Effect of low estrogen states in healthy women on dispersion of ventricular repolarization

Prevalence of Cardiac Arrhythmias in Transgender and Nonbinary Adult Community Health Center Patients

Purpose: Sex differences in cardiac arrhythmias are well established. This study aimed to explore the prevalence of arrhythmias in transgender and nonbinary (TGNB) adults. Methods: This cross-sectional study utilized electronic medical records from a center specializing in TGNB care. Adults aged ≥18 years with ≥2 medical visits between January 1, 2010, and December 31, 2021, were categorized into self-reported gender groups: TGNB (transgender men, transgender women, nonbinary [NB]-assigned male at birth, NB-assigned female at birth), cisgender men, and cisgender women. The primary outcome was any arrhythmia using age- and race-adjusted regression models comparing transgender patients with cisgender men and cisgender women. Prevalence of arrhythmias was explored in transgender people with a gender-affirming hormone therapy (GAHT) prescription. Results: The sample included 49,862 adults, with 7121 (14%) TGNB persons. Median age was 28 years. Prevalence of arrhythmias was low (0.7-1.4% NB persons, 1.4-1.5% transgender persons). After adjustment, transgender women and transgender men had similar odds of any arrhythmia compared with cisgender men (transgender women: adjusted odds ratio [aOR] 0.89, 95% confidence interval [CI] 0.63-1.24, p = 0.52; transgender men: aOR 1.17, 95% CI 0.82-1.62, p = 0.37), but higher odds of any arrhythmia compared with cisgender women (transgender women: aOR 1.65, 95% CI 1.13-2.34, p = 0.01; transgender men: aOR 2.15, 95% CI 1.48-3.04, p < 0.001). Prevalence of arrhythmias appeared similar among transgender adults regardless of GAHT use (transgender men: 1.5% vs 1.9%, transgender women: 1.2% vs 2.1%). Conclusion: Further research examining arrhythmias in TGNB patients and across gender minority subgroups is warranted, including longitudinal studies evaluating the potential impact of GAHT.

Sex differences in heart: from basics to clinics

Sex differences exist in the structure and function of human heart. The patterns of ventricular repolarization in normal electrocardiograms (ECG) differ in men and women: men ECG pattern displays higher T-wave amplitude and increased ST angle. Generally, women have longer QT duration because of reduced repolarization reserve, and thus, women are more susceptible for the occurrence of torsades de pointes associated with drugs prolonging ventricular repolarization. Sex differences are also observed in the prevalence, penetrance and symptom severity, and also in the prognosis of cardiovascular disease. Generally, women live longer, have less clinical symptoms of cardiac diseases, and later onset of symptoms than men. Sex hormones also play an important role in regulating ventricular repolarization, suggesting that hormones directly influence various cellular functions and adrenergic regulation. From the clinical perspective, sex-based differences in heart physiology are widely recognized, but in daily practice, cardiac diseases are often underdiagnosed and untreated in the women. The underlying mechanisms of sex differences are, however, poorly understood. Here, we summarize sex-dependent differences in normal cardiac physiology, role of sex hormones, and differences in drug responses. Furthermore, we also discuss the importance of human induced pluripotent stem cell-derived cardiomyocytes in further understanding the mechanism of differences in women and men.

The Effects of Different Hormones on Supraventricular and Ventricular Premature Contractions in Healthy Premenopausal Women

Background and Objectives: The effects of gender differences on cardiac parameters have been well-established. In this study, we aimed to evaluate the possible associations of plasma levels of different sex hormones with premature atrial or ventricular contractions in premenopausal women. Materials and Methods: We conducted a prospective study which included women in late reproductive age who presented with palpitations during an eight-month period. A 12-lead electrocardiography, a transthoracic echocardiogram, blood samples, and 24-hour rhythm Holter were conducted on the third day of the menstrual cycle. Results Overall, 93 healthy premenopausal women with a median age of 42 years were enrolled. QTc interval was within normal limits in all patients. The 24 h range of premature atrial contractions (PACs) and premature ventricular contractions (PVCs) was 0–6450 and was 0–21,230, respectively. The median number of PVCs was 540 and the median number of PACs was 212, respectively. In total, 51 patients (54.8%) had a frequency of PVCs > 500/24 h and 37 patients (39.8%) had a frequency of PACs > 500/24 h, respectively. No statistically significant association was shown between any hormone and the frequency of PACs. Regarding PVCs, patients with a PVCs frequency > 500/24 h had higher estradiol levels compared to patients with PVCs less than 500/24 h (median 60 pg/mL versus 42 pg/mL, p = 0.02, OR: 1.01). No association was found between PVCs and other hormones. Conclusions: In premenopausal healthy women, higher estradiol levels are independently associated with increased PVCs. This suggests that estradiol in late reproductive stages may exert proarrhythmic effects.

