Long-term flecainide therapy in type 3 long QT syndrome.

Aims: Type 3 long QT syndrome (LQT3) is caused by gain-of-function mutations in the cardiac sodium channel gene (SCN5A). Previous reports on the long-term use of sodium channel blockers in LQT3 are sparse. The objective of the current study was to evaluate the long-term safety and efficacy of flecainide therapy in patients with LQT3 who carry the D1790G SCN5A mutation. Methods and results: The study population comprised 30 D1790G carriers who were treated with flecainide and followed for 1-215 months (mean 145 ± 54 months, median 140 months). The mean baseline (off-drug) QTc was 522 ± 45 ms, and shortened to 469 ± 36 ms with flecainide therapy, a mean decrease of 53 ms [10.1%] (P < 0.01). A QTc longer than 500 ms was evident in 53% of carriers at baseline, and only in 13% on flecainide. All carriers while being compliant with flecainide therapy had no cardiac events during an average follow up of 83 ± 73 months. Twenty carriers stopped flecainide after an average follow up of 40 ± 42 months without symptoms. Six of them (30%) had cardiac events 1-11 months after stopping flecainide. Flecainide induced the appearance of Brugada pattern in six carriers (20%, 5 males), was stopped in three and was not associated with arrhythmia. Sinus-node dysfunction was evident in six carriers (20%) and was fully corrected by flecainide in three. Conclusions: These data suggest that long-term flecainide therapy is relatively safe and effective among LQT3 patients who carry the D1790G SCN5A mutation.

Clinical, genetic, and electrophysiologic characteristics of a new PAS-domain HERG mutation (M124R) causing Long QT syndrome.

OBJECTIVES: To describe the clinical, genetic, and electrophysiologic characteristics of a new PAS-domain HERG mutation (M124R) that has been identified in a single large Jewish family with Long QT syndrome (LQTS). BACKGROUND: Many previously reported HERG mutations causing LQTS are located either in the C-terminus, or in the pore region. Relatively fewer clinical data are available on N-terminus (PAS-domain) mutation carriers. METHODS: Clinical data were available in 76 family members (aged 1-93 years, 69 alive) over 18 years of follow-up, while electrocardiographic data were available in 57, and genetic data in 45 family members. Cellular electrophysiology was assessed in transfected Chinese Hamster Ovary (CHO) cells using the whole-cell patch-clamp technique. RESULTS: Thirty-six family members were phenotypically categorized as nonaffected, 3 as equivocal, and 20 as affected. Mean QTc was 410+/-23, 440+/-10, and 498+/-41 ms, respectively, in these three subgroups. Eight out of 20 affected family members were symptomatic: five had only syncope, two had aborted cardiac arrest, and one sudden death. Genetic analyses identified the M124R point mutation in all affected members tested (n=16), while all those tested with nonaffected (n=26) and equivocal (n=3) phenotype did not carry the mutation. The M124R mutation reduced the HERG tail-current density by 65%, significantly accelerated the deactivation kinetics, and caused a negative shift in the voltage dependence of activation. CONCLUSIONS: A new PAS-domain HERG mutation (M124R) was identified as causing LQTS in a large Jewish family, with high penetrance and frequent disease-related symptoms. This mutation markedly decreased the tail-current density and accelerated the deactivation kinetics of the HERG channel in transfected CHO cells.