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CLINICAL RESEARCH: ELECTROPHYSIOLOGIC DISORDERS

Morphology of atrial myocardium in human pulmonary veins

A postmortem analysis in patients with and without atrial fibrillation

Rutger J. Hassink, MD^*,*, H. Thomas Aretz, MD, Jeremy Ruskin, MD and David Keane, MD, PhD

^* University Medical Center, Heart Lung Center, Department of Cardio-Thoracic Surgery, Utrecht, Netherlands
Massachusetts General Hospital, Cardiac Unit, Harvard University, Boston, Massachusetts, USA
Massachusetts General Hospital, Pathology Department, Harvard University, Boston, Massachusetts, USA

Manuscript received April 30, 2003; accepted May 30, 2003.

^* Reprint requests and correspondence: Dr. Rutger J. Hassink, University Medical Center Utrecht, Department of Cardio-Thoracic Surgery, Uppsalalaan 8, 3584 CT Utrecht, the Netherlands.
rutger{at}niob.knaw.nl

Presented, in part, by Dr. Hassink at the Annual Congress of the European Society of Cardiology for which he was awarded the Young Investigator Award for Clinical Science.

OBJECTIVES: We report an in-depth postmortem morphologic analysis of atrial myocardium in human pulmonary veins (PVs) from patients with and without atrial fibrillation (AF).

BACKGROUND: Electrophysiologic studies established the critical role of PVs in the initiation of AF. To date, a paucity of data exists about PV morphology as an arrhythmogenic substrate.

METHODS: Longitudinal tissue-strips of PVs were excised and histologically analyzed from the distal part to just beyond the atriovenous junction in the left atrium from 20 patients, obtained at autopsy. Anatomical measurements, including diameters, lengths, and wall-thicknesses of PVs, obtained at autopsy, were made.

RESULTS: Histological analysis revealed extension of atrial myocardium into 89% of all PVs. Prevalence of myocardial extension was significantly higher in veins of 6 patients with compared with 14 patients without AF. Other significant differences in the histology of PVs between the two groups were a higher frequency of discontinuity and hypertrophy and a higher degree of fibrosis of the atrial myocardium in the PVs of patients with AF. A marked variation existed in anatomical dimensions of PVs, although no differences were observed between patients with or without AF.

CONCLUSIONS: Atrial myocardium was more often present in the PVs of patients with compared with patients without AF. In the first group, the atrial myocardium in the PVs was characterized by more severe discontinuity, hypertrophy, and fibrosis. A marked variation in anatomical dimensions of the PVs existed.

Abbreviations and Acronyms   AF   atrial fibrillation   LIPV   left inferior pulmonary vein   LSPV   left superior pulmonary vein   PV   pulmonary vein   RIPV   right inferior pulmonary vein   RSPV   right superior pulmonary vein   SMA   smooth muscle actin

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