The Link Between Sex Hormones and Susceptibility to Cardiac Arrhythmias: From Molecular Basis to Clinical Implications

It is well-known that gender is an independent risk factor for some types of cardiac arrhythmias. For example, males have a greater prevalence of atrial fibrillation and the Brugada Syndrome. In contrast, females are at increased risk for the Long QT Syndrome. However, the underlying mechanisms of these gender differences have not been fully identified. Recently, there has been accumulating evidence indicating that sex hormones may have a significant impact on the cardiac rhythm. In this review, we describe in-depth the molecular interactions between sex hormones and the cardiac ion channels, as well as the clinical implications of these interactions on the cardiac conduction system, in order to understand the link between these hormones and the susceptibility to arrhythmias.

Prevalence and risk factors of prolonged corrected QT interval in general Chinese population

BACKGROUND

Corrected QT (QTc) interval has been correlated with total and CVD mortality. Although much is known about the relation between prolonged QTc interval and clinical outcome, there is no information on the prevalence and specific risk factors of QTc prolongation in general Chinese population. We evaluated the prevalence of prolonged QTc interval and its risk factors in general Chinese population, aiming to fill in the gaps in the literature and provide evidence for potential CVD risk prediction and disease burden estimate in community.

METHODS

A population-based survey was conducted on 11,209 participants over the age of 35 in rural areas of Liaoning Province from 2012 to 2013. Twelve-lead ECGs and automatic analysis were performed on all participants. Logistic regression adjustments were made by using the Bazett's formula to correlate specific risk factors with prolonged QTc intervals (> 440 ms) for potential confounders.

RESULTS

The overall prevalence of prolonged QTc interval was 31.6%. The prevalence increased significantly with age (24.1% among those aged 35-44 years; 28.3%, 45-54 years; 35.2%, 55-64 years; 43.4%, ≥65 years, P < 0.001). Participants with a history of CVD had a higher prevalence of QTc prolongation (40.7% vs. 30.0%). In the fully adjusted logistic regress model, older age, abdominal obesity, hypertension, diabetes, hypokalemia and any medicine used in the past two weeks were associated independently with increased risk for prolonged QTc interval (All P < 0.05). We found no significant differences between general obesity, hypocalcemia and hypomagnesemia with prolongation of QTc interval. Female sex showed opposite results after applying clinical diagnostic criteria, and high physical activity could reduce the risk of prolonged QTc interval.

CONCLUSIONS

The prevalence of prolonged QTc interval was relatively high in general Chinese population and listed relevant factors, which would help identify patients at risk in pre-clinical prevention and provide evidence for estimating potential CVD burden and making management strategies in community.

The effects of gender on electrical therapies for the heart: physiology, epidemiology, and access to therapies

The difference between men and women is clear even just by looking at an electrocardiogram: females present higher resting heart rate, a shorter QRS complex length and greater corrected QT interval. The development of these differences from pubertal age onward suggests that sexual hormones play a key role, although their effect is far from being completely understood. Different incidences between sexes have been reported for many arrhythmias, both ventricular and supraventricular, and also for sudden cardiac death. Moreover, arrhythmias are an important issue during pregnancy, both for diagnosis and treatment. Interestingly, cardiovascular structural and electrophysiological remodelling promoted by exercise training enhances this 'gender effect'. Despite all these relevant issues, we lack gender specific recommendations in the current guidelines for electrical therapies for heart rhythm disorders and heart failure. Even more, we continue to see that fewer women are included in clinical trials and are less referred than men for these treatments.

Cardiac repolarization in recently postmenopausal women with or without hot flushes

OBJECTIVE

Menopausal hot flushes are associated with elevated activity of the sympathetic nervous system and may be related to increased risk for cardiovascular events. Sympathetic activation may trigger severe arrhythmias by modulating cardiac repolarization. The aim of this study was to evaluate the impact of hot flushes on cardiac repolarization in postmenopausal women with and without hot flushes.

