Torsade de pointes in a patient with complex medical and psychiatric conditions receiving low-dose quetiapine

OBJECTIVE: Describe potential cardiac complications of low-dose quetiapine and other atypical antipsychotic drugs. METHOD: We present a case report of a 45-year-old Black woman with multiple medical and psychiatric problems taking low-dose quetiapine. RESULTS: Coincident with a generalized seizure, the patient developed 'ventricular fibrillation'. She was countershocked with restoration of normal sinus rhythm. The initial electrocardiogram showed QT interval prolongation. Shortly thereafter, classical torsade de pointes appeared, lasted 10 min, and resolved spontaneously. Hypomagnesemia was present. A cardiac electrophysiologist was concerned that the very slow shortening of the prolonged QTc interval after magnesium replacement implicated quetiapine as a risk factor for QTc interval prolongation and torsade de pointes. A psychosomatic medicine consultant asserted that the fragmented medical and psychiatric care almost certainly contributed to the patient's medical problems. We discuss other cases of QT interval prolongation by newer antipsychotic drugs and previous reports by our group concerning the association of psychotropic drugs, QT interval prolongation, and torsade de pointes. CONCLUSION: Atypical antipsychotic drug administration, when accompanied by risk factors, may contribute to cardiac arrhythmias including torsade de pointes.     

Antipsychotic drugs and QT interval prolongation

The QTc prolongation by antipsychotic drugs is of major concern, especially in light of the data indicating an increased risk of sudden death in psychiatric patients taking these drugs. Sudden death in psychiatric patients could be partially attributed to drug-induced torsades de pointes and for this reason careful evaluation of QTc prolonging properties of antipsychotic drugs is needed. Antipsychotic drugs prolong QT interval usually by blocking the potassium I_Kr current. Improved understanding of ion channel structure and kinetics and its role in repolarization has tremendous impact on understanding of the mechanisms of drug-induced QT prolongation and torsades de pointes. Proarrhythmia caused by a QT-prolonging drug occurs infrequently, and usually multiple factors need to operate to precipitate such an event including a combination of two or more drugs affecting the same pathway, hypokalemia, and possibly genetic predisposition. Currently prescribed antipsychotics might cause QT prolongation ranging from 4–6 ms for haloperidol and olanzapine to 35 ms for thioridazine. The response of a patient to a drug is very individual and therefore an individualized system of drug administration and monitoring needs to be developed which takes into account baseline QTc duration and its changes after a drug was introduced. A systematic approach while stratifying psychiatric patients as those with short QTc (QTc 0.41 sec), borderline QTc (QTC = 0.42–0.44 sec), and prolonged QTc ( 0.45 sec) is being proposed to improve the safety of administering antipsychotic drugs and to decrease the risk of drug-related sudden death in psychiatric patients.     

Antipsychotic drugs: prolonged QTc interval, torsade de pointes, and sudden death.

OBJECTIVE: The authors review the mechanisms and establish the risk of torsade de pointes and sudden death with antipsychotic drugs. METHOD: They present a review of original concepts, the distinction between familial and drug-induced cases of torsade de pointes, and the recognition of the role of noncardiac drugs in torsade de pointes and sudden death. They review the evidence linking QTc interval prolongation, potassium channels, and torsade de pointes from both the long QT syndrome and drugs. They examine the risk for torsade de pointes from antipsychotic drugs and estimate the frequency of sudden death on the basis of epidemiological data in normal and schizophrenic populations. RESULTS: All drugs that cause torsade de pointes prolong the QTc interval and bind to the potassium rectifier channel, but the relationships are not precise. Prediction of torsade de pointes and sudden death can be improved by examining dose dependency, the percent of QTc intervals higher than 500 msec, and the risk of drug-drug interactions. Although sudden unexpected death occurs almost twice as often in populations treated with antipsychotics as in normal populations, there are still only 10-15 such events in 10,000 person-years of observation. CONCLUSIONS: Although pimozide, sertindole, droperidol, and haloperidol have been documented to cause torsade de pointes and sudden death, the most marked risk is with thioridazine. There is no association with olanzapine, quetiapine, or risperidone. Ziprasidone does prolong the QT interval, but there is no evidence to suggest that this leads to torsade de pointes or sudden death. Only widespread use will prove if ziprasidone is entirely safe. To date, all antipsychotic drugs have the potential for serious adverse events. Balancing these risks with the positive effects of treatment poses a challenge for psychiatry.     

