QT prolongation and safety in the Indian population

The QT interval in electrocardiogram (ECG) reflects the total duration of ventricular myocardial depolarization and repolarization. It has been well recognized that many condition may cause QT interval prolongation. Unfortunately, numbers of cardiac and non-cardiac drug prolong the QT interval and cause a distinctive polymorphic ventricular tachycardia termed torsade de pointes (TdP). TdP can degenerate into ventricular fibrillation, which leads to sudden cardiac death. Recently various regulatory and clinical bodies of Europe, USA, Canada and Australia have made their focus on the drugs that induce prolongation of QT interval. Committee for Proprietary Medicinal Products (CPMP) of the European Agency issued a document entitled 'Points to Consider: The assessment of the potential for QT interval prolongation by non-cardiovascular medicinal products' [1, 2]. In addition, USFDA adopted the guideline 'Clinical evaluation of QT/QTc interval prolongation and proarrhythmic potential for non-anti arrhythmic drugs' [3]. These documents and guidelines are primarily concern with development of novel agents and the new use or new dose of already approved drugs. The scope of this guideline is to study the effect of drugs on QT prolongation and give idea of evaluation of drug's effects on QT prolongation. Today more than 50 available drugs (both old and new) have been identify, which prolong the QT interval [1]. Several drugs have been withdrawn from many countries on this basis but many of these drugs are still available in Indian market and potentially creating life-threatening arrhythmias. This article will focus on recommendation of study on the normal limits of QT interval in Indian population and preparation of the database, which can be helpful in withdrawal of drugs from the market that produces QT prolongation.     

Effects of a single oral dose of sparfloxacin on ventricular repolarization in healthy volunteers

1 Sparfloxacin, a new fluoroquinolone, slightly increases the duration of the QT interval. Reverse rate-dependence of QT interval prolongation has been shown for many agents that are known to prolong QT interval duration, and QT prolongation at slow heart rates may be a risk factor for torsades de pointes.
2 A double-blind, randomized, placebo controlled, crossover study was performed in 15 healthy volunteers to determine the effects of single oral doses of sparfloxacin (200 and 400  mg) on the QT interval at various heart rates.
3 12-lead ECGs were recorded at rest and during exercise tests 5  h after sparfloxacin or placebo administration. QT intervals were calculated at predetermined RR intervals (1000, 800, 700, 600, 500 and 400 ms) after individual QT-RR curve fitting.
4 Sparfloxacin at both doses induced prolongation of the QT interval which was around 4% greater than placebo. No significant reverse rate-dependence of QT interval prolongation was observed.
5 Oral administration of sparfloxacin appears unlikely to be associated with marked QT interval prolongation.     

Acquired QT interval prolongation and HERG: implications for drug discovery and development

Putative interactions between the Human Ether-a-go-go Related Gene (HERG), QT interval prolongation and Torsades de Pointes (TdP) are now integral components of any discussion on drug safety. HERG encodes for the inwardly rectifying potassium channel (I_Kr), which is essential to the maintenance of normal cardiac function. HERG channel mutations are responsible for one form of familial long QT syndrome, a potentially deadly inherited cardiac disorder associated with TdP. Moreover, drug-induced (acquired) QT interval prolongation has been associated with an increase in the incidence of sudden unexplained deaths, with HERG inhibition implicated as the underlying cause. Subsequently, a number of non-cardiovascular drugs which induce QT interval prolongation and/or TdP have been withdrawn. However, a definitive link between HERG, QT interval prolongation and arrhythmogenesis has not been established. Nevertheless, this area is subject to ever increasing regulatory scrutiny. Here we review the relationship between HERG, long QT syndrome and TdP, together with a summary of the associated regulatory issues, and developments in pre-clinical screening.     