METHODS

We assessed 150 recently postmenopausal healthy women-72 with hot flushes and 78 without hot flushes. They underwent 24-hour electrocardiographic recording, comprising a total of over 10,000,000 QT-interval measurements. The cardiac repolarization was assessed by measuring QT-intervals, heat rate dependence of QT-end intervals, and T-waves.

RESULTS

The maximal QT-end interval was shorter in women with hot flushes compared with those without hot flushes (481 ± 64 ms vs 493 ± 50 ms; P = 0.046). There were no differences between the rate dependence of QT-end intervals and T-wave measures between the groups. During the night-time hot flush period, we detected a steeper rate-dependence of QT-end intervals and a longer maximal T-peak-T-end interval (117 ± 54 ms vs 111 ± 56 ms; P < 0.001) compared with the control period.

CONCLUSIONS

Women with hot flushes did not have clinically significant differences in ambulatory cardiac repolarization measurements compared with asymptomatic women. However, a sudden sympathetic surge occurring during the night-time hot flush may have direct effects on cardiac repolarization.

Vasomotor hot flashes and cardiac repolarization: a randomized placebo-controlled trial of postmenopausal hormone therapy

OBJECTIVE

The aim of the study was to compare the effects of different hormone therapies on cardiac repolarization in recently postmenopausal women with and without hot flashes.

METHODS

We recruited 150 healthy women: 72 with and 78 without hot flashes. They were randomized and treated for 6 months with transdermal estradiol (1 mg/day), oral estradiol (OE) alone (2 mg/day) or combined with medroxyprogesterone acetate (MPA; 5 mg/day), or placebo. Cardiac repolarization was assessed by measuring QT intervals, rate-dependence of QT-end interval, and T waves from 24-hour electrocardiographic recording before and during hormone therapy, comprising a total of over 20 million QT-interval measurements.

RESULTS

Hot flashes were accompanied with shortened median T-peak - T-end interval (at RR interval of 700, 800, and 900 ms; P = 0.040, 0.020, and 0.032; η = 0.35, 0.39, and 0.37; respectively) during the use of OE but not transdermal estradiol. In contrast, the addition of MPA to OE lengthened the maximal QT-end (at RR interval of 500 ms, P = 0.016, η = 0.27) and the maximal T-peak - T-end interval (at RR interval of 500 and 600 ms; P = 0.016 and 0.032; η = 0.25 and 0.22, respectively). These effects were not seen in women without hot flashes.

CONCLUSIONS

Hot flashes predict beneficial shortening in cardiac repolarization during OE, but not if MPA is combined with OE. These data may provide one explanation for MPA-related cardiac hazards in epidemiological studies.

The Effects of Female Sex Hormones on Ventricular Premature Beats and Repolarization Parameters in Physiological Menstrual Cycle

BACKGROUND

The effects of gender difference on cardiac electrophysiology have been well studied. In this study, we aimed to evaluate the effects of estradiol and progesteron changes occuring in physiological menstrual cycle on ventricular premature beats (VPBs) and cardiac repolarization parameters.

METHODS

Women of reproductive age with VPBs were included into the study group and healthy women were recruited as the control group. During the menstruation period, a 12-lead electrocardiography, blood samples, and 24-hour rhythm Holter were applied to the study group. Similarly, all tests were repeated in the estimated ovulation period (12-14 days before menstruation) by all cases.

RESULTS

The study group consisted of 20 women patients with VPB, and the control group of 18 healthy women. While the number of VPB in the menstruation period was 210 beats/day (interquartile range [IQR]: 1,144), it decreased to 86 beats/day (IQR: 251) in the ovulation period with statistical significance (P < 0.05). Average heart rate in the menstruation period was 81.4 ± 10 beats/min and it significantly increased to 84.6 ± 8 beats/min in the ovulation period (P < 0.05). There were no differences in cardiac repolarization parameters in both menstruation and ovulation periods between the study and control groups. Comparing the menstruation and the ovulation periods, J-Tpeak interval, which reflects early repolarization, was shorter in the ovulation period (193 ± 27.7 ms and 201.1 ± 28.6 ms, respectively; P < 0.05). Other repolarization parameters did not show any significant difference.

CONCLUSION

VPB frequency decreases with estradiol peak in the ovulation period. This suggests that estrogen may have protective effects against ventricular arrhythmias.