Cardiac safety parameters of olanzapine: comparison with other atypical and typical antipsychotics

Alterations of electrocardiogram results and cases of sudden cardiac death have been reported since the beginning of neuroleptic treatment. In particular, a temporal association exists between some antipsychotics and prolongation of the heart rate-corrected QT interval (QTc), an event that may increase the risk for developing a potentially fatal ventricular tachycardia arrhythmia known as torsades de pointes if it significantly exceeds normal intraindividual and interindividual variation. Although the incidence of serious adverse cardiac events in response to antipsychotic medications is relatively low, any possibility for the occurrence of cardiotoxicity warrants continued study. The present article reviews important differences among antipsychotic drugs in the potential for, and occurrence of, serious adverse cardiac outcomes and suggests that olanzapine, as therapeutically administered to patients with schizophrenia and related psychoses, does not contribute significantly to a QTc prolongation that could result in potentially fatal ventricular arrhythmias.     

Antipsychotics and QT prolongation

OBJECTIVE: To evaluate literature relating to cardiac QT prolongation and the use of antipsychotic drugs. METHOD: Literature searches of EMBASE, Medline, PsychLIT were performed in December 2001 and reference sections of retrieved papers scrutinized for further relevant reports. RESULTS: The Cardiac QTc interval is difficult to measure precisely or accurately but appears to be a useful predictor of risk of dysrhythmia (specifically torsade de pointes) and sudden death. It is less clear that drug-induced QTc prolongation gives rise to similar risks but data are emerging, linking antipsychotic use to increased cardiac mortality. Many antipsychotics have been clearly associated with QTc prolongation. Methodological considerations arguably preclude assuming that any antipsychotic is free of the risk of QTc prolongation and dysrhythmia. CONCLUSION: Available data do not allow assessment of relative or absolute risk of dysrhythmia or sudden death engendered by antipsychotics but caution is advised. Risk of dysrhythmia can very probably be reduced by careful prescribing of antipsychotics in low doses in simple drug regimens which avoid metabolic interactions. Electrocardiographic monitoring may also help to reduce risk but review by specialist cardiologist may be necessary.     

A retrospective study of the safety of intramuscular ziprasidone in agitated elderly patients

OBJECTIVE: Authors evaluated the safety of intramuscular ziprasidone for use in acute agitation in an elderly population. METHOD: Medical records were reviewed retrospectively to identify consecutive patients who were admitted to our neuropsychiatry service with the presenting complaint of dementia (DSM-IV) with agitation and who were given intramuscular ziprasidone and then administered an electrocardiogram (ECG) (N = 23). Some patients also had a baseline ECG (N = 14). QTc intervals were recorded, and significance was defined as a QTc of > or =450 ms or a 10% prolongation from baseline. A paired-samples t test was performed to compare the baseline and postmedication QTc intervals. Confounding factors were examined, and cardiac events (torsades de pointes, cardiac arrest) were recorded. RESULTS: There was no significant difference in the QTc interval between the baseline and the post-ziprasidone values. One patient had a QTc greater than 500 ms and 25% over baseline, and therefore the medication was discontinued. The mean prolongation of the QTc interval was only 0.5 ms. There were no episodes of torsades de pointes. Other medications that the patients were taking did not appear to affect the QTc interval in an expected manner. CONCLUSION: Larger studies need to be done to evaluate the safety of intramuscular ziprasidone in agitated elderly patients, a population with an increased risk of QT prolongation and torsades de pointes because of their age, comorbid conditions, and concomitant use of multiple medications.     

