Hostname: page-component-7c8c6479df-fqc5m Total loading time: 0 Render date: 2024-03-28T17:18:08.083Z Has data issue: false hasContentIssue false

Thioridazine and sudden unexplained death in psychiatric in-patients

Published online by Cambridge University Press:  02 January 2018

J. G. Reilly*
Affiliation:
Academic Department of Psychiatry, University of Newcastle upon Tyne
S. A. Ayis
Affiliation:
Wolfson Unit of Clinical Pharmacology, University of Newcastle upon Tyne
I. N. Ferrier
Affiliation:
Academic Department of Psychiatry, University of Newcastle upon Tyne
S. J. Jones
Affiliation:
Wolfson Unit of Clinical Pharmacology, University of Newcastle upon Tyne
S. H. L. Thomas
Affiliation:
Wolfson Unit of Clinical Pharmacology, University of Newcastle upon Tyne
*
Dr S. H. L. Thomas, Wblfson Unit of Clinical Pharmacology, University of Newcastle, Newcastle NE2 4HH, UK. Tel: 0191 222 8094; fax: 0191 261 5733; e-mail: simon.thomas@ncl.ac.uk
Rights & Permissions [Opens in a new window]

Abstract

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 arrythmia.

Type
Papers
Copyright
Copyright © 2002 The Royal College of Psychiatrists 

Psychiatric patients have a high death rate from cardiovascular causes (Reference Harris and BarracloughHarris & Barraclough, 1998). One contributory mechanism may be drug-induced arrhythmia, because some antipsychotic drugs delay ventricular repolarisation (Reference Warner, Barnes and HenryWarner et al, 1996; Reference Reilly, Ayis and FerrierReilly et al, 2000) and this may result in a form of ventricular tachycardia, termed torsades de pointes, which may cause sudden death (Reference ThomasThomas, 1994). This retrospective matched case—control study investigated the hypotheses that the risk of sudden death is increased in psychiatric in-patients exposed to antipsychotic drugs, that this is a dose-related phenomenon and that the relative risk is greatest for those drugs shown to have the most marked effects on the QT interval. Additional risk factors studied were other psychotropic drug therapy, past medical history and psychiatric diagnosis.

METHOD

The study was carried out in five large psychiatric hospitals in the north-east of England serving a total catchment population of 1.23 million. There was no direct patient contact and all information was obtained from medical records, following ethical approval.

Cases

All in-patient deaths involving those aged 18-74 years (inclusive) from 1 January 1984 to 31 December 1995 were identified and medical notes were sought and screened. Death was classified as ‘probable’ sudden unexplained death provided that (a) the patient died within 1 h of being observed in their usual state of health (or was found dead more than 1 h after having last been seen, but having been seen in their usual state of health within the previous 24 h) and (b) there was no evidence of a non-cardiac cause, including choking or convulsions.

Patients could be included as cases if they had suffered recent symptoms potentially caused by prodromal cardiac arrhythmia (dizziness, palpitations, syncope, chest pain or breathlessness) provided that there was no clinical evidence of an alternative cause such as myocardial infarction, stroke or chest disease.

Post-mortem data were sought, including from the local coroner, for all cases of ‘probable’ sudden unexplained death. If an alternative cause of death was demonstrated, including myocardial infarction, the patient was excluded as a case. If no alternative cause for death was identified, the death was classified as ‘confirmed’ sudden unexplained death. Coronary artery disease did not exclude use as a case unless there was evidence of recent coronary thrombosis or recent myocardial infarction.

Notes of all cases were examined independently by a researcher who was blind to drug therapy, to confirm that study criteria for sudden unexplained death were met. Possible cases where there was disagreement were rejected.