Sex differences in cardiac autonomic regulation and in repolarisation electrocardiography

The review summarises the present knowledge on the sex differences in cardiac autonomic regulations and in related aspects of electrocardiography with particular attention to myocardial repolarisation. Although some of the sex differences are far from fully established, multitude of observations show consistent differences between women and men. Despite more pronounced parasympathetic cardiac regulation, women have higher resting heart rate and lower baroreflex sensitivity. Of the electrocardiographic phenomena, women have longer QT interval duration, repolarisation sequence more synchronised with the inverse of the depolarisation sequence, and likely increased regional heterogeneity of myocardial repolarisation. Studies investigating the relationship of these sex disparities to hormonal differences led frequently to conflicting results. Although sex hormones seem to play a key role by influencing both autonomic tone and electrophysiological properties at the cellular level, neither the truly relevant hormones nor their detailed actions are known. Physiologic usefulness of the described sex differences is also unknown. The review suggests that new studies are needed to advance the understanding of the physiologic mechanisms responsible for these inequalities between women and men and provides key methodological suggestions that need to be followed in future research.

Sex hormones and the QT interval: a review

A prolonged QT interval is a marker for an increased risk of ventricular tachyarrhythmias. Both endogenous and exogenous sex hormones have been shown to affect the QT interval. Endogenous testosterone and progesterone shorten the action potential, and estrogen lengthens the QT interval. During a single menstrual cycle, progesterone levels, but not estrogen levels, have the dominant effect on ventricular repolarization in women. Studies of menopausal hormone therapy (MHT) in the form of estrogen-alone therapy (ET) and estrogen plus progesterone therapy (EPT) have suggested a counterbalancing effect of exogenous estrogen and progesterone on the QT. Specifically, ET lengthens the QT, whereas EPT has no effect. To date, there are no studies on oral contraception (OC) and the QT interval, and future research is needed. This review outlines the current literature on sex hormones and QT interval, including the endogenous effects of estrogen, progesterone, and testosterone and the exogenous effects of estrogen and progesterone therapy in the forms of MHT and hormone contraception. Further, we review the potential mechanisms and pathophysiology of sex hormones on the QT interval.

Effect of obstructive sleep apnea on QT dispersion: a potential mechanism of sudden cardiac death

OBJECTIVES

QT dispersion (QT(d)) measures the variability of the ventricular recovery time. QT(d) may identify patients at risk for ventricular arrhythmias and sudden cardiac death (SCD). The purpose of our study was to determine the effect of obstructive sleep apnea (OSA) on QT(d).

METHODS

There were 199 patients studied: 101 patients (28 women, 73 men) with OSA diagnosed in our sleep center and 98 patients (49 women, 49 men) without OSA from the outpatient clinic, representing the control group. QT intervals (milliseconds) were measured in each of the 12 leads of a standard surface electrocardiogram during wakefulness and QT(d) calculated (QT(max) - QT(min)). QT(c)(d), which corrects for heart rate, was also calculated.

RESULTS

Mean age and heart rate were similar in men and women with or without OSA. Control patients exhibited a significant difference (p < 0.001) in QT(d) between men (48 ± 19) and women (31 ± 13). Men and women with OSA had similar QT(d) (56 ± 35 vs. 54 ± 21) but higher QT(d) compared to the control group. QT(c)(d) results were similar to QT(d).

CONCLUSIONS

Patients with OSA and no structural heart disease have a higher QT(d)/QT(c)(d) compared to an overtly healthy patient population, possibly serving as a marker for an increased risk of SCD.

Lack of electrocardiographic changes in women with polycystic ovary syndrome

OBJECTIVE

The aim of the present study was to investigate the potential alterations in electrocardiographic (ECG) pattern in patients with polycystic ovary syndrome (PCOS).

PATIENTS

Fifty PCOS patients and 50 age- and body mass index-matched healthy women were studied.

METHODS

We assessed hormonal and metabolic pattern, and performed ECG analysis for evaluating PQ interval, QRS duration, minimum and maximum QT interval corrected for heart rate (QT(c)min and QT(c)max, respectively), corrected QT dispersion (QT(c)d), corrected J point/T-wave interval (JTend(c)), corrected JTmax interval (JTmax(c)), and corrected Tmax-end interval (Tmax-end(c)).

