Faculty Bibliography

BACKGROUND: Unexplained female predominance is observed in long-QT syndrome (LQTS), a congenital autosomal disorder with prolonged repolarization and syncope or sudden death due to ventricular tachyarrhythmias. Our objectives were to evaluate age- and sex-related differences in events among LQTS patients referred to the LQTS International Registry. METHODS AND RESULTS: Age- and sex-related occurrence of events was analyzed in 479 probands (70% females) and 1041 affected family members (QTc >440 ms, 58% females). LQTS-gene mutations were identified in 162 patients: 69 LQT1 carriers (KVLQT1 on 11p15.5), 62 LQT2 carriers (HERG on 7q35-36), and 31 LQT3 carriers (SCN5A on 3p21-24). Females predominated among 366 probands (71% females) and 230 symptomatic family members (62% females). Male probands were younger than females at first event (8+/-7 versus 14+/-10 years, P<0.0001) and had higher event rates by age 15 years than females (74% versus 51%, P<0.0001). Affected family members had similar findings. By Cox analysis adjusting for QTc duration, the hazard ratio for female probands of experiencing events by age 15 years was 0.48 (P<0.001), and it was 1.87 (P=0.09) by age 15 to 40 years. In female family members, the hazard ratio was 0.58 (P<0.001) by age 15 years, and it was 3.25 (P<0.001) by age 15 to 40 years. The event rate was higher in male than female LQT1 carriers (69% versus 32%, P=0.001). No age-sex difference in event rate was detected in LQT2 and LQT3 carriers. CONCLUSIONS: Among LQTS patients, the risk of cardiac events was higher in males until puberty and higher in females during adulthood. The same pattern was evident among LQT1 gene carriers. Unknown sex factors modulate QT duration and arrhythmic events, with preliminary evidence of gene-specific differences in age-sex modulation

BACKGROUND: The duration of the QT interval is only a gross estimate of repolarization. Besides its limited accuracy and reproducibility, it does not provide information on the morphology of the T wave; thus, morphologic alterations such as notches can be only qualitatively described but not objectively quantified. METHODS AND RESULTS: To measure the complexity of repolarization in the long-QT syndrome (LQTS) patients, we previously applied principal component analysis to body surface mapping and found it useful in distinguishing normal from abnormal repolarization patterns (sensitivity, 87%). In the present study, we applied principal component analysis to 12-lead Holter recordings. The index of complexity of repolarization that we have developed (CR24h) reflects the average 24-hour complexity of repolarization and is mathematically defined as the average ratio between the second and the first eigenvalue. We studied 36 LQTS patients and 40 control subjects. A mean of 22+/-1.3 ECG recordings at 1-hour intervals was used in each patient, and a total of 1655 recordings were analyzed. CR24h was significantly higher in LQTS than in control subjects (34+/-12% versus 13+/-3%; P<.0001). A CR24h exceeding 2 SD above the mean of the control group (>20%) was present in 32 of 36 patients (88%). The negative predictive value of CR24h in LQTS was 88%, and the combination of prolonged QT and abnormal CR24h identified all LQTS patients from normal subjects, including 4 affected symptomatic individuals with a normal QT interval duration, suggesting that CR24h provides information independent of QT duration. CONCLUSIONS: Our data suggest that principal component analysis applied to 24-hour, 12-lead Holter recording adequately quantifies the complexity of ventricular repolarization and may become a useful noninvasive diagnostic tool in LQTS