Controls

Two controls were sought for each case. Both were in-patients at the same hospital at the time of death of the case. They were each matched for age, gender and duration of in-patient stay and one was also matched for primary psychiatric diagnosis. The purpose of using two controls was to increase the statistical power of the study. The availability of a control unmatched for psychiatric diagnosis allows the investigation of diagnosis as a risk for sudden death, whereas the availability of a control matched for psychiatric diagnosis is helpful if diagnosis is found to be a significant factor for sudden cardiac death. The use of two types of controls also allows the consistency and robustness of associations with drug therapy to be determined in different models. Controls were identified by searching hospital databases for patients of the same gender who were within 5 years of the age of the case. For cases who had been in hospital less than 5 years, controls were sought from the age— and gendermatched controls admitted within 1 year of the death of the case. Close matching by year of admission was more difficult for cases who had been in hospital for more than 5 years. For these, age— and gendermatched controls who had also been in hospital for more than 5 years and who were in-patients at the time of death of the case were sought. For either group, the potential controls selected were those whose date of admission most closely matched that of the case. If no controls were identified, the process was repeated using a 10-year age band. The same process was used to select the second controls, who were also matched according to primary psychiatric diagnosis and classified according to ICD-10 (World Health Organization, 1992) in one of five categories (organic disorders, schizophrenia, affective disorders, alcohol dependence or misuse and ‘other’, including neuroses, eating disorders and personality disorders).

Data collected

Psychiatric diagnoses, medical history, cardiac history and all drug therapy within the previous 6 months prior to death (cases) or the index date (controls) were recorded for both patients and controls. For controls of those cases who had died within 60 days of admission, the index date was defined as the same number of days after admission as death occurred in the case. If the interval was longer, the index date was taken as the date of death of the case. The index time was the time of death of the case. Exposure to drugs was defined as use, according to the hospital prescription chart, within 24 h of death or the index date and time. Antipsychotic drugs were put in three groups by dose using the following chlorpromazine equivalent dose ranges: zero (none), ≤1000 mg per day (low dose) and > 1000 mg per day (high dose).

Statistical analysis

Probable sudden death and confirmed sudden death were defined as the outcome variables for separate conditional logistic regression analyses. The statistical software packages SPSS version 10 and EGRET for Windows (1999, Cytel Software Corporation, Cambridge, Massachusetts, USA) were used.

The original design specified the matching of each case with two controls, one of which was matched for psychiatric disease group. Before performing this analysis, a 1:1 case—control analysis was to be performed using the single control unmatched for psychiatric disease to determine if there was an association between psychiatric disease group and sudden cardiac death. If this was found, the influence of psychiatric disease would be included in the final model. In the absence of a significant association, it was to be ignored.

For each analysis, unadjusted odds ratios for ‘probable’ sudden unexplained death were first calculated for a range of possible predictive variables, including specific drug therapy and cardiac disease. Adjusted odds ratios were then obtained via the conditional logistic regression model, incorporating those variables where P<0.05. The method of backward stepwise regression was also used to establish the most important predictive variables, for which adjusted odds ratios were calculated. Using this method, the least significant predictive factors are eliminated from the conditional logistic regression analysis in turn, until only those that are significantly associated with sudden death remain. Variables were retained in the model if their significance level was less than 15%. The unadjusted and adjusted odds ratios using ‘confirmed’ sudden death as the outcome variable were obtained using the same approach.

RESULTS

There were 1350 deaths identified in the 5 hospitals over the 12-year period of study and 89% of case notes were available for review. Of these, 77 initially met the criteria for ‘probable’ sudden unexplained death. In 30, a post-mortem was available and 3 of these were excluded as cases because there was evidence of an alternative cause of death (three myocardial infarctions). Thus, 74 (5%) of all deaths met the study criteria for ‘probable’ and 27 met the criteria for ‘confirmed’ sudden unexplained death.

Of the 74 ‘probable’ cases, 37 (50%) were female. The median age was 69 years. Seventeen cases were younger than 65 years but only one was less than 50 years old. No sudden deaths occurred during restraint or within 1 h of parenteral antipsychotic medication. Adequately matched controls could not be found for 5 (disease unmatched) and 11 (disease matched) ‘probable’ cases, leaving a total of 69 and 63 clusters for the respective case—control analyses. Demographic information and breakdown by principal psychiatric diagnosis, cardiovascular disorder and drug therapy are shown in Table 1. There was a particular lack of information on smoking and alcohol use in the medical notes.

