Iatrogenic torsade de pointes induced by thioridazine

Torsade de pointes induced by psychotropic drugs and the prevalence of its risk factors

OBJECTIVE

To investigate all published case reports of torsade de pointes (TdP) induced by psychotropic drugs (PDs) in order to examine the prevalence of risk factors for TdP prior to the drug initiation.

METHOD

We found 45 reports on 70 patients with TdP induced by PDs. Each report was analyzed for the presence of risk factors for TdP: female gender, heart disease, hypokalemia, high doses of offending agent, concomitant use of a QT interval prolonging agent, and a history of long-QT syndrome.

RESULTS

Female gender was the most common risk factor for TdP (71.4%). The other studied risk factors were also frequently present (34.2-14.2%). Nearly all patients had at least one and 51 (73%) patients had >2 risk factors for TdP prior to PD initiation.

CONCLUSION

We wish to raise the level of awareness of risk factors for TdP in the psychiatric community.

Pharmacokinetic Factors in the Adverse Cardiovascular Effects of Antipsychotic Drugs

Antipsychotics may cause serious adverse cardiovascular effects, including prolonged QT interval and sudden death. This review considers antipsychotic-induced cardiovascular events from three perspectives: high-risk drugs, high-risk individuals and high-risk drug interactions. Pharmacokinetic drug interactions involving the cytochrome P450 (CYP) enzymatic pathway and pharmacodynamic interactions leading to direct cardiotoxic effects are discussed. Original reports on antipsychotic-induced drug interactions are reviewed, with consideration of management guidelines. The literature was reviewed from 1 January 1966 to 1 February 2002. The literature search revealed only 12 original articles published on antipsychotic drug interactions leading to cardiovascular adverse events. Only 4 of the 12 reports were prospective studies; the remainder were either retrospective or anecdotal.Although poor study designs preclude a definitive statement, it appears that pharmacokinetic interactions primarily involved the CYP2D6 and CYP3A4 enzymatic pathways. Those involving the CYP2D6 isozyme included interactions with tricyclic antidepressants, selective serotonergic reuptake inhibitors and beta-blockers. Among these drug interactions, tricyclic antidepressants were most likely to reach clinical significance because of their limited therapeutic index. Drug interactions related to the CYP3A4 pathway were generally less severe, and involved high-potency antipsychotics coadministered with inhibitors such as clarithromycin. Strategies are discussed for the management of adverse cardiovascular events related to antipsychotic drug interactions, including the use of an algorithm. Large, randomised, placebo-controlled studies with strict inclusion criteria are needed to determine the role that antipsychotics play in QT prolongation and sudden death.

Torsade de pointes due to noncardiac drugs: most patients have easily identifiable risk factors

Numerous medications, including drugs prescribed for noncardiac indications, can lead to QT prolongation and trigger torsade de pointes. Although this complication occurs only rarely, it may have lethal consequences. It is therefore important to know if patients with torsade de pointes associated with noncardiac drugs have risk factors that are easy to identify. We reviewed reports of drug-induced torsade de pointes and analyzed each case of torsade de pointes associated with a noncardiac drug for the presence of risk factors for the long QT syndrome that can be easily identified from the medical history or clinical evaluation (female gender, heart disease, electrolyte disturbances, excessive dosing, drug interactions, and history of familial long QT syndrome). We identified 249 patients with torsade de pointes caused by noncardiac drugs. The most commonly identified risk factor was female gender (71%). Other risk factors were frequently present (18%-41%). Virtually all patients had at least 1 of these risk factors, and 71% of patients had 2 or more risk factors. Our study suggests that almost all patients with torsade de pointes secondary to noncardiac drugs have risk factors that can be easily identified from the medical history before the initiation of therapy with the culprit drug.

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.

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.