In vivo effects of the IKr agonist NS3623 on cardiac electrophysiology of the guinea pig

The long QT syndrome is characterized by a prolongation of the QT interval measured on the surface electrocardiogram. Prolonging the QT interval increases the risk of dangerous ventricular fibrillations, eventually leading to sudden cardiac death. Pharmacologically induced QT interval prolongations are most often caused by antagonizing effects on the repolarizing cardiac current called IKr. In humans IKr is mediated by the human ether-a-go-go related gene (hERG) potassium channel. We recently presented NS3623, a compound that selectively activates this channel. The present study was dedicated to examining the in vivo effects of NS3623. Injection of 30 mg/kg NS3623 shortened the corrected QT interval by 25 +/- 4% in anaesthetized guinea pigs. Accordingly, 50 mg/kg of NS3623 shortened the QT interval by 30 +/- 6% in conscious guinea pigs. Finally, pharmacologically induced QT prolongation by a hERG channel antagonist (0.15 mg/kg E-4031) could be reverted by injection of NS3623 (50 mg/kg) in conscious guinea pigs. In conclusion, the present in vivo study demonstrates that injection of the hERG channel agonist NS3623 results in shortening of the QTc interval as well as reversal of a pharmacologically induced QT prolongation in both anaesthetized and conscious guinea pigs.     

Evaluation of the impact of altered lipoprotein binding conditions on halofantrine induced QTc interval prolongation in an anaesthetized rabbit model

Halofantrine has been observed to cause QT interval prolongation in susceptible patients and the effect has most commonly been observed after post-prandial administration. Halofantrine-induced QT prolongation occurs in conjunction with a significant increase in plasma halofantrine concentrations and an increase in halofantrine association with post-prandial plasma lipoproteins. The increased association of halofantrine with post-prandial lipoproteins is accompanied by a marked change in drug distribution between the different plasma lipoprotein fractions. This study was designed to evaluate the putative role of myocardium-based lipoprotein receptor-mediated uptake of lipoproteins as a possible contributing factor to the observed effect of halofantrine on QT intervals. The extent of QT interval prolongation following intravenous halofantrine administration (10 mg kg(-1)) to normolipidaemic (fasted) or hyperlipidaemic (induced with Intralipid infusion) anaesthetized New Zealand White rabbits (n = 6) was determined, as was the distribution of halofantrine between the plasma lipoprotein classes. The results, however, were in contrast to the suggested hypothesis since the QT interval was reduced (and not increased) after halofantrine administration to hyperlipidaemic rabbits relative to fasted rabbits. Therefore, it is unlikely that lipoprotein-based uptake of halofantrine into the myocardium is a major contributor to the previously observed increase in QT prolongation after post-prandial administration of halofantrine.     

Zoniporide: a potent and highly selective inhibitor of human Na(+)/H(+) exchanger-1

Many antipsychotic drugs produce QT interval prolongation on the electrocardiogram (ECG). Blockade of the human cardiac K(+) channel known as human ether-a-go-go-related gene (HERG) often underlies such clinical findings. In fact, HERG channel inhibition is now commonly used as a screen to predict the ability of a drug to prolong QT interval. However, the exact relationship between HERG channel blockade, target receptor binding affinity and clinical QT prolongation is not known. Using patch-clamp electrophysiology, we examined a series of seven antipsychotic drugs for their ability to block HERG, and determined their IC(50) values. We then compared these results to their binding affinities (K(i) values) for the dopamine D(2) receptor, the 5-HT(2A) receptor and, where available, to clinical QT prolongation data. We found that sertindole, pimozide and thioridazine displayed little (<10-fold) or no selectivity for dopamine D(2) or 5-HT(2A) receptors relative to their HERG channel affinities. This lack of selectivity likely underlies the significant QT interval prolongation observed with administration of these drugs. Of the other drugs tested (ziprasidone, quetiapine, risperidone and olanzapine), olanzapine displayed the greatest selectivity for dopamine D(2) and 5-HT(2A) receptor binding (100-1000-fold) compared to its HERG channel IC(50). We also compared these HERG channel IC(50) values to QT interval prolongation and plasma drug levels obtained in a recent clinical study. We found that the ratio of total plasma drug concentration to HERG IC(50) value was indicative of the degree of QT prolongation observed. Target receptor affinity and expected clinical plasma levels are important parameters to consider for the interpretation of HERG channel data.     

