). After successful radiofrequency catheter ablation of the midportion of BB, AF >5 s was not induced in all dogs. Mapping studies of transient AF (< or =5 s) induced after ablation showed neither reentrant circuits nor wave fronts activating the right atrium via BB.nnnCONCLUSIONSnIn this AF model, catheter ablation of BB terminates and prevents the induction of AF by preventing 1) formation of unstable reentrant circuits that involve BB, and 2) activation of the atrial-free walls after a nonactivation period.

Role of Functional Block Extension in Lesion-Related Atrial Flutter

Background —A line of block in the right atrium (RA) between the venae cavae is necessary to obtain classic atrial flutter (AFL). We tested the hypothesis that the location of that line of block would determine whether the AFL reentrant circuit would be due to single-loop reentry or figure-of-8 reentry. Methods and Results —Simultaneous mapping from 392 sites (both atria and the atrial septum) was performed in 13 normal dogs before and after creating a linear lesion on the RA free wall. The lesion was 1 to 1.5 cm anterior and parallel to the crista terminalis (7 dogs) or posterior and close to the crista terminalis region (6 dogs). Sustained AFL (>2 minutes) was then induced. In 4 dogs with an anterior lesion, the AFL reentrant circuit traveled around the lesion (lesion reentry). In 9 dogs (3 with anterior lesions and 6 with posterior lesions), the AFL reentrant circuit included the anterior RA free wall, the atrial septum, and Bachmann’s bundle (single-loop reentry). In these 9 dogs, the fixed line of block was extended to the superior and/or inferior vena cava by a functional line of block, thereby preventing lesion reentry. No figure-of-8 reentry was induced. Conclusions —In this model, the location of a fixed line of block and its functional extension determine the type of AFL reentry. These data provide an explanation for the chronic AFL that occurs in some patients after surgical repair of congenital heart lesions.

New Insights Regarding the Atrial Flutter Reentrant Circuit Studies in the Canine Sterile Pericarditis Model

Background-We studied atrial activation during induced atrial flutter in the canine sterile pericarditis model to test the hypothesis that the atrial flutter reentrant circuit includes a septal component. Methods and Results-We studied 10 episodes of induced, sustained (>5 minutes) atrial flutter in 9 dogs. In all episodes, the reentrant circuit included a septal component. In 6 episodes, there were 2 reentrant circuits, one in the right atrial free wall and the second involving the atrial septum, Bachmanns bundle, and the right atrial free wall; both circuits shared a pathway in the right atrial free wall (figure-of-eight). The direction (superior or inferior) of the septal wave front of the second circuit correlated with the direction (clockwise or counterclockwise, respectively) of the right atrial free-wall circuit. A line of functional block in the right atrial free wall was part of both reentrant circuits. In the other 4 atrial flutter episodes, only 1 reentrant circuit was present, with activation in an inferior-to-superior direction in the septum and a superior-to-inferior direction in the right atrial free wall in 2 episodes and in the opposite direction in the other 2 episodes. In all atrial flutter episodes, the flutter wave polarity in ECG lead II was determined by the direction of activation in the left atrium; polarity was positive when the direction was superior to inferior and negative when the direction was inferior to superior. Conclusions-In this model of atrial flutter, the reentrant circuit (1) always included a septal component, (2) did not always require a right atrial free-wall reentrant circuit, (3) demonstrated figure-of-eight reentry when a reentrant circuit was present in the right atrial free wall, and (4) was associated with a line of functional block in the right atrial free wall.

Mechanism of interruption of atrial flutter by moricizine. Electrophysiological and multiplexing studies in the canine sterile pericarditis model of atrial flutter.