Antipsychotic-related QTc prolongation, torsade de pointes and sudden death

Sudden unexpected deaths have been reported with antipsychotic use since the early 1960s. In some cases the antipsychotic may be unrelated to death, but in others it appears to be a causal factor. Antipsychotics can cause sudden death by several mechanisms, but particular interest has centred on torsade de pointes (TdP), a polymorphic ventricular arrhythmia that can progress to ventricular fibrillation and sudden death. The QTc interval is a heart rate-corrected value that represents the time between the onset of electrical depolarisation of the ventricles and the end of repolarisation. Prolongation of the QTc interval is a surrogate marker for the ability of a drug to cause TdP. In individual patients an absolute QTc interval of >500 msec or an increase of 60 msec from baseline is regarded as indicating an increased risk of TdP. However, TdP can occur with lower QTc values or changes. Concern about a relationship between QTc prolongation, TdP and sudden death applies to a wide range of drugs and has led to the withdrawal or restricted labelling of several. Among antipsychotics available in the UK, sertindole was voluntarily suspended, droperidol was withdrawn, and restricted labelling introduced for thioridazine and pimozide. The degree of QTc prolongation is dose dependent and varies between antipsychotics reflecting their different capacity to block cardiac ion channels. Significant prolongation is not a class effect. Among currently available agents, thioridazine and ziprasidone are associated with the greatest QTc prolongation. Virtually all drugs known to cause TdP block the rapidly activating component of the delayed rectifier potassium current (I(kr)). Arrhythmias are more likely to occur if drug-induced QTc prolongation coexists with other risk factors, such as individual susceptibility, presence of congenital long QT syndromes, heart failure, bradycardia, electrolyte imbalance, overdose of a QTc prolonging drug, female sex, restraint, old age, hepatic or renal impairment, and slow metaboliser status. Pharmacodynamic and pharmacokinetic interactions can also increase the risk of arrhythmias. Further research is needed to quantify the risk of sudden death with antipsychotics. The risk should be viewed in the context of the overall risks and benefits of antipsychotic treatment. It seems prudent, where possible, to select antipsychotics that are not associated with marked QTc prolongation. If use of a QTc-prolonging drug is warranted, then measures to reduce the risk should be adopted.

Thioridazine and sudden unexplained death in psychiatric in-patients

BACKGROUND

Sudden death has been linked to antipsychotic therapy, but the relative risk associated with specific drugs is unknown.

AIMS

To assess the risk of sudden unexplained death associated with antipsychotic drug therapy and its relation to drug dose and individual agents.

METHOD

A case-control study of psychiatric in-patients dying suddenly in five hospitals in the north-east of England and surviving controls matched for age, gender and mental disorder. Logistic regression analysis was used to identify significant risk factors, and odds ratios were calculated.

RESULTS

Sixty-nine case-control clusters were identified. Probable sudden unexplained death was significantly associated with hypertension, ischaemic heart disease and current treatment with thioridazine (adjusted odds ratio=5.3, 95% CI 1.7-16.2, P=0.004). There was no significant association with other individual antipsychotic drugs.

CONCLUSIONS

Thioridazine alone was associated with sudden unexplained death, the likely mechanism being drug-induced arrhythmia.

Electrophysiologic characterization of the antipsychotic drug sertindole in a rabbit heart model of torsade de pointes: low torsadogenic potential despite QT prolongation

There is growing concern that antipsychotic drugs that prolong the QT interval almost always increase the risk for patients to develop life-threatening ventricular tachyarrhythmias (VTs) of the torsade de pointes type. We therefore sought to compare the electrophysiologic effects of the psychotropic agent sertindole, which prolongs cardiac repolarization by inhibiting the rapid component of the delayed rectifier potassium current (I(Kr)) but has a low torsadogenic potential to the antiarrhythmic agent dl-sotalol. In 18 Langendorff-perfused rabbit hearts, sotalol (10 microM, n = 8) and sertindole (0.5, 1.0, and 1.5 microM; n = 10) led to significant and comparable QT prolongation. In the presence of sotalol, torsade de pointes reproducibly occurred in atrioventricular node-blocked hearts after lowering the potassium concentration to 1.5 mM. High doses of sertindole (1.5 microM) only caused monomorphic VT (n = 4) and nonsustained polymorphic VT (n = 2) in the presence of QRS prolongation. Multiple simultaneous epi- and endocardial monophasic action potentials and a volume-conducted ECG demonstrated widening of the T/U wave, early afterdepolarizations, and increased dispersion of repolarization in the presence of dl-sotalol. In contrast to sotalol, QT and monophasic action potential prolongation were cycle length-independent in the presence of sertindole. Sertindole had no significant effect on transmural or interventricular dispersion of repolarization. Early afterdepolarizations did not occur. Despite comparable QT prolongation, sertindole did not display the proarrhythmic profile typical of other blockers of I(Kr) such as dl-sotalol. It is likely that a different mode of interaction between sertindole and the channel and/or additional pharmacological effects of sertindole, e.g., its ability to inhibit I(Na) and/or its ability to block alpha(1)-receptors, play a role.

