Quantitative Assessment of the Spatial Organization of Atrial Fibrillation in the Intact Human Heart

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Circulation. 1996;93:513-518

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(Circulation. 1996;93:513-518.)
© 1996 American Heart Association, Inc.

Articles

Quantitative Assessment of the Spatial Organization of Atrial Fibrillation in the Intact Human Heart

Gregory W. Botteron, MD; Joseph M. Smith, MD, PhD

From the Washington University School of Medicine, Cardiovascular Division, St Louis, Mo.

Correspondence to Joseph M. Smith, MD, PhD, Assistant Professor of Medicine, Washington University School of Medicine, 660 S Euclid Ave, Box 8086, St Louis, MO 63110. E-mail joesmith@visar.wustl.edu.

Background Atrial activation during atrial fibrillation (AF)is frequently described as random or chaotic. We propose that activationduring AF is constrained by the principles of reentrant excitation;that these constraints impart a measurable spatial organizationto activation during AF; and that the distance over which activationsequences remain well correlated can be readily measured and relatedboth to the propensity of AF to sustain itself as well as to atrialtissue wavelength.

Methods and Results We describe a novel signal-processing techniquethat quantifies the correlation in activation sequences recordedfrom five equally spaced sites in the right atrium in patientsundergoing electrophysiology studies. In 20 patients in AF (12with paroxysmal AF, 5 with chronic AF, and 3 with no clinicalhistory of AF), the average correlation was 0.54±0.12at 11 mm and 0.32±0.11 at 44 mm, compared with 0.95±.023and 0.91±.023 in sinus rhythm. In AF, the correlationversus distance relation was monotonically decreasing, wellfit by a decaying exponential function. The space constant ofthis exponential function, termed the activation space constant,provides a single objective metric of the spatial organizationof activation during AF. The mean activation space constantfor the group was 2.6±1.15 cm. Chronic AF had the lowestmean activation space constant (1.84±0.36 cm) and AFin patients with no prior history of AF had the highest (3.06±0.40cm) (P<.05), with paroxysmal AF characterized by intermediate values(2.80±1.4 cm).

Conclusions Using a novel method to measure the spatial organizationof atrial activation during AF, we have demonstrated that AFin the intact human heart is organized over a length scale consistentwith reentrant excitation. Preliminary results suggest a relationshipbetween measured spatial organization and the clinical courseof the arrhythmia. Further work is needed to determine whethermeasurement of spatial organization may be useful in prospectivepatient-specific selection of therapeutic options.

Key Words: fibrillation • electrophysiology • atrium

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