BACKGROUNDnMoricizine is said to have potent effects on cardiac conduction but little or no effect on cardiac refractoriness.nnnMETHODS AND RESULTSnThe effects of moricizine (2 mg/kg IV) on induced atrial flutter were studied 2 to 4 days after the creation of sterile pericarditis in 11 dogs. Ten episodes of stable atrial flutter before and after the administration of moricizine were studied in 9 dogs in the conscious, nonsedated state, and 7 episodes were studied in 6 dogs in the anesthetized, open chest state. In the conscious state, the effects of moricizine on atrial excitability, atrial effective refractory period, and intra-atrial conduction times were studied by recording during overdrive pacing of sinus rhythm from epicardial electrodes placed at selected atrial sites. Moricizine prolonged the atrial flutter cycle length in all the episodes, from a mean of 133 +/- 9 to 172 +/- 27 milliseconds (P < .001), and then terminated 7 of the 10 episodes. Moricizine increased the atrial threshold of excitability from a mean of 2.3 +/- 1.4 to 3.3 +/- 2.2 mA (P < .01) and prolonged intra-atrial conduction times (measured from the sulcus terminalis to the posteroinferior left atrium) from a mean of 58 +/- 6 to 64 +/- 5 milliseconds (P < .005). Prolongation of the atrial effective refractory period from 166 +/- 20 to 174 +/- 24 milliseconds (P < .05) was observed only at the sulcus terminalis site. In the open chest studies, administration of moricizine prolonged the atrial flutter cycle length from a mean of 150 +/- 15 to 216 +/- 30 milliseconds (P < .001) and then terminated the atrial flutter in all 7 episodes. As demonstrated by simultaneous multisite mapping from 95 bipolar sites on the right atrial free wall, the atrial flutter cycle length prolongation was either due to further slowing of conduction in an area of slow conduction in the reentrant circuit of the atrial flutter (5 episodes) or further slowing of conduction in an area of slow conduction plus the development of a second area of slow conduction (2 episodes). The change in conduction times in the rest of the reentrant circuit was negligible (10.9 +/- 8.7% of the total change). In all 7 episodes, the last circulating reentrant wave front blocked in an area of slow conduction.nnnCONCLUSIONSnMoricizine (1) prolongs the atrial flutter cycle length, primarily by slowing conduction in an area of slow conduction in the reentrant circuit, (2) terminates atrial flutter by causing block of the circulating reentrant wave front in an area of slow conduction of the reentrant circuit, and (3) effectively interrupts otherwise stable atrial flutter in this canine model. The reason for these effects of moricizine are not readily explained by its effects on global atrial conduction times and refractoriness studied during sinus rhythm. Local changes in conduction in an area(s) of slow conduction are responsible for both cycle length prolongation and atrial flutter termination rather than the traditional wavelength concept of head-tail interaction.

Safety of transvenous atrial defibrillation: studies in the canine sterile pericarditis model.

BACKGROUNDnIt is recognized that a ventricular vulnerability period exists during which atrial shock delivery may induce a ventricular tachyarrhythmia. This study was designed to define the zone in which the ventricles are vulnerable to induction of ventricular tachyarrhythmia during delivery of atrial shocks in the sterile pericarditis canine model of atrial fibrillation.nnnMETHODS AND RESULTSnTwo days after creation of sterile pericarditis, 24 dogs underwent either a four-part or five-part ventricular vulnerability protocol during which atrial shocks were delivered between transvenous catheters, one in the distal coronary sinus and one in the right atrial appendage. The protocol included part 1, shocks during induced atrial fibrillation; parts 2 through 4, shocks delivered synchronously with the last ventricular beat of one of the following three ventricular pacing protocols: constant ventricular rates (S1S1), short-long-short cycles (S1S2S3-V), and ventricular premature beats (S1); and part 5, shocks delivered synchronously with the last R wave resulting from an atrially paced short-long-short cycle (S1S2S3-A). Ventricular tachyarrhythmia was induced 122 times: 2 of 665 shocks in two dogs in part 1, 29 of 786 shocks in nine dogs in part 2, 67 of 734 shocks in 15 dogs in part 3, 24 of 919 shocks in five dogs in part 4, and none in part 5. All ventricular proarrhythmia resulted from shocks delivered during the T wave of a preceding ventricular beat. No episodes of ventricular tachyarrhythmia were induced by atrial shocks synchronized to R waves with the previous RR at intervals above the QT+60 ms interval (absolute interval >320 ms), with one exception, at the QT+100 ms interval (absolute interval 360 ms).nnnCONCLUSIONSnWith transvenous electrode catheters used to deliver atrial shocks, life-threatening ventricular rhythms were induced but were limited to a specific zone defined by the QT interval.

Termination of Atrial Flutter and Fibrillation by K201's Metabolite M-II: Studies in the Canine Sterile Pericarditis Model.

Introduction: K201, a 1,4-benzodiazepine derivative, acts on multiple cardiac ion channels and the ryanodine receptor. We tested whether administration of M-II, the main metabolite of K201, would terminate induced atrial flutter (AFL) or atrial fibrillation (AF) in the canine sterile pericarditis model. Methods: In 6 dogs, electrophysiologic studies were performed at baseline and after drug administration, measuring atrial effective refractory period (AERP), and conduction time from 3 sites during pacing at cycle lengths (400, 300, and 200 milliseconds) on postoperative days 1–4. In 12 induced episodes of sustained AF/AFL (2/10, respectively), M-II was administered intravenously to test efficacy. Five of the AFL episodes were studied in the open chest state during simultaneous multisite atrial mapping. Results: M-II terminated 2/2 AF and 8/10 AFL episodes, prolonged AERP (P < 0.05), significantly increased atrial pacing capture thresholds but did not significantly change atrial conduction time. AFL CL prolongation was largely explained by prolonged conduction in an area of slow conduction in the reentrant circuit. AFL terminated with block in the area of slow conduction. Conclusions: M-II was very effective in terminating AFL/AF in the canine sterile pericarditis model. AFL terminated due to block in the area of slow conduction of the reentrant circuit.