Antipsychotic drugs and cardiovascular safety: current studies of prolonged QT interval and risk of ventricular arrhythmia

Cardiovascular mortality is higher among schizophrenic patients than in the general population, and it is possible that most unexplained sudden deaths among these patients are due to ventricular arrhythmias for which antipsychotic drugs are either the cause or a predisposing factor. Most antipsychotic agents show electrophysiological effects resembling those of class 1a antiarrhythmic agents, and may be responsible for prolonging the QT interval, potentially going on to cause torsades de pointes. Some of the antipsychotic agents carry a high risk of arrhythmias, related to their effects on the QT interval. These include thioridazine, pimozide, sultopride, droperidol, and to a lesser extent haloperidol and chlorpromazine. In the case of the new atypical antipsychotic agents, it is possible to rank the risks of different drugs, with sertindole (now withdrawn from sale) having the highest risk, and ziprasidone somewhat lower, followed by risperidone and finally by quetiapine, clozapine and olanzapine which have negligible effects on the QT interval. A number of risk factors have been demonstrated, particularly: hypokalaemia and hypomagnesaemia, bradycardia, congenital long QT syndrome, and any underlying cardiac pathology. Lastly, the risk associated with any given antipsychotic agent is increased if it is combined either with any other drug known to prolong the QT interval and provoke torsades de pointes, or with any drug capable of inhibiting the hepatic metabolism of the antipsychotic agent. A list of such drugs is provided, together with advice on the action to be taken when prescribing an antipsychotic agent to a patient with a long QT interval.     

QTc prolongation by antiepileptic drugs and the risk of torsade de pointes in patients with epilepsy

Sudden unexpected death in epilepsy (SUDEP) is the most common epilepsy-related cause of death. While the precise pathophysiological mechanisms underlying SUDEP are still uncertain, impaired cardiac function including seizure-induced arrhythmias has received increased attention. In addition, the potential role of antiepileptic drugs has been suggested. While the preponderance of clinical data would suggest that use of most antiepileptic drugs does not pose excessive additional risk of QT prolongation, available data also do not provide sufficient evidence that these drugs are entirely free of risk in all patients. In particular, the potential for these medications, either alone or in combination, to prolong the QT interval should be considered. This review will discuss mechanisms for drug-induced QT prolongation and its relationship to potentially fatal arrhythmias such as torsades de pointes.This article is part of a Special Issue entitled “Translational Epilepsy Research”.     

Whole genome association study identifies polymorphisms associated with QT prolongation during iloperidone treatment of schizophrenia

Administration of certain drugs (for example, antiarrhythmics, antihistamines, antibiotics, antipsychotics) may occasionally affect myocardial repolarization and cause prolongation of the QT interval. We performed a whole genome association study of drug-induced QT prolongation after 14 days of treatment in a phase 3 clinical trial evaluating the efficacy, safety and tolerability of a novel atypical antipsychotic, iloperidone, in patients with schizophrenia. We identified DNA polymorphisms associated with QT prolongation in six loci, including the CERKL and SLCO3A1 genes. Each single nucleotide polymorphism (SNP) defined two genotype groups associated with a low mean QT change (ranging from -0.69 to 5.67 ms depending on the SNP) or a higher mean QT prolongation (ranging from 14.16 to 17.81 ms). The CERKL protein is thought to be part of the ceramide pathway, which regulates currents conducted by various potassium channels, including the hERG channel. It is well established that inhibition of the hERG channel can prolong the QT interval. SLCO3A1 is thought to play a role in the translocation of prostaglandins, which have known cardioprotective properties, including the prevention of torsades de pointes. Our findings also point to genes involved in myocardial infarction (PALLD), cardiac structure and function (BRUNOL4) and cardiac development (NRG3). Results of this pharmacogenomic study provide new insight into the clinical response to iloperidone, developed with the goal of directing therapy to those patients with the optimal benefit/risk ratio.     

抗精神病药致首发精神疾病QTc 间期变化的相关 因素分析

目的 调查抗精神病药致首发精神疾病QTc间期延长的影响因素.方法 对服用稳定剂量抗精神病药治疗1月的309例首发精神疾病患者进行回顾性调查,收集人口学资料、空腹血糖、血压、血脂等生化指标、心电图资料,以QTc≥440ms作为QTc间期延长的标准,分析QTc间期延长的状况及其相关因素.结果 QTc间期延长的发生率为10.6%.药物治疗组QTc间期均值大于基线期,差异有统计学意义(P<0.05);药物联合电休克治疗组以及药物联合脑电治疗组QTc间期与基线期相比,差异无统计学意义(P>0.05).单一抗精神病药治疗组QTc间期与基线期差异无统计学意义(P>0.05);而抗精神病药联用以及抗精神病药联用抗抑郁药/心境稳定剂组QTc间期均值大于基线期,差异有统计学意义(P<0.05).抗精神病药等效氯丙嗪剂量<1000mg/d组别QTc间期与基线期相比差异有统计学意义(P<0.05).抗精神病药剂量与QTc间期没有相关性.女性是QTc间期延长的风险因素(OR=3.26,95%CI=1.050~10.094),其他因素未进入回归方程.结论 首发精神疾病患者抗精神病药治疗期间QTc间期延长存在性别差异,女性发生QTc间期延长的风险是男性的3.26倍.药物联用延长的QTc间期并未达到异常值.抗精神病药剂量与QTc间期没有相关性.除了性别因素外,其他指标不是QTc间期延长的风险因素.     