Prediction of drug-induced QT interval prolongation in telemetered common marmosets

Drug-induced QT interval prolongation is a critical issue in development of new chemical entities, so the pharmaceutical industry needs to evaluate risk as early as possible. Common marmosets have been in the limelight in early-stage development due to their small size, which requires only a small amount of test drug. The purpose of this study was to determine the utility of telemetered common marmosets for predicting drug-induced QT interval prolongation. Telemetry transmitters were implanted in common marmosets (male and female), and QT and RR intervals were measured. The QT interval was corrected for the RR interval by applying Bazett's and Fridericia's correction formulas and individual rate correction. Individual correction showed the least slope for the linear regression of corrected QT (QTc) intervals against RR intervals, indicating that it dissociated changes in heart rate most effectively. With the individual correction method, the QT-prolonging drugs (astemizole, dl-sotalol) showed QTc interval prolongations and the non-QT-prolonging drugs (dl-propranolol, nifedipine) did not show QTc interval prolongations. The plasma concentrations of astemizole and dl-sotalol associated with QTc interval prolongations in common marmosets were similar to those in humans, suggesting that the sensitivity of common marmosets would be appropriate for evaluating risk of drug-induced QT interval prolongation. In conclusion, telemetry studies in common marmosets are useful for predicting clinical QT prolonging potential of drugs in early stage development and require only a small amount of test drug.     

Predicting QT prolongation in humans during early drug development using hERG inhibition and an anaesthetized guinea-pig model

BACKGROUND AND PURPOSE: Drug-induced prolongation of the QT interval can lead to torsade de pointes, a life-threatening ventricular arrhythmia. Finding appropriate assays from among the plethora of options available to predict reliably this serious adverse effect in humans remains a challenging issue for the discovery and development of drugs. The purpose of the present study was to develop and verify a reliable and relatively simple approach for assessing, during preclinical development, the propensity of drugs to prolong the QT interval in humans. EXPERIMENTAL APPROACH: Sixteen marketed drugs from various pharmacological classes with a known incidence -- or lack thereof -- of QT prolongation in humans were examined in hERG (human ether a-go-go-related gene) patch-clamp assay and an anaesthetized guinea-pig assay for QT prolongation using specific protocols. Drug concentrations in perfusates from hERG assays and plasma samples from guinea-pigs were determined using liquid chromatography-mass spectrometry. KEY RESULTS: Various pharmacological agents that inhibit hERG currents prolong the QT interval in anaesthetized guinea-pigs in a manner similar to that seen in humans and at comparable drug exposures. Several compounds not associated with QT prolongation in humans failed to prolong the QT interval in this model. CONCLUSIONS AND IMPLICATIONS: Analysis of hERG inhibitory potency in conjunction with drug exposures and QT interval measurements in anaesthetized guinea-pigs can reliably predict, during preclinical drug development, the risk of human QT prolongation. A strategy is proposed for mitigating the risk of QT prolongation of new chemical entities during early lead optimization.     

抗精神病药与QT间期延长关系研究进展

本文分析QT间期延长、尖端扭转性室速和心脏猝死之间的关系，并重点叙述QT间期延长的易感素质、抗精神病药对QT间期的影响以及如何预防QT间期延长。     

Clinical relevance and management of drug-related QT interval prolongation

Much attention recently has focused on drugs that prolong the QT interval, potentially leading to fatal cardiac dysrhythmias (e.g., torsade de pointes). We provide a detailed review of the published evidence that supports or does not support an association between drugs and their risk of QT prolongation. The mechanism of drug-induced QT prolongation is reviewed briefly, followed by an extensive evaluation of drugs associated with QT prolongation, torsade de pointes, or both. Drugs associated with QT prolongation are identified as having definite, probable, or proposed associations. The role of the clinician in the prevention and management of QT prolongation, drug-drug interactions that may occur with agents known to affect the QT interval, and the impact of this adverse effect on the regulatory process are addressed.     

QT-RR relationships and suitable QT correction formulas for halothane-anesthetized dogs

Several QT correction (QTc) formulas have been used for assessing the QT liability of drugs. However, they are known to under- and over-correct the QT interval and tend to be specific to species and experimental conditions. The purpose of this study was to determine a suitable formula for halothane-anesthetized dogs highly sensitive to drug-induced QT interval prolongation. Twenty dogs were anesthetized with 1.5% halothane and the relationship between the QT and RR intervals were obtained by changing the heart rate under atrial pacing conditions. The QT interval was corrected for the RR interval by applying 4 published formulas (Bazett, Fridericia, Van de Water, and Matsunaga); Fridericia's formula (QTcF = QT/RR(0.33)) showed the least slope and lowest R(2) value for the linear regression of QTc intervals against RR intervals, indicating that it dissociated changes in heart rate most effectively. An optimized formula (QTcX = QT/RR(0.3879)) is defined by analysis of covariance and represents a correction algorithm superior to Fridericia's formula. For both Fridericia's and the optimized formula, QT-prolonging drugs (d,l-sotalol, astemizole) showed QTc interval prolongation. A non-QT-prolonging drug (d,l-propranolol) failed to prolong the QTc interval. In addition, drug-induced changes in QTcF and QTcX intervals were highly correlated with those of the QT interval paced at a cycle length of 500 msec. These findings suggest that Fridericia's and the optimized formula, although the optimized is a little bit better, are suitable for correcting the QT interval in halothane-anesthetized dogs and help to evaluate the potential QT prolongation of drugs with high accuracy.     