Table 1 Risk factors for ‘probable’ sudden death

Risk factor Cases included in analysis Controls unmatched for diagnosis Controls matched for diagnosis Missing data (across all three groups) Unadjusted odds ratios (95% CI) P
Total number 69 69 63 -
Age in years (mean and s.d.) 66.7 (7.7) 66.6 (8.7) 66.9 (10.7) -
Male 33 31 33 -
Median length of stay in days 633 300 345 -
Psychiatric disorder
Schizophrenia 23 24 19 0.92 (0.40-2.1) 0.84
Mood disorder 27 22 17 1.4 (0.68-2.7) 0.38
Organic disorder 31 30 32 1.1 (0.57-1.9) 0.88
Physical illness
Arrhythmia 5 2 1 3 N/A
Chronic lung disease 6 2 2 3 2.5 (0.49-12.9) 0.27
Heart failure 7 3 1 N/A
Hypertension 9 3 3 3 4.0 (0.85-18.8) 0.08
Ischaemic heart disease 17 6 3 3 3.5 (1.15-10.6) 0.027
Previous myocardial infarction1 11 3 2 3.7 (1.02-13.1) 0.05
Stroke 8 8 8 3 1.0 (0.25-4.0) 1.0
Alcohol excess 4 4 3 140 N/A
Smoking ever 15 19 12 136 N/A
Antipsychotic therapy
Chlorpromazine 5 6 7 1 0.75 (0.17-3.3) 0.71
Droperidol 2 0 0 N/A
Flupenthixol 5 3 3 1 1.67 (0.40-7.0) 0.48
Fluphenazine 3 6 5 1 0.40 (0.08-2.1) 0.27
Haloperidol 7 13 6 0.50 (0.19-1.3) 0.16
Risperidone 0 1 1 N/A
Sulpiride 1 1 2 1.0 (0.06-16.0) 1.0
Thioridaziné 24 19 9 1.6 (0.67-3.9) 0.28
Trifluoperazine 3 3 6 1.0 (0.20-4.9) 1.0
Zuclopenthixol 2 0 1 N/A
High-dose antipsychotic 4 4 1 1.0 (0.25-4.0) 1.0
Low-dose antipsychotic 38 38 30 1.1 (0.56-2.3) 0.72
Any antipsychotic 42 40 31 1.1 (0.55-2.4) 0.71
Other drug therapy
Beta-blockers 4 0 0 N/A
Benzodiazepines 12 13 14 1.0 (0.35-2.8) 1.0
Carbamazepine 5 10 4 0.38 (0.10-1.4) 0.15
Chlormethiazole 7 7 4 1.0 (0.29-3.4) 1.0
Diuretics 17 3 10 8.0 (1.8-34.8) 0.01
Lithium 2 4 3 0.50 (0.09-2.7) 0.42
Other 1 1 0 1.0 (0.06-16.0) 1.0
Phenelzine 2 0 0 N/A
Procyclidine 11 10 9 1.1 (0.43-2.9) 0.80
Sodium valproate 1 5 1 0.2 (0.02-1.7) 0.14
SSRIs 2 2 2 1.0 (0.14-7.1) 1.0
Tricyclic antidepressants 13 12 11 1.11 (0.45-2.7) 0.81

Two initial analyses were performed using single controls, unmatched and matched for psychiatric diagnosis, respectively. Table 1 shows the unadjusted odds ratios for the ‘probable’ sudden death group (n=69) using the single control unmatched for diagnosis. Odds ratios adjusted using conditional logistic regression and backwards stepwise regression are shown in Table 2. In this analysis, the psychiatric conditions of mood disorder and schizophrenia were not significantly associated with sudden cardiac death. However, the presence of organic disorder was significantly associated after adjustment for confounding. Other factors significantly associated with probable sudden death in this analysis were the presence of a history of hypertension or myocardial infarction and current treatment with diuretics or thioridazine. There was a significant negative association with carbamazepine and sodium valproate therapy (Table 2).