QTc-interval abnormalities in a forensic population

Background Antipsychotic drugs have been linked to sudden death among psychiatric patients, with a suggestion that prolongation of the QT‐interval detectable on a standard electrocardiogram may be linked to fatal cardiac arrhythmias in these circumstances. Patients in secure forensic psychiatric facilities may be particularly likely to be on high‐dose antipsychotic medication, and yet, as far as the authors are aware, no study of QT‐intervals among such patients has been reported. Aim To investigate the prevalence of QT‐interval abnormalities and associated known risk factors for fatal cardiac arrhythmias in a sample of forensic patients. Method Participants had a 12‐lead electrocardiogram taken at 50 mm/s. Information was collected on their age, gender, psychiatric diagnosis, history of cardiovascular, liver and kidney diseases, and smoking, on all medications and on history of seclusion over the previous 12 months. Analysis was carried out using binary logistic regression. Results Lower rates of QT‐interval abnormalities than might be expected for this population were found. It was also found that a high dose of antipsychotics was associated with QTc prolongation (Adjusted OR = 9.5, 95% CI 2.6–34.2), a result consistent with previous literature. Conclusion Forensic patients need not be at increased risk of QTc abnormality provided risk factors are properly managed. A high dose of antipsychotic medication increases the risk of QTc prolongation. Copyright © 2007 John Wiley & Sons, Ltd.     

Low-dose escitalopram for 2 days associated with corrected QT interval prolongation in a middle-aged woman: a case report and literature review

Prolongation of the corrected QT interval (QTc) on the electrocardiography is an important clinical condition because it increases the risk of torsade de pointes, a medical emergency that can cause sudden cardiac death. QTc prolongation can be induced by many drugs, including antipsychotics and tricyclic antidepressants (TCAs). Compared with TCAs, use of selective serotonin reuptake inhibitors (SSRIs) was less likely to cause severe cardiac adverse effects. Escitalopram, one of the SSRIs, has shown significant antidepressant efficacy and well tolerability. Here, we present one female patient showing QTc prolongation induced by low-dose (5 mg/day) treatment of escitalopram for 2 days. The QTc returned to normal soon after discontinuation of escitalopram. Clinicians should be cautious about cardiac effects when using a SSRI, even in a low dose.     

QT interval prolongation related to psychoactive drug treatment: a comparison of monotherapy versus polytherapy

Background  

Several antipsychotic agents are known to prolong the QT interval in a dose dependent manner. Corrected QT interval (QTc) exceeding a threshold value of 450 ms may be associated with an increased risk of life threatening arrhythmias. Antipsychotic agents are often given in combination with other psychotropic drugs, such as antidepressants, that may also contribute to QT prolongation. This observational study compares the effects observed on QT interval between antipsychotic monotherapy and psychoactive polytherapy, which included an additional antidepressant or lithium treatment.     

Electrocardiographic safety profile and monitoring guidelines in pediatric psychopharmacology

Summary. A number of medications commonly used in pediatric psychopharmacology can prolong the QTc interval of the electrocardiogram. QTc prolongation can in turn predispose to torsades de pointes, a sometimes deadly arrhythmia. These considerations are clinically relevant given documented, if still controversial, reports of sudden deaths associated with the use of the tricyclic antidepressant (TCA) desipramine in children. While most reports of QTc prolongation have involved adult patients, this adverse effect can occur in children. After discussing the QTc parameters derivation, accuracy, and limitations, this article reviews current knowledge about the propensity of the antipsychotics (both atypical and traditional), TCAs, and alpha agonists to prolong the QTc interval in young patients. Based on the literature reviewed, guidelines are provided for clinical and electrocardiographic monitoring in pediatric psychopharmacology.     

