This Article Full Text Full Text (PDF) All Versions of this Article: 2/5/531    most recent CIRCEP.109.862441v1 Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Google Scholar Articles by Amin, A. S. Articles by Tan, H. L. PubMed PubMed Citation Articles by Amin, A. S. Articles by Tan, H. L. Related Collections Exercise testing Electrocardiology Arrhythmias, clinical electrophysiology, drugs

Original Articles

Exercise-Induced ECG Changes in Brugada Syndrome

Ahmad S. Amin, MD; Elisabeth A.A. de Groot, BSc; Jan M. Ruijter, PhD; Arthur A.M. Wilde, MD, PhD and Hanno L. Tan, MD, PhD

From the Heart Failure Research Center (A.S.A., E.A.A.d.G., J.M.R., A.A.M.W., H.L.T.) and Department of Cardiology (A.A.M.W., H.L.T.), Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands.

Correspondence to Hanno L. Tan, MD, PhD, Department of Cardiology, Academic Medical Center, Room K2–109, Meibergdreef 9, 1105 AZ, Amsterdam, The Netherlands. E-mail h.l.tan{at}amc.nl

Received March 3, 2009; accepted August 12, 2009.

Background— Ventricular arrhythmia occurrence during exercise is reported in Brugada syndrome (BrS). Accordingly, experimental studies suggest that BrS-linked SCN5A mutations reduce sodium current more at fast heart rates. Yet, the effects of exercise on the BrS ECG phenotype have not been studied. We aimed to assess ECG responses to exercise in BrS and determine whether these responses are affected by the presence of an SCN5A mutation.

Methods and Results— ECGs at baseline, at peak exercise, and during recovery were analyzed from 35 male control subjects, 25 BrS men without SCN5A mutation (BrS_SCN5A–), and 25 BrS men with SCN5A mutation (BrS_SCN5A+; 15 with missense mutation and 10 with mutation leading to premature truncation of the protein). No differences existed in clinical phenotype between BrS groups. At baseline, BrS_SCN5A– and BrS_SCN5A+ patients had lower heart rates, wider QRS, shorter QT_c, and higher peak J-point amplitudes than control subjects; BrS_SCN5A+ patients also had longer PR than BrS_SCN5A– and control subjects. Exercise resulted in PR shortening in all groups, more QRS widening in BrS_SCN5A+ than in BrS_SCN5A– and control subjects_, and less QT shortening in BrS_SCN5A– and BrS_SCN5A+ than in control subjects. The latter resulted in QT_c shortening in control subjects but QT_c prolongation in BrS_SCN5A– and BrS_SCN5A+. Finally, the increase in peak J-point amplitude during exercise was similar in all 3 groups but resulted in a coved-type pattern only in BrS_SCN5A– and BrS_SCN5A+.

Conclusions— Exercise aggravated the ECG phenotype in BrS. The presence of an SCN5A mutation was associated with further conduction slowing at fast heart rates. Possible mechanisms that may explain the observed ECG changes are discussed.

Key Words: Brugada syndrome • arrhythmia • exercise • tachycardia • SCN5A, mutation • ECG

---

 

CLINICAL PERSPECTIVE