Table 2 Risk factors for ‘probable’ sudden death

Risk factor Adjusted odds ratios1(full model) Adjusted odds ratios1(backwards stepwise regression)
OR (95% CI) P OR (95% CI) P
Psychiatric disorder
Schizophrenia 1.2 (0.12-11.2) 0.90
Mood disorder 0.69 (0.09-5.5) 0.72
Organic disorder 9.9 (1.2-83.6) 0.035 5.2 (1.3-21.8) 0.022
Physical illness
Chronic lung disease 22.4 (0.31->100) 0.16
Hypertension > 100(7.7->100) 0.011 > 100(4.6->100) 0.008
Ischaemic heart disease 6.2 (0.47-81.0) 0.17
Previous myocardial infarction 7.6 (0.47->100) 0.15 10.9 (1.7-69.7) 0.012
Antipsychotic therapy
Chlorpromazine 7.6 (0.54-108.1) 0.132 7.2 (0.52->100) 0.141
Flupenthixol 9.4 (0.21->100) 0.25
Fluphenazine 0.06 (0.00-6.0) 0.23
Haloperidol 4.1 (0.39-42.1) 0.24
Thioridazine 37.0 (2.1->100) 0.014 16.9 (2.0->100) 0.009
Other drug therapy
Carbamazepine 0.00 (0.00-0.19) 0.006 0.02 (0.00-0.30) 0.006
Diuretics > 100 (24.3->100) 0.003 > 100 (14.8->100) 0.002
Lithium 0.42 (0.02-9.6) 0.58
Sodium valproate 0.00 (0.00-9.1) 0.13 0.00 (0.00-0.28) 0.019

Because of the significant association between organic disease and sudden death, a further case—control analysis was performed using the single control matched for psychiatric disorder. In this analysis (data not shown), factors significantly associated with sudden death after adjustment for confounding using backwards stepwise regression were the presence of ischaemic heart disease (odds ratio=17.0, 95% CI 2.3 to >100, P=0.005) or hypertension (odds ratio=13.6, 95% CI 1.6 to >100, P=0.018), and current therapy with thioridazine (odds ratio=15.4, 95% CI 2.6-89.5,P=0.002). In this analysis, there was no significant association with diuretic therapy.

The prespecified primary analysis for the study used both controls to optimise study power. Because the presence of organic disorder was shown to be significantly associated with sudden unexpected death, this was adjusted for in the model. In this analysis, sudden unexpected death was again significantly associated only with hypertension, ischaemic heart disease and thioridazine therapy (Table 3). The possibility was considered that differences in the duration of hospital stay between cases and controls might be an important confounding factor, leading to a spurious association between thioridazine therapy and sudden death. However, the use of thioridazine was not related to duration of hospital stay, and removing those clusters with the poorest matching by duration of hospital stay from the analysis did not alter the size or statistical significance of the odds ratio linking thioridazine with sudden death.

Table 3 Risk factors for ‘probable’ sudden death

Risk factor Adjusted odds ratios1(full model) Adjusted odds ratios1(backwards stepwise regression)
OR (95% CI) P OR (95% CI) P
Psychiatric disorder
Schizophrenia 1.1 (0.18-6.1) 0.95
Mood disorder 2.5 (0.57-10.9) 0.22
Organic disorder 1.6 (0.43-6.4) 0.47
Physical illness
Arrhythmia 11.9 (0.52->100) 0.12 10.9 (0.61->100) 0.10
Chronic lung disease 6.1 (0.82-44.8) 0.077 4.1 (0.74-22.4) 0.11
Heart failure 6.1 (0.45-83.8) 0.17 10.5 (0.92->100) 0.059
Hypertension 8.6 (1.4-52.2) 0.020 7.4 (1.6-33.7) 0.009
Ischaemic heart disease 6.0 (0.95-37.8) 0.057 5.4 (1.1-25.4) 0.034
Previous myocardial infarction 3.0 (0.47-18.8) 0.24 4.5 (0.77-26.3) 0.096
Antipsychotic therapy
Chlorpromazine 0.93 (0.19-4.5) 0.93
Flupenthixol 0.87 (0.11-6.7) 0.89
Fluphenazine 1.2 (0.21-7.2) 0.82
Haloperidol 1.2 (0.33-4.3) 0.79
Thioridazine 5.0 (1.4-17.5) 0.012 5.3 (1.7-16.2) 0.004
Zuclopenthixol 5.1 (0.11->100) 0.41
Other drug therapy
Carbamazepine 0.34 (0.06-1.9) 0.23
Diuretics 2.3 (0.61-8.8) 0.22
Lithium 0.60 (0.06-6.1) 0.67
Sodium valproate 0.10 (0.01-1.7) 0.11 0.08 (0.01-1.0) 0.052

To examine for the presence of a dose—response relationship with sudden death, further analyses were performed grouping antipsychotic drugs together, according to dose in chlorpromazine equivalents. When both controls were used in the analysis, a significant relationship between high-dose antipsychotic therapy and sudden death was obtained by conditional logistic regression (low-dose odds ratio=1.6, 95% CI 0.7-4.1, P=0.28; high-dose odds ratio=12.5, 95% CI 1.1-139.2, P=0.04). However, the odds ratio for high-dose therapy was not statistically significant at the 5% level after backwards stepwise regression (odds ratio=7.8, 95% CI 0.8-71.3,P=0.07) or if the single psychiatric disease-matched controls were used (adjusted odds ratio=19.7, 95% CI 0.72 to > 100, P=0.08).