Possible association of QTc interval prolongation with co-administration of quetiapine and lovastatin.

BACKGROUND: QTc interval prolongation can occur as a result of treatment with both conventional and novel antipsychotic medications and is of clinical concern because of its association with the potentially fatal ventricular arrhythmia, torsade de pointes. METHODS: One case is described in which a patient with schizophrenia, who was being treated for dyslipidemia, developed a prolonged QTc interval while taking quetiapine and lovastatin. RESULTS: QTc returned to baseline when the lovastatin dose was reduced. CONCLUSIONS: QTc prolongation associated with antipsychotic medication occurs in a dose-dependent manner. We therefore hypothesize that the addition of lovastatin caused an increase in plasma quetiapine levels through competitive inhibition of the cytochrome P(450) (CYP) isoenzyme 3A4. Our case highlights the potential for a drug interaction between quetiapine and lovastatin leading to QTc prolongation during the management of dysipidemia in patients with schizophrenia.     

Antipsychotic Polypharmacy and Corrected QT Interval: A Systematic Review

Objective:

It remains unclear whether antipsychotic polypharmacy, a common clinical practice, is related to an increased risk of corrected time between start of Q wave and end of T wave (QTc) interval prolongation. We conducted a systematic review of the literature to address this important issue.

Method:

A systematic literature search was conducted in October 2014, using MEDLINE, Embase, and PsycINFO. Studies and case reports were included if they reported QTc intervals or QTc interval changes before and after antipsychotic polypharmacy or QTc intervals in both antipsychotic polypharmacy and monotherapy groups.

Results:

A total of 21 articles (10 clinical trials, 4 observational studies, and 7 case reports) met inclusion criteria. The clinical trials have shown that a combination treatment with risperidone or pimozide is not obviously related to an increase in QTc interval, whereas ziprasidone or sertindole combined with clozapine may prolong QTc interval. Among the 4 observational studies, antipsychotic polypharmacy was not clearly associated with QTc prolongation in 3 studies, each cross-sectional. In contrast, one prospective study showed a significant increase in QTc interval following antipsychotic coadministration. The case reports indicated an increased risk of QTc prolongation in at least some patients receiving antipsychotic polypharmacy.

Conclusions:

Currently available evidence fails to confirm that antipsychotic polypharmacy worsens QTc prolongation in general, although the evidence is scarce and inconsistent. Clinicians are advised to remain conservative in resorting to antipsychotic polypharmacy, as a combination of some QTc-prolongation liable antipsychotics may further prolong QTc interval, and efficacy supporting the clinical benefits of antipsychotic polypharmacy is equivocal, at best.     

Antipsychotic agents and QT changes

Recently, antipsychotic medications of the novel or atypical classes have received increased attention because of concerns with respect to potential lengthening of the QT interval, yet the currently available and commonly prescribed conventional antipsychotics are significantly more cardiotoxic, particularly agents in the butyrophenone and phenothiazine classes. Lengthening of the QT interval can be associated with a fatal paroxysmal ventricular arrhythmia known as torsades de pointes. The specific duration of the QT interval at which the risk of an adverse cardiac event is greatest, is not established. There is not only significant variation in the applied definition of an abnormal interval, but the maximal QT interval in healthy volunteers is greater than the currently accepted standards. The QT interval is influenced by normal physiological and pathologic factors, but the mechanisms remain unclear. Using recombinant technology, haloperidol and sertindole have been demonstrated to be high-affinity antagonists of a human cardiac potassium channel encoded by the human ether-a-go-go-related gene. Pimozide, however, has been shown to act principally through calcium channel antagonism, and chlorpromazine may affect sodium channels. Nevertheless, it is possible that these effects are significant only in the presence of predisposing factors, either genetic or acquired. Despite proven efficacy in clinical trials and subsequent supervised use in Europe, a number of recently developed antipsychotic medications are not available to patients in North America. Yet, conventional antipsychotic medications that would not be approved by current safety standards continue to be widely used.     

Impact of Age and Sex on QT Prolongation in Patients Receiving Psychotropics

Objective:

To assess older age and female sex, 2 of the major risk factors for potentially fatal cardiac arrhythmias or sudden cardiac death in patients prescribed psychotropics, within the context of electrocardiographic evidence of time between start of Q wave and end of T wave (QT) interval prolongation, which is an indicator of an increased risk for potentially fatal cardiac arrhythmias.

