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Comparative Study
. 2012 Feb 7;59(6):595-606.
doi: 10.1016/j.jacc.2011.10.879.

Atrial conduction slows immediately before the onset of human atrial fibrillation: a bi-atrial contact mapping study of transitions to atrial fibrillation

Gautam G Lalani  1 Amir SchrickerMichael GibsonArmand RostamianDavid E KrummenSanjiv M Narayan
Affiliations
Comparative Study

Atrial conduction slows immediately before the onset of human atrial fibrillation: a bi-atrial contact mapping study of transitions to atrial fibrillation

Gautam G Lalani et al. J Am Coll Cardiol. .

Abstract

Objectives: The aim of this study was to determine whether onset sites of human atrial fibrillation (AF) exhibit conduction slowing, reduced amplitude, and/or prolonged duration of signals (i.e., fractionation) immediately before AF onset.

Background: Few studies have identified functional determinants of AF initiation. Because conduction slowing is required for reentry, we hypothesized that AF from pulmonary vein triggers might initiate at sites exhibiting rate-dependent slowing in conduction velocity (CV restitution) or local slowing evidenced by signal fractionation.

Methods: In 28 patients with AF (left atrial size 43 ± 5 mm; n = 13 persistent) and 3 control subjects (no AF) at electrophysiological study, we measured bi-atrial conduction time (CT) electrogram fractionation at 64 or 128 electrodes with baskets in left (n = 17) or both (n = 14) atria during superior pulmonary vein pacing at cycle lengths (CL) accelerating from 500 ms (120 beats/min) to AF onset.

Results: Atrial fibrillation initiated in 19 of 28 AF patients and no control subjects. During rate acceleration, conduction slowed in 23 of 28 AF patients (vs. no control subjects, p = 0.01) at the site of AF initiation (15 of 19) or latest activated site (20 of 28). The CT lengthened from 79 ± 23 ms to 107 ± 39 ms (p < 0.001) on acceleration, in a spectrum from persistent AF (greatest slowing) to control subjects (least slowing; p < 0.05). Three patterns of CV restitution were observed: 1) broad (gradual CT prolongation, 37% patients); 2) steep (abrupt prolongation, at CL 266 ± 62 ms, 42%); and 3) flat (no prolongation, 21% AF patients, all control subjects). The AF initiation was more prevalent in patients with CV restitution (17 of 23 vs. 2 of 8; p = 0.03) and immediately followed abrupt re-orientation of the activation vector in patients with broad but not steep CV restitution (p < 0.01). Patients with broad CV restitution had larger atria (p = 0.03) and were more likely to have persistent AF (p = 0.04). Notably, neither amplitude nor duration (fractionation) of the atrial signal at the AF initiation site were rate-dependent (both p = NS).

Conclusions: Acceleration-dependent slowing of atrial conduction (CV restitution) precedes AF initiation, whereas absence of CV restitution identifies inability to induce AF. Conduction restitution, but not fractionated electrograms, may thus track the functional milieu enabling AF initiation and has implications for guiding AF ablation and pharmacological therapy.

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Figures

Figure 1
Figure 1. Bi-Atrial Electrode Recordings to Record Sites of AF Initiation
(A) Fluoroscopy showing 64-pole catheters in each atrium. Selected splines are shown in patient-specific electro-anatomic models (NavX, St. Jude Medical, St. Paul, Minnesota) in (B) left anterior oblique (LAO) and (C) right anterior oblique (RAO) views. (D) Left atrial (LA) schematic shows sites of atrial fibrillation (AF) initiation in each patient (red dots, size representing number of patients). The LA is opened transversely at the mitral annulus, with the anterior annulus opened upward. ABL = ablation; CS = coronary sinus; LLPV = left lower pulmonary vein; LUPV = left upper pulmonary vein; RA = right atrium; RLSP = right lower pulmonary vein; RUPV = right upper pulmonary vein.
Figure 2
Figure 2. Steep Conduction Restitution in a Patient With Persistent AF
(A) Intra-atrial activation delay (61 ms) in sinus rhythm. During pacing, conduction time (CT) to latest electrode (D35) shows minimal prolongation from 85 to 94 ms at (B) cycle length (CL) 500 ms, (C) CL 400 ms, and (D) CL 300 ms. (E) At CL 200 ms, just before atrial fibrillation (AF) initiation, CT prolongs dramatically to 135 ms. (F) Steep conduction velocity (CV) restitution. Note the reciprocal decrease in amplitude with CT prolongation (blue diamonds). A12, A34, A56 = anterior roof; CS56 = mid coronary sinus; D35 = inferior posterior wall; E35 = posterior mitral valve annulus; F13 = anterior mitral valve annulus; HRA = high right atrium.
Figure 3
Figure 3. Broad Conduction Restitution in a Patient With Persistent AF
(A) Intra-atrial activation delay (122 ms) in sinus rhythm. During pacing, CT to latest electrode (A13) prolongs progressively from 84 to 139 ms at (B) CL 500 ms, (C) CL 380 ms, (D) CL 280 ms, and (E) CL 170 ms, before AF initiation. (F) Broad CV restitution. A13 = anterior mitral valve annulus; B13, B35 = anterior roof; D13 = superior posterior wall; E35 = inferior posterior wall; F57 = posterior mitral valve annulus; other abbreviations as in Figure 2.
Figure 4
Figure 4. Flat Conduction Restitution in a Patient Without AF
(A) Intra-atrial activation delay (100 ms) in sinus rhythm. During pacing, CT to latest electrode (G56) shows no slowing from (B) CL 550 ms, (C) CL 450 ms, and (D) CL 320 ms to (E) CL 250 ms. Atrial fibrillation did not initiate. (F) Flat CV restitution is seen. A34 = anterior roof; E78 = posterior mitral valve annulus; F12 = inferior mitral valve; G45 = superior mitral valve; H45 = anterior mitral valve; other abbreviations as in Figure 2.
Figure 5
Figure 5. Rate-Dependent Reorientation of Conduction Time Vectors in Patients With Broad Restitution
In each patient, vectors are shown between slowest (CL 500 ms, red) and fastest (blue) rate pacing, for: I) Steep CV restitution; and II) Broad CV restitution. Note the greater vectorial shift in activation between slow/fast rates for patients with broad compared with steep restitution. First panel shows orientation of electrodes in left atrium, and pacing site superimposed on schematic left atrium. Nodes on the grid represent electrodes on the basket. Abbreviations as in Figures 1 and 2.
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