The QT interval and the atypical antipsychotic, sertindole

Sertindole is a limbic-selective antipsychotic agent with a strong affinity for D2, 5-HT2 and α1-adrenergic receptors. Prolongation of the QT interval and other adverse cardiac or cardiovascular reactions are known effects of most antipsychotic drugs. For this reason such effects have been extensively monitored during clinical trials of sertindole. A small proportion of sertindole-treated patients were found to exhibit an increase in QT interval. Detailed analysis revealed no increased risk with sertindole of lethal complications due to an increase in QT interval. Nevertheless, as with other antipsychotics, electrocardiogram (ECG) recordings should be made prior to starting and during treatment with sertindole.

Concentration-related pharmacodynamic effects of thioridazine and its metabolites in humans

OBJECTIVE

To measure cardiac and other effects of thioridazine and relate these to the plasma concentration of the parent drug and its principal metabolites.

METHODS

A double-blind, randomized-order crossover study involving nine healthy male subjects compared the effects of single doses of thioridazine (10 mg and 50 mg) with placebo. Plasma concentrations of thioridazine and its ring sulfoxide, side-chain sulfoxide, and side-chain sulfone metabolites were measured, together with effects on the ECG, blood pressure, salivary flow, and a batch of psychomotor tests for 72 hours after administration.

RESULTS

Thioridazine, 50 mg, reduced standing systolic blood pressure (mean peak changes from baseline [95% CI] -32 mm Hg [-55, 10 mm Hg]; p < 0.01 versus placebo) and diastolic blood pressure (-14 mm Hg [-26, -2 mm Hg]; p < 0.05), increased standing heart rate (7 beats/min [-1, 16 beats/min]; p < 0.05), impaired psychomotor function, and prolonged the JT (20 ms1/2 [7, 34 ms1/2]; p < 0.05), QTa (22 ms1/2 [8, 36 ms1/2]; p < 0.05), and QTc (22 ms1/2 [11, 33 ms1/2]; p < 0.01) intervals, but had no effect on QT dispersion (-12 ms1/2 [-31, 6 ms1/2]). Thioridazine, 1.0 mg, also significantly increased QTc, but the effect was less marked (9 ms1/2 [-1, 19 ms1/2]; p < 0.05). Plasma thioridazine and metabolite concentrations did not correlate significantly with these effects. Maximum effects on QTc occurred after peak concentrations of thioridazine but before peak concentrations of the ring sulfoxide and side-chain sulfone metabolites.

CONCLUSIONS

These data suggest that thioridazine has dose-related effects on ventricular repolarization and that the parent drug causes an important proportion of these effects, although its metabolites may also contribute.

Amisulpride poisoning: a report on two cases

The first two observations of human poisoning involving the recently developed neuroleptic amisulpride are described. In both cases drug determination was performed using reversed-phase HPLC coupled with diode array detection. Case 1 was a nonfatal overdosage in which the ingestion of 3.0 g amisulpride induced an attack of seizures, then light coma with agitation, hyperthermia, mydriasis, minimal extrapyramidal features, tachycardia and slight prolongation of the QT interval; the blood concentration of amisulpride was 9.63 micrograms ml-1. Case 2 was a fatality attributed to amisulpride in which the measured blood concentration was 41.70 micrograms ml-1. Our results are discussed in the light of data previously reported on the toxicity of substituted benzamides.

In vitro electrophysiological detection of iatrogenic arrhythmogenicity

Cardiac arrhythmias and sudden death have been associated with both therapeutic and toxic doses of a number of cardiotropic and non-cardiac drugs. Generally the drug-induced electrocardiographic (ECG) alterations have been well described, whereas corresponding cellular electrophysiological effects are poorly documented or lacking. Taking into account the recent advances in the understanding of the mechanisms underlying arrhythmias and antiarrhythmic effects, suitable relationships can be established between ECG alterations and drug effects on cardiac action potential. Thus, a decrease in maximal upstroke velocity (Vmax) and membrane depolarisation leading to cellular inexcitability may slow conduction, prolong QRS interval duration and result in incessant wide QRS ventricular tachycardia. On the other hand, lengthening of the repolarisation phase and early afterdepolarisations (EADs) have been proposed as a mechanism for prolonged QT interval and subsequent Torsades de Pointes. A representative study aimed at detecting the arrthymogenic potentiality of a drug is given, by examining carefully the concentration- and frequency-dependent effects of four neuroleptics (sultopride, droperidol, thioridazine and clozapine) on Purkinje fibers and comparing them with the reported iatrogenic arrhythmias. The results showed that 10 to 100 microM sultopride and 0.01 to 1 microM droperidol exerted "pure" class III effects. In addition, higher concentrations (3 to 30 microM) of droperidol reversed the prolonging effect on repolarisation concomitantly with a dose- and frequency-dependent decrease in Vmax, action potential amplitude and resting membrane potential (class I effects) resulting in cellular inexcitability at 30 microM. Similar class I effects were induced by thioridazine and clozapine concomitantly with a slight prolonging effect on final repolarisation (class Ia effects). In the presence of sultopride (30 and 100 microM) and droperidol (0.3 to 3 microM), EADs developed at plateau level. Their incidence, amplitude and number were influenced by extracellular K or Mg concentration, stimulation frequency, modification of Ca entry (by nifedipine or isoproterenol). These experimental results fit well with clinical data although they need further development to precise underlying ionic mechanisms. Therefore, in vitro studies should be considered before clinical prospects for future drug development.

