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.     

Cardiac ion channel safety profiling on the IonWorks Quattro automated patch clamp system

The normal electrophysiologic behavior of the heart is determined by the integrated activity of specific cardiac ionic currents. Mutations in genes encoding the molecular components of individual cardiac ion currents have been shown to result in multiple cardiac arrhythmia syndromes. Presently, 12 genes associated with inherited long QT syndrome (LQTS) have been identified, and the most common mutations are in the hKCNQ1 (LQT1, Jervell and Lange-Nielson syndrome), hKCNH2 (LQT2), and hSCN5A (LQT3, Brugada syndrome) genes. Several drugs have been withdrawn from the market or received black box labeling due to clinical cases of QT interval prolongation, ventricular arrhythmias, and sudden death. Other drugs have been denied regulatory approval owing to their potential for QT interval prolongation. Further, off-target activity of drugs on cardiac ion channels has been shown to be associated with increased mortality in patients with underlying cardiovascular diseases. Since clinical arrhythmia risk is a major cause for compound termination, preclinical profiling for off-target cardiac ion channel interactions early in the drug discovery process has become common practice in the pharmaceutical industry. In the present study, we report assay development for three cardiac ion channels (hKCNQ1/minK, hCa(v)1.2, and hNa(v)1.5) on the IonWorks Quattro? system. We demonstrate that these assays can be used as reliable pharmacological profiling tools for cardiac ion channel inhibition to assess compounds for cardiac liability during drug discovery.     

A common antitussive drug, clobutinol, precipitates the long QT syndrome 2

QT prolongation, a classic risk factor for arrhythmias, can result from a mutation in one of the genes governing cardiac repolarization and also can result from the intake of a medication acting as blocker of the cardiac K(+) channel human ether-a-go-go-related gene (HERG). Here, we identified the arrhythmogenic potential of a nonopioid antitussive drug, clobutinol. The deleterious effects of clobutinol were suspected when a young boy, with a diagnosis of congenital long QT syndrome, experienced arrhythmias while being treated with this drug. Using the patch-clamp technique, we showed that clobutinol dose-dependently inhibited the HERG K(+) current with a half-maximum block concentration of 2.9 microM. In the proband, we identified a novel A561P HERG mutation. Two others long QT mutations (A561V and A561T) had been reported previously at the same position. None of the three mutants led to a sizeable current in heterologous expression system. When coexpressed with wild-type (WT) HERG channels, the three Ala561 mutants reduced the trafficking of WT and mutant heteromeric channels, resulting in decreased K(+) current amplitude (dominant-negative effects). In addition, A561P but not A561V and A561T mutants induced a approximately -11 mV shift of the current activation curve and accelerated deactivation, thereby partially counteracting the dominant-negative effects. A561P mutation and clobutinol effects on the human ventricular action potential characteristics were simulated using the Priebe-Beuckelmann model. Our work shows that clobutinol has limited effects on WT action potential but should be classified as a "drug to be avoided by congenital long QT patients" rather than as a "drug with risk of torsades de pointes".     

Pharmacogenomics and acquired long QT syndrome

During the past decade pharmaceutical companies have been faced with the withdrawal of some of their marketed drugs because of rare, yet lethal, postmarketing reports associated with ventricular arrhythmias. The implicated drugs include antiarrhythmics, but also non-cardiac drugs, such as histamine blockers, antipsychotics, and antibiotics. These undesired effects involve prolongation of the QT interval, which may lead to characteristic ventricular tachyarrhythmias, known as torsades de pointes. These clinical symptoms of the acquired long QT syndrome (LQTS) are also found in an inherited form of the disease, called congenital LQTS. Nowadays, a number of environmental (non-genetic) and genetic risk factors for acquired LQTS have been described. Non-genetic factors include female gender, hypokalemia, and other heart diseases. The knowledge of genetic risk factors is emerging rapidly. During the last decade, mutations in several genes encoding ion channels have been shown to cause congenital LQTS. In acquired LQTS, a number of 'silent' mutation carriers in these LQTS genes have been identified, and functional polymorphisms in the same genes have been found that are associated with an increased vulnerability for the disease. Furthermore, there is also evidence that interindividual differences in drug metabolism, caused by functional polymorphisms in drug-metabolizing enzyme genes, may be a risk factor for acquired LQTS, especially if multiple drugs are involved. This review evaluates the current knowledge on these risk factors for acquired LQTS, with an emphasis on the genetic risk factors. It also assesses the potential to develop pharmacogenetic tests that will enable clinicians and pharmaceutical companies to identify at an early stage patients or individuals in the general population who are at risk of acquired LQTS.     