Assessment of the effect of a single oral dose of telithromycin on sotalol-induced qt interval prolongation in healthy women

AIMS: Telithromycin belongs to ketolides, a new class of macrolide antibiotics. Macrolides are known to have the potential to prolong QT interval duration. Previous studies have shown that telithromycin did not induce significant QT interval prolongation in healthy subjects compared with placebo. The main objective of this study was to demonstrate the absence of amplification of QT interval prolongation induced by sotalol, when telithromycin and sotalol were co-administered. The secondary objective was to correlate the QT interval changes induced by the study drugs to plasma concentrations during the elimination phase. METHODS: Twenty-four women received sotalol (160 mg) together with placebo or telithromycin (800 mg) in a two-period, double-blind, randomized study. Electrocardiograms were recorded at rest. Comparison of maximal corrected QT interval (QTc(max)) with sotalol in the presence or absence of telithromycin was performed. The relation between sotalol concentration and QTc was studied using linear regression. RESULTS: Mean difference (95% CI) between QTc(max) with sotalol-placebo and QTc(max) with sotalol-telithromycin was -15.5 ms (-27.7 to -3.2 ms). QTc(max) interval prolongation was lower (P < 0.05) with sotalol-telithromycin than with sotalol-placebo, in relation to decreased sotalol plasma concentrations. Regression analysis showed that the relationship between sotalol plasma concentration and QTc interval duration was not modified by telithromycin co-administration. CONCLUSION: Our results do not support a potential synergistic effect on QT interval prolongation between sotalol and telithromycin. The decrease of mean QTc interval in subjects taking telithromycin and sotalol may be explained by a decrease of sotalol concentration.     

Drug- and non-drug-associated QT interval prolongation

Sudden cardiac death is among the most common causes of cardiovascular death in developed countries. The majority of sudden cardiac deaths are caused by acute ventricular arrhythmia following repolarization disturbances. An important risk factor for repolarization disturbances is use of QT prolonging drugs, probably partly explained by gene–drug interactions. In this review, we will summarize QT interval physiology, known risk factors for QT prolongation, including drugs and the contribution of pharmacogenetics. The long QT syndrome can be congenital or acquired. The congenital long QT syndrome is caused by mutations in ion channel subunits or regulatory protein coding genes and is a rare monogenic disorder with a mendelian pattern of inheritance. Apart from that, several common genetic variants that are associated with QT interval duration have been identified. Acquired QT prolongation is more prevalent than the congenital form. Several risk factors have been identified with use of QT prolonging drugs as the most frequent cause. Most drugs that prolong the QT interval act by blocking hERG-encoded potassium channels, although some drugs mainly modify sodium channels. Both pharmacodynamic as well as pharmacokinetic mechanisms may be responsible for QT prolongation. Pharmacokinetic interactions often involve drugs that are metabolized by cytochrome P450 enzymes. Pharmacodynamic gene–drug interactions are due to genetic variants that potentiate the QT prolonging effect of drugs. QT prolongation, often due to use of QT prolonging drugs, is a major public health issue. Recently, common genetic variants associated with QT prolongation have been identified. Few pharmacogenetic studies have been performed to establish the genetic background of acquired QT prolongation but additional studies in this newly developing field are warranted.     