Clinical use of high-dose neuroleptics

There has been increasing public concern about the risks of high-dose antipsychotic (neuroleptic) treatment, arising in part from an, as yet unproven, association between high-dose treatment and death in a small minority of patients. The clinical issues related to the use of neuroleptics in doses exceeding the maximum recommended in theBritish National Formulary(BNF) were discussed at the Psychopharmacology Subcommittee. When, if ever, should the recommended doses be exceeded?

[Arrhythmogenic effects of sultopride chlorhydrate: clinical and cellular electrophysiological correlation]

This study was designed following the first documented case of torsades de pointes induced by sultopride hydrochloride, a substituted benzamide neuroleptic drug. The patient, a 48 year-old woman with no known cardiovascular disease, had been treated for several years with this drug. She was admitted for severe bronchospasm requiring artificial ventilation. Twenty-one hours after her admission, she developed several episodes of torsades de pointes, which were successfully treated with magnesium sulphate. At that time, the QT interval was 500 ms for a heart rate of 108 b.min-1 (QTc of 668 ms, and theoretical QTc 370 ms). On the fourth day, QTc was 548 ms and theoretical QTc 370 ms. The sultopride was stopped on the fifth day. Two days later, QTc was 397 ms. Six months later, there was no recurrence. Several cases of TdP or sudden death have been reported in patients receiving neuroleptic drugs. The effects of sultopride hydrochloride were therefore tested on isolated ferret Purkinje fibres, using the microelectrode technique. Three concentrations of the drug (D1, D2, D3) were tested, as well as normal Tyrode solution. Maximum diastolic potentials (Vmax) were -88.37 +/- 0.89 mV (control), -89.08 +/- 1.20 mV (D1), -90.00 +/- 1.06 mV (D2), and -90.14 +/- 1.20 mV (D3). Vmax was not affected by sultopride during pacing at 1,000 ms of cycle length. The duration of the action potential increased with the drug concentration. There was no early after-depolarisation (EAD) during control, and 7 out of 9 fibers had EAD and 3 out of 9 triggered activity in D3. The solvent (benzyl alcohol) did not modify the action potential.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanisms and risk factors for proarrhythmia with type Ia compared with Ic antiarrhythmic drug therapy

Proarrhythmia defined as the exacerbation of existing arrhythmias or the genesis of new arrhythmias de novo may result from any antiarrhythmic agent. The two general clinical syndromes of sustained arrhythmias that result appear to have distinct clinical properties that are consistent with the proposed basic mechanisms of arrhythmogenesis. Torsades de points occurs most commonly in association with administration of type Ia antiarrhythmic agents and has characteristics most consistent with triggered activity mediated by early after depolarization. Conversely, incessant, sustained, monomorphic, wide complex ventricular tachycardia occurs most commonly in association with type Ic antiarrhythmic agents and has characteristics most consistent with incessant reentry. These general subdivisions are probably oversimplified, and in fact, much overlap likely exists. In addition, these proposed mechanisms may not apply to other forms of proarrhythmia such as an increased frequency of isolated ventricular premature couplets or repetitive forms. Furthermore, proarrhythmia may also occur during treatment of supraventricular arrhythmias; although some of these described syndromes are consistent with incessant reentry, the clinical syndromes are not sufficiently defined to better characterize potential mechanisms. Further investigation, therefore, is needed to better define the mechanisms in question, but the mechanisms proposed in this article help to provide a rational approach toward understanding and dealing with clinical proarrhythmia.