To study a potential dose—response in the relationship between thioridazine and sudden death, an analysis was performed examining the effects of low— and high-dose thioridazine exposure. No cases were prescribed thioridazine at doses above 1000 mg (the chlorpromazine equivalent threshold for high dose) or 800 mg per day (maximum recommended by the British National Formulary (British Medical Association & Royal Pharmaceutical Society of Great Britain, 2000)). The median dose of 75 mg per day was chosen as a threshold for the high dose. Both low— (≤75 mg/24 h) and high-dose (>75 mg/24 h) thioridazine exposure were each significantly associated with sudden death and these effects were consistent whether either or both controls were used (Table 4). However, no statistically significant dose—response effect could be demonstrated.

Table 4 Thioridazine dose and ‘probable’ sudden death

Risk factor Adjusted odds ratios1(full model) Adjusted odds ratios1(backwards stepwise regression)
OR (95% CI) P OR (95% CI) P
One control, unmatched for diagnosis
Low-dose thioridazine > 100 (2.7->100) 0.018 42.9 (2.8->100) 0.007
High-dose thioridazine 25.6 (0.81->100) 0.066 7.6 (0.71-82.4) 0.094
Any thioridazine 37.0 (2.1->100) 0.014 16.9 (2.0->100) 0.009
One control, matched for diagnosis
Low-dose thioridazine 18.8 (0.7->100) 0.075 17.0 (1.7->100) 0.015
High-dose thioridazine 54.2 (1.5->100) 0.028 14.4 (2.0->100) 0.009
Any thioridazine 32.5 (2.0->100) 0.015 15.4 (2.6-89.5) 0.002
Two controls
Low-dose thioridazine 5.4 (1.2-23.9) 0.028 5.3 (1.4-20.5) 0.016
High-dose thioridazine 4.5 (0.86-23.7) 0.075 5.2 (1.2-23.3) 0.030
Any thioridazine 5.0 (1.4-17.5) 0.012 5.3 (1.7-16.2) 0.004

A case—control analysis was also performed using the same methods by restricting analysis to the subgroup of cases with ‘confirmed’ sudden death (n=27). Using both controls, only ischaemic heart disease was significantly associated with sudden death. Thioridazine was not a statistically significant predictor of ‘confirmed’ sudden death, but the odds ratio for the association was greater than unity and the power of this part of the study is low (Table 5).

Table 5 Risk factors for ‘confirmed’ sudden death

Risk factor Adjusted odds ratios1(full model) Adjusted odds ratios1(backwards stepwise regression)
OR (95% CI) P OR (95% CI) P
Physical illness
Arrhythmia 1.4 (0.02-94.7) 0.87
Ischaemic heart disease 4.2 (0.28-64.3) 0.30 12.0 (1.6-89.7) 0.015
Previous myocardial infarction 35.5 (0.07-> 100) 0.26
Hypertension 2.9 (0.32-25.7) 0.34
Heart failure 1.1 (0.01-> 100) 0.96
Chronic lung disease 12.4 (0.26-> 100) 0.20 7.3 (0.66-82.1) 0.11
Drug therapy
Thioridazine 7.6 (0.47-> 100) 0.15 2.9 (0.70-11.7) 0.14
Chlorpromazine 5.5 (0.16-> 100) 0.39
Haloperidol 0.18 (0.01-2.9) 0.23
Fluphenazine 8.6 (0.47-> 100) 0.15
Zuclopenthixol 1.9 (0.02-> 100) 0.79
Lithium 16.4 (0.36-> 100) 0.15
Diuretics 1.3 (0.14-12.0) 0.82

DISCUSSION

Background

Many antipsychotic drugs affect cardiac repolarisation, but these effects appear more prominent for some antipsychotic drugs than for others (Reference Fulop, Phillips and ShapiroFulop et al, 1987; Reference Fritze and BandelowFritze & Bandelow, 1998), raising the concern that these drugs, in particular, may provoke arrythmias and sudden death. Regulatory action has previously been taken for pimozide and sertindole, and we recently demonstrated that prolongation of the QT interval is more common with thioridazine and droperidol than with other antipsychotic drugs (Reference Reilly, Ayis and FerrierReilly et al, 2000). However, the systematic evidence in support of a direct link between antipsychotic drug therapy and arrythmia or sudden cardiac death is sparse.