QT-interval prolongation by non-cardiac drugs: lessons to be learned from recent experience

Background: Evidence has accrued that several non-cardiac drugs may prolong cardiac repolarisation (hence, the QT interval of the surface electrocardiogram) to such a degree that potentially life-threatening ventricular arrhythmias (e.g. torsades de pointes) may occur, especially in case of overdosage or pharmacokinetic interactions. Discussion: This has fostered discussion on the molecular mechanisms underlying the class-III anti-arrhythmic effect shared by apparently disparate classes of drugs, on the clinical relevance of this side effect and on possible guidelines to be followed by drug companies, ethics committees and regulatory agencies in the risk–benefit assessment of new and licensed drugs. This review provides an update on the different classes of non-cardiac drugs reported to prolong the QT interval (e.g. histamine H₁-receptor antagonists, antipsychotics, antidepressants and macrolides), on the possible underlying molecular mechanisms and on the clinical relevance of the QT prolonging effect. Identification and widespread knowledge of risk factors that may precipitate prolongation of the QT interval into life-threatening arrhythmias becomes an important issue. Risk factors include congenital long QT syndrome, clinically significant bradycardia or heart disease, electrolyte imbalance (especially hypokalaemia, hypomagnesaemia), impaired hepatic/renal function and concomitant treatment with other drugs with known potential for pharmacokinetic/pharmacodynamic interactions (e.g. azole antifungals, macrolide antibacterials and class-I or -III anti-arrhythmic agents). Future perspectives for drug research and development are also briefly outlined. Received: 4 October 1999 / Accepted in revised form: 13 January 2000     

非抗心律失常药的致心律失常作用及相关危险因子

获得性QT间期延长综合征 (LQTS)可由抗心律失常药以外的药物引起 ,包括促胃肠动力药、止吐药、抗心律失常药以外的心血管药物、抗菌药、静脉麻醉药、抗精神病药、抗抑郁药、抗组胺药等 ,它们可阻断心脏的电压门控性通道特别是延迟整流钾电流的快速激活成分 (IKr)、延长动作电位时程(APD)及QT间期、诱发尖端扭转型室性心动过速(TdP)等快速型室性心律失常。一些常见的危险因子如女性 ,电解质紊乱 (特别是低钾、低镁 ) ,临床显著的心动过缓或心脏疾病 ,遗传性LQTS ,肝、肾功能障碍 ,与其他药物合用所致的药动学与药效学的相互作用等通过减少复极储备 ,大大增加诱发TdP的可能性     

病变心脏中的易损基质及多离子通道损害为抗心律失常药的新靶点

心血管疾病主要死因是致命性心律失常,对它的治疗仍是一个问题。当前I类及Ⅲ类药均不推荐用于控制室性心律失常,由于药效差及增加死亡率,对病变心脏有毒性、梗死心脏中非梗死区（NIZ）中形成易损基质（VS）,如去甲肾上腺素耗竭,SOD活性降低,心肌肥大,APD延长及QT离散度增加等。慢性给左甲状腺素可形成心肌肥大及加重缺血／再灌注性心律失常,此模型有VS的特点。离子通道的病变类型在先天性LQTS与后天性心脏病中有明显的不同。先天性LQTS是单一离子通道的改变。我们发现在HERG中一个新突变－提前终止密码,使QT延长。而后天性心脏病的心肌肥大是多离子通道病变而非性。后天性心脏病中离子通道病变是继发于VS病变对脂质膜的影响。VS及多离子通道的病变可作为药物治疗病变心脏心律失常的新靶点。     

Mutation-specific pharmacology of the long QT syndrome

The congenital long QT syndrome is a rare disease in which inherited mutations of genes coding for ion channel subunits, or channel interacting proteins, delay repolarization of the human ventricle and predispose mutation carriers to the risk of serious or fatal arrhythmias. Though a rare disorder, the long QT syndrome has provided invaluable insight from studies that have bridged clinical and pre-clinical (basic science) medicine. In this brief review, we summarize some of the key clinical and genetic characteristics of this disease and highlight novel findings about ion channel structure, function, and the causal relationship between channel dysfunction and human disease, that have come from investigations of this disorder.     