Method:

The literature on the relation between age, sex, and QT interval with respect to psychotropic drugs was reviewed.

Results:

The QT interval must be corrected (QTc) for heart rate. Because slower heart rates prolong and faster heart rates shorten the QT interval, people with faster heart rates may have a prolonged QT interval that is not apparent until the correction is performed. QTc values for apparently healthy post-pubertal people are less than 450 ms for males and less than 470 ms for females. The longer QT intervals in women may account for their increased risk of potentially fatal cardiac arrhythmias on psychotropics. QTc increases with increasing age. Assessment of QTc in older people is especially important to identify people with a longer QTc who are more likely to attain a serious QT level with drugs that prolong QTc. The age-related increase in QTc is more evident in men than women, suggesting that male sex does not afford protection against potentially fatal arrhythmias at older age.

Conclusion:

The association of increasing age and female sex with greater QT intervals indicates the need to have an increased awareness of the QTc prior to use of these psychotropics and to evaluate the QTc after initiation of therapy.     

QTc prolongation and antipsychotic medications in a sample of 1017 patients with schizophrenia

Many antipsychotic drugs cause QT prolongation, although the effect differs based on the particular drug. We sought to determine the potential for antipsychotic drugs to prolong the QTc interval (> 470 ms in men and > 480 ms in women) using the Bazett formula in a “real-world” setting by analyzing the electrocardiograms of 1017 patients suffering from schizophrenia. Using logistic regression analysis to calculate the adjusted relative risk (RR), we found that chlorpromazine (RR for 100 mg = 1.37, 95% confidence interval (CI) = 1.14 to 1.64; p < .005), intravenous haloperidol (RR for 2 mg = 1.29, 95% CI = 1.18 to 1.43; p < .001), and sultopride (RR for 200 mg = 1.45, 95% CI = 1.28 to 1.63; p < .001) were associated with an increased risk of QTc prolongation. Levomepromazine also significantly lengthened the QTc interval. The second-generation antipsychotic drugs (i.e., olanzapine, quetiapine, risperidone, and zotepine), mood stabilizers, benzodiazepines, and antiparkinsonian drugs did not prolong the QTc interval. Our results suggest that second-generation antipsychotic drugs are generally less likely than first-generation antipsychotic drugs to produce QTc interval prolongation, which may be of use in clinical decision making concerning the choice of antipsychotic medication.     

The Clinical Significance of QT Interval Prolongation in Anesthesia and Pain Management: What You Should and Should Not Worry About

The most feared drug-induced complication is fatal cardiac arrest. Torsades de pointes (TdP) is a polymorphic ventricular tachycardia occurring in the setting of a QT interval prolongation and is the most frequent type of drug-induced pro-arrhythmia. The most common mechanism of QT prolongation and TdP is blockade of the rapid component of the delayed rectifier repolarizing potassium conductance IKr. Anesthesiologists have extensive experience with QT prolonging drugs, but there are relatively few reports of TdP occurring in the perioperative setting. Nevertheless, regulatory concern regarding the drug droperidol resulted in a significant reduction in its use. Concern regarding two other agents that potently block IKr, i.e., sevoflurane and methadone, has grown, and practitioners are worried that these valuable agents may meet the same fate. In this review, the data regarding the TdP risk of droperidol, sevoflurane, and methadone are compared with particular emphasis on the different settings in which they are employed. While the three drugs are potent IKr inhibitors, little evidence exists to suggest that droperidol or sevoflurane are associated with significant proarrhythmia in the perioperative setting. Due to factors such as inhibition of the parasympathetic nervous system, prevention of hypoxia and hypercarbia, and attention to serum electrolytes, TdP is a very rare occurrence in the perioperative environment. Methadone, however, is typically given to outpatients, over long periods, and in combination with agents that inhibit its metabolism or are QT prolonging in their own right. Thus, pre- and post-drug electrocardiograms may be appropriate when prescribing methadone for outpatients, while the much lower risk for TdP (and the difficulties inherent in QT measurement in the perioperative period) render this approach unfruitful and worthy of reevaluation.