Characteristics of sudden death patients

This study indicates that most patients who die suddenly without explanation in psychiatric hospitals are over 50 years old and many have pre-existing cardiovascular disease, in common with those at greatest risk in the wider community. No cases occurred in the aftermath of parenteral administration of antipsychotics or in the context of restraint, and this is consistent with the findings of other systematic research (Reference UngvariUngvari, 1980; Reference Davis and ZhangDavis & Zhang, 1988). The prominence of these factors in previous studies involving younger patients (Reference Jusic and LaderJusic & Lader, 1994; Reference LareyaLareya, 1995) may result from reporting bias. However, it is possible that antipsychotic drug-induced deaths that involve younger people occur more often in the community than in hospital and such deaths would not have been detected in this study. The low post-mortem rate suggests that many of the deaths in this study were not suspected by clinicians to be drug-related.

Study limitations and strengths

This matched case—control study has a number of limitations. The retrospective nature of the study and the reliance on descriptions of death recorded in medical notes are disadvantages. Records are often incomplete for important risk factors such as underlying cardiac disease, smoking or use of alcohol or illicit drugs. The low post-mortem rate raises the possibility that some of the deaths were from causes other than cardiac arrythmia, although these were only found in 3 out of 30 cases when a post-mortem had been done. Strengths of the study design and setting include the systematic method for collecting cases, which minimises potential recall or reporting bias, and the examination of hospital drug charts, which allows the collection of more detailed and accurate information about drug use than would be possible in a community setting.

Factors associated with sudden death

In this study, sudden unexplained death in psychiatric in-patients was associated with ischaemic heart disease, previous arrythmia and hypertension. Diuretic therapy was a significant risk factor in one analysis but not others. This might be because it is a marker for underlying cardiovascular disease or because diuretic therapy itself increases the arrythmia risk by causing hypokalaemia, as reported previously (Reference Siscovick, Raghunathan and RautaharjuSiscovick et al, 1996).

Thioridazine was the only single antipsychotic drug therapy found to be an independent risk factor for sudden unexplained death. There was also a possible association with increasing total antipsychotic dose. Droperidol has previously been shown to be associated with repolarisation abnormalities (Reference Reilly, Ayis and FerrierReilly et al, 2000), but there were too few exposed cases in this study to perform a reliable analysis of the impact of this drug on sudden death. Tricyclic antidepressants prolong cardiac repolarisation and have been associated with sudden death (Reference Coull, Dingwall-Fordyce and Scott:Coull et al, 1970; Reference Ballinger and RamsayBallinger & Ramsay, 1976). However, no association was found in this study. The apparent negative association between sudden unexpected death and the antiepileptic drugs carbamazepine and sodium valproate, may be due to diagnostic bias because deaths possibly caused by epilepsy were excluded as cases. However, we cannot exclude the possibility that these drugs may afford some protection by an unknown mechanism.

Confounding factors

In spite of the small size of this study and its retrospective nature, we have shown a consistent association between thioridazine and ‘probable’ sudden death. The possibility should be considered that this association is not causal but results from confounding or bias. Age is unlikely to provide important confounding because cases and controls were matched for age, albeit in 5— or 10-year bands, and the mean ages of cases and controls were similar. It seems unlikely that thioridazine would be used preferentially in patients with cardiac disease and there is no evidence of this; indeed, adjustment for the influence of cardiovascular disease increases the strength of the association. A cohort effect on prescribing linked to length of stay in hospital is also unlikely because length of stay was matched for patients dying within 60 days. Although there were differences in the cases and controls for mean length of stay when the case died after more than 60 days, removal of those clusters with the poorest matching did not affect the strength of the association between sudden death and thioridazine. We cannot completely exclude the possibility that thioridazine use is a marker for a more debilitated population more prone to sudden death for other reasons. It has not been possible to correct for the possible confounding effects of smoking or use of alcohol or illicit drugs, because information on these factors was usually missing from the patient's notes. If these factors contribute to the increased risk of sudden death associated with thioridazine, this would mean that thioridazine must be prescribed preferentially to smokers, drinkers or illicit drug-takers, which seems implausible. Caution is also required because no significant association was found between post-mortem ‘confirmed’ sudden unexplained death and thioridazine therapy, and neither was a dose—response relationship demonstrated. However, the small numbers of cases and controls involved hinder both of these analyses.