RESULTS

QT(c)min (399 +/- 21 vs. 396 +/- 25 ms, P = 0.51); QT(c) max (445 +/- 25 vs. 443 +/- 27 ms, P = 0.70); and QT(c)d (46 +/- 13 vs. 47 +/- 15 ms, P = 0.72); JTend(c) (337 +/- 14 vs. 336 +/- 16 ms(1/2), P = 0.74); and JTmax(c) (256 +/- 22 vs. 258 +/- 21 ms(1/2), P = 0.64); Tmax-end(c) (81 +/- 18 vs. 78 +/- 19 ms(1/2), P = 0.42) were not significantly different between PCOS and healthy women.

CONCLUSION

Despite profound differences in hormonal and metabolic pattern, our data demonstrate no significant difference in ECG pattern in PCOS compared to healthy controls.

QT dispersion increases with aging

BACKGROUND

Age-related changes in cardiovascular system are well-known. Arrhythmias in elderly patients constitute most of the urgencies, consultations, or hospitalizations. QT dispersion (QTd) is a simple noninvasive arrhythmogenic marker to demonstrate the electrical instability of the heart. The aim of this study was to investigate how QTd changes with increasing age by calculating the QTd in the elderly and younger subjects.

METHODS

One hundred and forty-six consecutive subjects (62 males and 84 females; age range: 18-82 years) were enrolled in the study. Sixty-seven of the subjects were 65 years and over (mean age, 70 +/- 4), 79 were younger than 65 (mean age, 37 +/- 11). A 12-lead ECG was recorded. The longest and the shortest QT intervals were measured manually on these ECG recordings. QTd was calculated from the formula, QTd = QTmax - QTmin.

RESULTS

Demographic features were similar between the two groups. QTd of the elderly group was found to be significantly higher than the younger group (35.6 +/- 15.6 in elderly, 24.2 +/- 12.4 in younger group, P < 0.001). A positive relationship was found between QTd and age (r = 0.415, P < 0.001). QTd was greater in female than in male (31.9 +/- 16.7 ms vs 26.0 +/- 11.3 ms, respectively, P = 0.018).

CONCLUSIONS

Our study shows that QTd increases with advancing age. We think that long-term follow-up of these patients would be useful to show if there is any relationship between the clinical outcomes and the increase in QTd.

Clinical implication of T-wave morphology analysis as a new repolarization descriptor

BACKGROUND

T-wave morphology analysis (TMA) quantifies irregularities of ventricular repolarization based on singular value decomposition of the 12-lead electrocardiogram (ECG). Furthermore, TMA is useful for risk stratification of patients with myocardial infarction (MI), although gender differences in TMA and the relationship between TMA and heart diseases are unknown. The aim of this study was to evaluate the significance of TMA in healthy individuals and patients with heart diseases.

METHODS AND RESULTS

Patients with heart disease and either with or without an implanted cardioverter defibrillator (ICD, n = 33, 57+/-16 years; non-ICD, n = 50, 67+/-10 years) were studied. Normal control ECGs (n = 114) were selected from Marquette's database (NC, 33+/-13 years) and the TMA descriptors, including T-wave morphology dispersion (TMD) and percentage of the loop area (PL), were calculated. TMD was significantly lower in group NC males than in the group NC females (11+/-5.9 vs 22+/-16, p < 0.0001). PL was significantly higher in group NC than in the ICD and non-ICD groups (0.63+/-0.12 vs 0.53+/-0.15, p < 0.0001). TMD of group NC was significantly lower than that of the ICD and non-ICD groups (14+/-11 vs 47+/-27, p < 0.0001).

CONCLUSION

There are gender differences in TMD. Abnormal values for TMA could reflect abnormalities of ventricular repolarization.

Long term effects of hormone replacement therapy on heart rate variability, QT interval, QT dispersion and frequencies of arrhythmia

BACKGROUND

The aim of the study was to investigate the effects of a long term (1 year) hormone replacement therapy (HRT) on QT interval, QT dispersion (QTd) frequencies of arrhythmia and heart rate variability (HRV) parameters.

METHODS

Forty-six healthy postmenopausal women (mean age; 55.34+/-4.21) as a hormone replacement therapy group and 25 healthy premenopausal women (mean age; 35.36+/-6.06) as a control group were prospectively enrolled to the study. Hormone replacement therapy group was divided into two groups; estrogen replacement therapy (ERT) group (n=23) and progestin-estrogen replacement therapy (PERT) group (n=23). Standard 12 lead electrocardiograms and 24-h ambulatory Holter recording were obtained to evaluate the effects of one year of ERT and PERT on QT intervals, QTd, frequencies of arrhythmias and HRV parameters.