抗心律失常药物作用的靶点——HERG K+通道

快速延迟整流钾电流(rapidly activating component of delayed rectifier potassium current，I_Kr)在心肌动作电位复极化过程中发挥重要作用。HERG基因编码心脏快速延迟整流钾通道的α亚基，HERG基因突变导致遗传性长QT间期综合征(long QT syndrome，LQTS)，另外I_Kr/HERG通道是绝大多数能引起心脏QT间期延长药物的作用靶标，其他一些化学结构不同的药物也可阻断该通道，引起QT间期延长，甚至发展成获得性心律失常。本文从门控机制及功能、HERG通道相关的心律失常、药物与通道相互作用机制、优化通道靶点的策略等四个方面综述I_Kr/HERG通道在抗心律失常方面的最新研究进展。     

Drug induced QT prolongation: lessons from congenital and acquired long QT syndromes

Recent developments regarding the underlying genetic and intracardiac ion channel causes of congenital long QT syndrome have shed new light in the area of repolarization disorders and their resultant cardiac arrhythmias. Drug induced or acquired QT prolongation often represents a latent form of congenital long QT syndrome, though the genetic basis of this has not been elucidated in the majority of cases. Understanding this has lead to a new concept of repolarization reserve, a measure of inherent susceptibility to repolarization-mediated arrhythmias. The majority of pharmacologic agents that cause significant QT prolongation have potassium channel blocking characteristics, predominantly affecting the rapidly activating current I(Kr). The list of agents known to affect I(Kr)continues to grow, best monitored through several websites that collate reports of drug-induced QT prolongation and arrhythmias. Discontinuation of the offending agent and supportive care are often all that is necessary when clinical arrhythmias arise.     

An update on risk factors for drug-induced arrhythmias

A variety of drugs, either anti-arrhythmics or non-antiarrhythmics, have been associated with drug-induced arrhythmias. Drug-induced arrhythmias are usually observed in the presence of long QT interval or Brugada electrocardiographic pattern. Clinical risk factors, such as female gender, structural heart disease, metabolic and electrolyte abnormalities, bradycardia and conduction disease, increased drug bioavailability, and silent channelopathies act as ‘‘effect amplifiers’’ which can make an otherwise relatively safe drug dangerous with regard to risk for polymorphic ventricular tachycardia in the setting of QT interval prolongation. A drug-induced type 1 electrocardiographic pattern of Brugada syndrome is considered highly proarrhythmic. Specific electrocardiographic markers including the corrected QT interval, QRS duration, T_peak–T_end/QT ratio, and others may predict the risk of arrhythmias in both situations. The present review highlights on the current clinical and electrocardiographic risk factors for prediction of drug-induced arrhythmias.     

Genetic background predisposing the drug-induced long QT syndrome

Molecular and cellular mechanisms underlying the QT prolongation have been elucidated largely because of the recent understanding of the generation of the congenital forms of QT prolongation; i.e., the long QT syndrome. To date, at least 7 different genes that modulate cardiac ion channels were identitied to be associated with the syndrome. In the clinical setting, the drug-induced long QT syndrome is more frequently seen and therefore important. We found several mutations as well as an SNP specific among the Japanese population in probands referred to as the secondary long QT patients, including the drug-induced cases. These findings raised the potential that there are also predisposing risk factors at patient's side.     

Congenital long QT syndromes and Brugada syndrome: the arrhythmogenic ion channel disorders

Congenital long QT syndromes (LQTS) and Brugada syndrome are hereditary disorders of cardiac ion channels which result in life-threatening cardiac arrhythmias or sudden cardiac death in patients with anatomically normal hearts. The pathogenesis of these dramatic events has been partially elucidated with the identification of the individual ion channels involved and understanding of the effect of some disease-causing mutations on the membrane currents and action potential. The clinical spectrum of congenital LQTS is broader than previously thought and involves certain patients previously diagnosed with idiosyncratic drug-induced proarrhythmia. The initial treatment for congenital LQTS patients involves beta-blockers in most cases. Indications for implantable cardioverter-defibrillator (ICD) or pace-maker (PM) implantation in selected individuals continue to evolve.     