The long QT syndrome (LQTS) is a familial disease characterized by prolonged ventricular repolarization and high incidence of malignant ventricular tachyarrhythmias often occurring in conditions of adrenergic activation. Recently, the genes for the LQTS inked to chromosomes 3 (LQT3), 7 (LQT2), and 11 (LQT1) were identified as SCN5A, the cardiac sodium channel gene and as HERG and KvLQT1 potassium channel genes. These discoveries have paved the way for the development of gene-specific therapy for these three forms of LQTS. In order to test specific interventions potentially beneficial in the molecular variants of LQTS, we developed a cellular model to mimic the electrophysiological abnormalities of LQT3 and LQT2. Isolated guinea pig ventricular myocytes were exposed to anthopleurin and dofetilide in order to mimic LQT3 and LQT2, respectively. This model has been used to study the effect of sodium channel blockade and of rapid pacing showing a pronounced action potential shortening in response to Na+ channel blockade with mexiletine and during rapid pacing only in anthopleurin-treated cells but not in dofetilide-treated cells. Based on these results we tested the hypothesis that QT interval would shorten more in LQT3 patients in response to mexiletine and to increases in heart rate. Mexiletine shortened significantly the QT interval among LQT3 patients but not among LQT2 patients. LQT3 patients shortened their QT interval in response to increases in heart rate much more than LQT2 patients and healthy controls. These findings suggest that LQT3 patients are more likely to benefit from Na+ channel blockers and from cardiac pacing because they are at higher arrhythmic risk at slow heart rates. Conversely, LQT2 patients are at higher risk to develop syncope under stressful conditions, because of the combined arrhythmogenic effect of catecholamines with the insufficient adaptation of their QT interval. Along the same line of development of gene-specific therapy, recent data demonstrated that an increase in the extracellular concentration of potassium shortens the QT interval in LQT2 patients suggesting that intervention aimed at increasing potassium plasma levels may represent a specific treatment for LQT2. The molecular findings on LQTS suggest the possibility of developing therapeutic interventions targeted to specific genetic defects. Until definitive data become available, antiadrenergic therapy remains the mainstay in the management of LQTS patients, however it may be soon worth considering the addition of a Na+ channel blocker such as mexiletine for LQT3 patients and of interventions such as K+ channel openers or increases in the extracellular concentration of potassium for LQT1 and LQT2 patients

The long QT syndrome (LQTS) is a familial disease characterized by abnormally prolonged ventricular repolarization and high incidence of malignant ventricular tachyarrhythmia. Recently, molecular biology studies brought major advancements in the understanding of the pathophysiologic mechanisms of this disease. The genes for the LQTS linked to chromosomes 3 (LQT3). 7 (LQT2) and 11 (LQT1) were identified as SCNSA, the cardiac sodium channel gene and as HERG and KVLQT1 potassium channel genes. We developed a cellular model in which ventricular myocytes were exposed to anthopleurin and dofetilide in order to mimic LQT3 and LQT2, respectively. The effects of sodium channel blockade and rapid pacing were then studied showing a pronounced action potential shortening in response to mexlietine and during rapid pacing only in antopleurin-treated cells but no in dofetilide-treated cells. On this experimental basis, we tested the hypothesis that QT interval would behave differently during similar intervention in LQT3 and LQT2 patients. Results showed that 1) mexiletine shortened significantly the QT interval among LQT3 patients but not among LQT2 patients and 2) LQT3 patients shortened their QT interal in response to increases in heart rate much more than LQT2 patients and healthy controls. These findings demonstrate differential responses of LQTS patients to interventions targeted to their specific genetic defect. They also suggest that LQT3 patients are more likely to benefit from Na+ channel blockers and from cardiac pacing. Conversely, LQT2 patients are at higher risk to develop syncope under stressful conditions, because of the combined arrhythmogenic effect of cathecolamines with the insufficient adaptation of their QT interval when heart rate increases

The long-QT syndrome (LQTS) is a hereditary disorder characterized by an abnormally prolonged QT interval and by life-threatening arrhythmias. Recently, two of the genes responsible for LQTS have been identified: SCN5A, a voltage-dependent Na+ channel on chromosome 3 (LQT3), and HERG, responsible for the rapid component of the delayed rectifier current (IKr), on chromosome 7 (LQT2). We developed an in vitro model to attempt reproduction of the expected alterations in LQT3 and LQT2 patients. Guinea pig ventricular myocytes were exposed to anthopleura toxin A (anthopleurin), an inhibitor of the inactivation of the Na+ current, and to dofetilide, a selective blocker of IKr. Both interventions significantly prolonged action potential duration (APD), by 54 +/- 13 and 62 +/- 16 ms, respectively. Cells pretreated with anthopleurin significantly shortened APD in response to mexiletine, isoproterenol, and rapid pacing (from 264 +/- 38 to 226 +/- 32 ms after mexiletine, P < .001). On the contrary, cells exposed to dofetilide did not shorten the APD after mexiletine and even prolonged it after initial exposure to isoproterenol (from 280 +/- 25 to 313 +/- 20 ms, P < .001); during rapid pacing, APD was shortened but less (38 +/- 9 versus 60 +/- 11 ms, P < .05) than in anthopleurin-treated cells. This study shows that a cellular model for LQTS, based on the recent advances in molecular genetics, can provide adequate 'phenotypes' of prolonged repolarization amenable to the testing of interventions of potential clinical relevance. We found differential responses to Na+ channel blockade, to beta-adrenergic stimulation, and to rapid pacing according to specific pretreatment with either anthopleurin (to mimic LQT3) or dofetilide (to mimic LQT2). These different responses in myocytes bear striking similarities with the differential response to analogous interventions in LQTS patients with mutations on the SCN5A and HERG genes