RESULTS

Long term use of ERT increases QT interval, QTd, in the frequencies of arrhythmia and HRV indexes of parasympathetic activity; however, the increase in frequencies of arrhythmia was not statistically significant (p>0.05). Long term use of PERT did not effected QT interval, QTd, frequencies of ventricular arrhythmia and HRV parameters (p>0.05). Frequency of supraventricular tachycardia increased in post-treatment PERT group was compared with pre-treatment PERT group.

CONCLUSION

These findings supported the hypothesis that estrogen may directly modulate ventricular repolarization. But progestin do not effect the ventricular repolarization. However, these findings must be supported with a large-scale study.

Recent advances in understanding sex differences in cardiac repolarization

A number of gender differences exist in the human electrocardiogram (ECG): the P-wave and P-R intervals are slightly longer in men than in women, whilst women have higher resting heart rates than do men, but a longer rate-corrected QT (QT(C)) interval. Women with the LQT1 and LQT2 variants of congenital long-QT syndrome (LQTS) are at greater risk of adverse cardiac events. Similarly, many drugs associated with acquired LQTS have a greater risk of inducing torsades de pointes (TdP) arrhythmia in women than in men. There are also male:female differences in Brugada syndrome, early repolarisation syndrome and sudden cardiac death. The differences in the ECG between men and women, and in particular those relating to the QT interval, have been explored experimentally and provide evidence of differences in the processes underlying ventricular repolarization. The data available from rabbit, canine, rat, mouse and guinea pig models are reviewed and highlight involvement of male:female differences in Ca and K currents, although the possible involvement of rapid and persistent Na current and Na-Ca exchange currents cannot yet be excluded. The mechanisms underlying observed differences remain to be elucidated fully, but are likely to involve the influence of gonadal steroids. With respect to the QT interval and risk of TdP, a range of evidence implicates a protective role of testosterone in male hearts, possibly by both genomic and non-genomic pathways. Evidence regarding oestrogen and progesterone is less unequivocal, although the interplay between these two hormones may influence both repolarization and pro-arrhythmic risk.

Sex differences in ventricular repolarization: from cardiac electrophysiology to Torsades de Pointes

A number of non-cardiovascular drugs have been withdrawn from clinical use due to unacceptable adverse cardiac side-effects involving drug-induced Torsades de Pointes (TdP)--a rare, life-threatening polymorphic ventricular tachycardia associated with prolongation of the action potential duration of ventricular myocytes and, hence, prolongation of the QT interval, of the electrocardiogram (ECG), which measures the total time for activation of the ventricles and their recovery to the resting state. Research has suggested that women are more prone to develop TdP than men during administration of medicines that share the potential to prolong the QT interval, with 65-75% of drug-induced TdP occurring in women. Clinical and experimental studies show that female sex demonstrate differences in the electrocardiographic pattern of ventricular repolarization in human and other animal species and is associated with a longer rate-corrected QT (QTc) interval at baseline than males. Reports of a similar propensity towards drug-induced TdP in both premenopausal and postmenopausal women support factors in addition to those of female sex hormones eliciting sex-based differences in ventricular repolarization. However, conflicting evidence suggests sex hormones may have a role in increasing the susceptibility of women or ultimately reducing the susceptibility of men to TdP. Cyclical variations in hormone levels during the menstrual cycle have been associated with an increased and reduced risk of TdP. In contradiction to this finding, the male sex hormone is thought to be beneficial. Modulation of the ventricular repolarization by testosterone may explain why the QTc interval shortens at puberty, and might account for the tendency towards an age-dependent reduction in the incidence of drug-induced TdP in men. Mechanisms underlying these differences are not fully understood but a case for the involvement of gonadal steroids is obviously strong. Therefore, further non-clinical/clinical investigations ought to be a necessary step to elucidate any sex differences in cardiac repolarization characteristics, QT interval prolongation and susceptibility to cardiac arrhythmias. This may have implications for the development of the safest medicinal products and for the clinical management of cardiac arrhythmias.

Multivariate analysis of risk factors for QT prolongation following subarachnoid hemorrhage

BACKGROUND

Subarachnoid hemorrhage (SAH) often causes a prolongation of the corrected QT (QTc) interval during the acute phase. The aim of the present study was to examine independent risk factors for QTc prolongation in patients with SAH by means of multivariate analysis.