Erythromycin prolongs the QTc interval among patients with pneumonia

Erythromycin is commonly used to treat simple community-acquired pneumonia. We measured the prolongation in QT(c) intervals in EKGs associated with intravenous erythromycin administration among patients hospitalized for simple pneumonia (DRGs 89 and 90). We reviewed the medical records of 50 patients who received at least 5 days of intravenous erythromycin, and found 15 with readable paired EKGs, at least one taken during the period of erythromycin administration and at least one other obtained when the patient had no erythromycin. The mean QT(c) interval in lead II for EKGs taken without erythromycin was 0.422 s and the average prolongation of the QT(c) interval associated with erythromycin administration was 0.046 s (P<0.01). The administration of erythromycin was thus associated with an increase in QT(c) intervals to a mean of 0.468 s, a value considered to be abnormally prolonged. We conclude that erythromycin prolongs the QT(c) interval among patients hospitalized with pneumonia in the same manner previously reported for healthy volunteers in an experimental setting. The magnitude of this erythromycin-induced QT(c) prolongation raises QT(c) intervals into the abnormal range. Although no patient in this small study suffered an adverse effect from the QT(c) prolongation, the magnitude of this effect is sufficiently large to raise clinical concerns.     

QT PRODACT: in vivo QT assay in anesthetized dog for detecting the potential for QT interval prolongation by human pharmaceuticals

The purpose of this study was to assess the utility of the isoflurane-anesthetized dog model for detecting the potential for QT interval prolongation by human pharmaceuticals. The effects of 10 positive compounds with torsadogenic potential, 8 negative compounds with little torsadogenic potential, and dl-sotalol as a common positive compound were evaluated in 5 facilities in accordance with the common protocol approved by QT PRODACT. Each test compound was cumulatively infused into male beagle dogs anesthetized with isoflurane. Surface lead II ECG, blood pressure, and plasma concentrations for the positive compounds were measured. Repeated administration of the vehicle examined in each facility before the start of the experiments resulted in a slight, but not significant, change in corrected QT (QTc) interval, indicating that this model only shows slight experimental variation. Although an inter-facility variability in the extent of dl-sotalol-induced QT interval prolongation was observed, dl-sotalol significantly prolonged QTc interval in all facilities. All positive compounds significantly prolonged QTc interval at plasma levels up to 10 times those in patients who developed prolonged QTc interval or TdP, whereas no negative compounds did so. These data suggest that the in vivo QT assay using the anesthetized dog is a useful model for detecting the potential for QT interval prolongation by human pharmaceuticals.     

全面QT研究的临床试验设计

药物导致的心电图QT/QTc间期延长,虽然发生率不高,但潜在危险性大,严重的可诱发室性心律失常甚至猝死。2005年5月,人用药品注册技术要求国际协调会正式颁布了《非抗心律失常药物潜在导致QT/QTc间期延长和心律失常的临床评价指南》(E14)。本文根据该指南及从大量已完成的研究中总结的经验讨论全面QT研究的临床试验设计要点,以期对今后中国的相关研究提供有益的指导。     

The impact of drug-induced QT interval prolongation on drug discovery and development

During the past decade, a number of non-cardiovascular drugs have had their label revised or have been withdrawn from the market because of unexpected post-marketing reports of sudden cardiac death associated with a prolongation of the QT interval, and an increased propensity to develop a ventricular tachyarrhythmia called Torsades de Pointes. Although a direct link between QT interval prolongation and arrhythmogenesis is still unclear, QT prolongation is now the subject of increased regulatory review and is considered a significant risk factor for predicting human safety of New Chemical Entities. Consequently, pharmaceutical companies are striving to improve the drug discovery and development process to identify, as early as possible, the risk of novel agents, or their metabolites, of causing QT interval prolongation and to make appropriate go/no-go decisions or modify their development programme accordingly.     

Statistical Analysis Methods For QT/QTc Prolongation

Prolonged QT interval is associated with life-threatening arrhythmias. Regulatory authorities have paid special attention to investigating the drug-induced delay of cardiac repolarization. Studies aimed at evaluating QT prolongation have become a routine part of safety packages across the pharmaceutical industry. However, the assessment of QT interval prolongation on the surface electrocardiogram is complicated by the fact that many factors influence the duration of the QT interval, among which heart rate plays a predominant role. Some widely used corrections of the QT interval for varying heart rate are known to be inadequate. Many alternatives have been proposed in the literature. Using information obtained from Eli Lilly thorough QT studies, we examine the performance of several approaches to the analysis of QT changes, including subject-specific (individual) QT corrections and model-based QT analysis methods. The simulation results indicate that the mixed-effects modeling approach proposed in this paper is more powerful than the other methods, all of which are commonly used in QT studies.