BACKGROUND: The genes for the long QT syndrome (LQTS) linked to chromosomes 3 (LQT3) and 7 (LQT2) were identified as SCN5A, the cardiac Na+ channel gene, and as HERG, a K+ channel gene. These findings opened the possibility of attempting gene-specific control of ventricular repolarization. We tested the hypothesis that the QT interval would shorten more in LQT3 than in LQT2 patients in response to mexiletine and also in response to increases in heart rate. METHODS AND RESULTS: Fifteen LQTS patients were studied. Six LQT3 and 7 LQT2 patients were treated with mexiletine, and its effects on QT and QTc were measured. Mexiletine significantly shortened the QT interval among LQT3 patients (QTc from 535 +/- 32 to 445 +/- 31 ms, P < .005) but not among LQT2 patients (QTc from 530 +/- 79 to 503 +/- 60 ms, P = NS). LQT3 patients (n = 7) shortened their QT interval in response to increases in heart rate much more than LQT2 patients (n = 4) and also more than 18 healthy control subjects (9.45 +/- 3.3 versus 3.95 +/- 1.97 and 2.83 +/- 1.33, P < .05; data expressed as percent reduction in QT per 100-ms shortening in RR). Among these patients, there is also a trend for LQT2 patients to have syncope or cardiac arrest under emotional or physical stress and for LQT3 patients to have cardiac events either at rest or during sleep. CONCLUSIONS: This is the first study to demonstrate differential responses of LQTS patients to interventions targeted to their specific genetic defect. These findings also suggest that LQT3 patients may be more likely to benefit from Na+ channel blockers and from cardiac pacing because they would be at higher risk of arrhythmia at slow heart rates. Conversely, LQT2 patients may be at higher risk to develop syncope under stressful conditions because of the combined arrhythmogenic effect of catecholamines with the insufficient adaptation of their QT interval when heart rate increases

OBJECTIVES. The aim of the present study was to test, in vivo and in vitro, the influence of adrenergic activation on action potential prolongation induced by the potassium channel blocking agent d-sotalol. BACKGROUND. d-Sotalol is not effective against myocardial ischemia-dependent ventricular fibrillation in the presence of elevated sympathetic activity. Most potassium channel blockers, such as d-sotalol, affect only one of the two components of Ik (Ikr) but not the other (Iks). Iks is activated by isoproterenol. An unopposed activation of Iks might account for the loss of anti-fibrillatory effect by d-sotalol in conditions of high sympathetic activity. METHODS. In nine anesthetized dogs we tested at constant heart rate (160 to 220 beats/min) the influences of left stellate ganglion stimulation on the monophasic action potential prolongation induced by d-sotalol. In two groups of isolated guinea pig ventricular myocytes we tested the effect of isoproterenol (10(-9) mol/liter) on the action potential duration at five pacing rates (from 0.5 to 2.5 Hz) in the absence (n = 6) and in the presence (n = 8) of d-sotalol. RESULTS. In control conditions, both in vivo and in vitro, adrenergic stimulation did not significantly change action potential duration. d-Sotalol prolonged both monophasic action potential duration in dogs and action potential duration of guinea pig ventricular myocytes by 19% to 24%. Adrenergic activation, either left stellate ganglion stimulation in vivo or isoproterenol in vitro, reduced by 40% to 60% the prolongation of action potential duration produced by d-sotalol. CONCLUSIONS. Sympathetic activation counteracts the effects of potassium channel blockers on the duration of repolarization and may impair their primary antifibrillatory mechanism. An intriguing clinical implication is that potassium channel blockers may not offer effective protection from malignant ischemic arrhythmias that occur in a setting of elevated sympathetic activity