METHOD

We studied 100 patients who were admitted within 24 hours after onset of SAH. Standard 12-lead electrocardiography (ECG) was performed immediately after admission. QT intervals were measured from the ECG and were corrected for heart rate using the Bazett formula. We measured serum levels of sodium, potassium, calcium, adrenaline (epinephrine), noradrenaline (norepinephrine), dopamine, antidiuretic hormone, and glucose.

RESULTS

The average QTc interval was 466 +/- 46 ms. Patients were categorized into two groups based on the QTc interval, with a cutoff line of 470 ms. Univariate analyses showed significant relations between categories of QTc interval, and sex and serum concentrations of potassium, calcium, or glucose. Multivariate analyses showed that female sex and hypokalemia were independent risk factors for severe QTc prolongation. Hypokalemia (<3.5 mmol/l) was associated with a relative risk of 4.53 for severe QTc prolongation as compared with normokalemia, while the relative risk associated with female sex was 4.45 as compared with male sex. There was a significant inverse correlation between serum potassium levels and QTc intervals among female patients.

CONCLUSION

These findings suggest that female sex and hypokalemia are independent risk factors for severe QTc prolongation in patients with SAH.

Repolarization measures and their relation to sex hormones in postmenopausal women with cardiovascular disease receiving hormone replacement therapy

Women are more susceptible to the development of Torsades de Pointes ventricular tachycardia and have a longer heart rate-corrected QT interval than men. A causal role for estrogen has been implicated. The purpose of this study was to investigate if hormone replacement therapy (HRT) resulted in any changes in noninvasive depolarization and repolarization measurements, and to study their relation to circulating concentrations of sex hormones. Sixty postmenopausal women with cardiovascular disease (mean age 59 +/- 7 years; range 44 to 75) were randomized to receive oral conjugated estrogens, transdermal estradiol-17-beta (both with addition of progestins), or placebo. QRS, QT, and JT intervals and their dispersion on 12-lead electrocardiograms were analyzed at baseline, and after 6 and 12 treatment cycles of HRT. Blood samples for analyses of serum concentration of estrogens and androgens were obtained on the same occasions. Neither mean RR, QT, QTc, JT, and JTc intervals, nor QT and JT dispersion changed during treatment. There was a significant inverse relation between the mean JTc interval and the serum concentration of estradiol-17-beta, independent of age, testosterone levels, and abdominal obesity. There was also a significant inverse relation between the change in androstenedione levels and the change in QT interval (Spearman -0.35, p = 0.028) or JT interval (Spearman -0.41, p = 0.009) at 6 treatment cycles compared with baseline. In conclusion, treatment with oral conjugated estrogens or transdermal estradiol-17-beta combined with progestins did not alter depolarization or repolarization measurements. However, the inverse relation between repolarization and androgens fits with an effect of androgens on repolarization in postmenopausal women.

Effects of long-term hormone replacement therapy on QT and corrected QT dispersion during resting and peak exercise electrocardiography in post-menopausal women

It is known that the QT interval is longer in women than men. Estrogen is reported to account for the QT interval prolongation in several studies conducted with hormone replacement therapy (HRT) in postmenopausal women. Along with this, there are conflicting data as regards the effects of HRT on QT interval and dispersion. Moreover, there is no evidence about the effect of HRT on exercise QT parameters. We compared QT parameters obtained from surface electrocardiograms during resting and peak exercise before and after 6 months of HRT consisting of estrogen plus progesterone in healthy postmenopausal women. Twenty-four healthy postmenopausal women were given 0.625 mg/day conjugated estrogens and 2.5 mg/day medroxyprogesterone acetate for 6 months. Exercise stress testing using the Bruce protocol was performed before and after HRT. QT maximum, minimum, dispersion and corrected QT maximum, minimum and dispersion were calculated during resting and peak exercise. HRT resulted in a significant increase in estradiol plasma levels from 24+/-10 pg/mL to 117+/-66 pg/mL (P<0.001). There was no significant difference in resting QT parameters after HRT, whereas QT dispersion and corrected QT dispersion were significantly increased during peak exercise (20+/-7 versus 25+/-10 ms; P<0.05, 33+/-12 versus 41+/-16 ms; P<0.05, respectively). Nonetheless, the other exercise QT parameters were unchanged. The resting QT parameters are not affected by long term HRT consisting of estrogen plus progesterone, which leads to an increase in QT dispersion and corrected QT dispersion during peak exercise.