Sudden cardiac death secondary to antidepressant and antipsychotic drugs

A number of antipsychotic and antidepressant drugs are known to increase the risk of ventricular arrhythmias and sudden cardiac death. Based largely on a concern over QT prolongation and the development of life-threatening arrhythmias, a number of antipsychotic drugs have been temporarily or permanently withdrawn from the market or their use restricted. Some antidepressants and antipsychotics have been linked to QT prolongation and the development of Torsade de pointes arrhythmias, whereas others have been associated with a Brugada syndrome phenotype and the development of polymorphic ventricular arrhythmias. This review examines the mechanisms and predisposing factors underlying the development of cardiac arrhythmias, and sudden cardiac death, associated with antidepressant and antipsychotic drugs in clinical use.     

Understanding drug-induced torsades de pointes: a genetic stance

Drugs may produce a variety of arrhythmias, but drug-induced QT prolongation and the risk of the polymorphic ventricular tachycardia torsades de pointes (drug-induced long QT syndrome) has garnered the most attention. The wide array of drugs with potential for QT prolongation, the correspondingly large number of patients exposed to such drugs, the difficulty in predicting an individual's risk, and the potentially fatal outcome, make drug-induced long QT syndrome an important public health problem for clinicians, researchers, drug development programs, and regulatory agencies. This review focuses on the genetic risk factors and mechanisms underlying QT prolongation and proarrhythmia. The post-genomic era hints at an improved understanding (and prediction) of how the gene-environment interaction produces this particular adverse drug response.     

抗新型冠状病毒药物致QT间期延长的文献复习及药学监护

本文对新型冠状病毒肺炎患者临床用药方案涉及的抗病毒药物致QT间期延长的文献报道情况进行复习。根据目前文献复习结果可知,洛匹那韦/利托那韦和磷酸氯喹存在引起QT间期延长进而引发尖端扭转型室速的潜在风险。在新型冠状病毒肺炎患者中使用此类药物需关注由此带来的用药风险,熟悉临床上常用的可引起QT间期延长的药物,提高识别患者QT间期延长的易感因素和药物相互作用的能力,重视心电图、电解质管理来预防临床潜在的药物致急性心律失常事件,以降低新型冠状病毒肺炎患者的药物不良反应,避免药源性损害。     

Inherited cardiac arrhythmia syndromes: What have they taught us about arrhythmias and anti‐arrhythmic therapy?

1. In recent years, the identification of the gene defects in a vast array of monogenic disorders has revolutionized our understanding of the basic mechanisms underlying numerous disease processes. 2. Mutations in cardiac ion channels have been identified as the basis of a wide range of inherited arrhythmia syndromes, including the congenital long QT syndromes, Brugada syndrome, Lenegre syndrome, Andersen's disease and familial atrial fibrillation. 3. Identification of mutations in the human-ether-a-go-go-related gene (HERG) K(+) channel as the molecular basis of congenital long QT syndrome type 2 also led to the discovery that HERG is the molecular target for the vast majority of drugs (both cardiac and non-cardiac) that cause drug-induced arrhythmias. This has had profound implications not only for the development of anti-arrhythmic agents, but also for drug development in general. 4. The sequencing of the human genome in a sense represents the pinnacle of the reductionist era of molecular medicine. The great challenge now is to re-integrate the information gathered during the 'reductionist era' to provide a better understanding of the intact organism. Computer modelling is likely to be a key component of that re-integration process.     

QT interval prolongation and cardiac risk assessment for novel drugs

Fatal cardiac arrhythmias, known as torsades de pointes, can occur with a wide variety of medicinal drugs and are associated with prolongation of the QT interval. This review critically evaluates the major strategies for assessing QT prolongation risk: ion channel studies, in vitro cardiac electrophysiology, and in vivo cardiac electrophysiology and hemodynamics. Disease- or drug-induced QT prolongation is mainly associated with reduced amplitude of the repolarizing outward K+ current in myocardial cells, particularly those carried by the human ether-a-go-go-related gene (HERG) channel. Thus, measuring HERG currents using patch-clamp technology and cloned HERG channels represents a first approach for evaluating adverse effects of drugs on ion channel function, under physiological conditions. Evaluation of changes in transmembrane action potential in isolated rabbit or dog Purkinje fibers reflects mixed ion channel blocking properties of the test substance and therefore permits a greater understanding of the mechanisms underlying the genesis of arrhythmias. Both HERG channel and Purkinje fiber procedures are clinically predictive, however, no in vitro technique can fully reproduce the in vivo situation. Therefore, both in vitro and in vivo approaches should be employed to maximize the chances of an accurate assessment of risk in an area where prolonged QT can result in death.