Mechanism of sudden death

Although other mechanisms of antipsychotic-induced sudden death have been suggested, including convulsions, hypotension, choking or asphyxia, myocarditis or pulmonary embolism, we believe that the most likely explanation for the association demonstrated here is that thioridazine causes arrythmias and sudden cardiac death. This finding is consistent with other evidence. Although most antipsychotic drugs show some propensity for cardiac adverse effects, thioridazine is cited most frequently. It appears more cardiotoxic than other antipsychotic drugs in overdose (Reference Buckley, Whyte and DawsonBuckley et al, 1995) and prolongs the heart rate corrected QT interval to a greater extent (Reference Reilly, Ayis and FerrierReilly et al, 2000). Thioridazine is a potent blocker of the delayed rectifier potassium channel (I kr), the main determinant of cardiac repolarisation (Reference Drolet, Vincent and RailDrolet et al, 1999). This effect is likely to be independent of the drug's dopamine receptor blocking effect because it occurs with antipsychotic drugs such as sertindole that have low potency for dopamine receptors, as well as with a wide range of drugs that do not block dopamine receptors (Reference ThomasThomas, 1994). Torsades de pointes induced by thioridazine has been reported frequently in the context of both overdose (Reference Kiriike, Maeda and NishiwakiKiriike et al, 1987) and therapeutic administration (Reference Denvir, Sood and DowDenvir et al, 1998). A previous study linked sudden death with thioridazine, although this did not adjust for age (Reference Mehtonen, Aranko and MalkonenMehtonen et al, 1991).

Clinical implications

Although rarely prescribed now as a first-line drug for schizophrenia, thioridazine is often perceived as having fewer adverse effects than more potent neuroleptics and, until recently, was commonly prescribed for anxiety, confusion and behavioural problems. Considering the risk of repolarisation abnormalities and the apparent association with sudden cardiac death, this widespread use of thioridazine can no longer be justified. If thioridazine is used at all, it should be given in the lowest possible dose because higher doses have been shown to cause more marked repolarisation abnormalities. However, we were unable to demonstrate a dose—response effect in this study and low doses are not free from risk. Based on accumulating evidence of cardiotoxicity, regulatory authorities in the USA and the UK have now recommended restriction of thioridazine prescribing to those with treatment-resistant schizophrenia. Caution is advised where thioridazine is prescribed to patients with cardiovascular diseases and is contraindicated in those most at risk of torsades de pointes. Electrocardiographic screening prior to initiation of drug therapy and monitoring during therapy are recommended. Co-prescription with inhibitors of CYP2D6 — a hepatic cytochrome P-450 isoform responsible for thioridazine metabolism — should be avoided, and patients should be monitored for hypokalaemia, which can also increase the risk of arrhythmia (Committee on Safety of Medicines, 2001).

The results of this study should be interpreted with caution. We cannot be reassured that significant risks do not exist with other antipsychotic drugs. Larger studies of sudden unexplained death in psychiatric in-patients are needed, such as the national study now underway (Reference Appleby, Thomas and FerrierAppleby et al, 2000).

Sudden unexplained death in psychiatric patients is uncommon. A proportion may be related to antipsychotic drug therapy, particularly thioridazine, and a higher index of suspicion is required when deaths occur, whether in hospital or in the community. This is a rare adverse drug reaction that should be considered in the context of the major benefits offered to patients by appropriate antipsychotic therapy.

Clinical Implications and Limitations

CLINICAL IMPLICATIONS

  1. Most patients who die suddenly without explanation in psychiatric hospitals are over 50 years old and many have pre-existing cardiovascular disease.

  2. A proportion of sudden deaths may be related to antipsychotic-induced torsades de pointes and thioridazine is particularly implicated.

  3. Both UK and US regulatory action to restrict the prescribing of thioridazine is further justified by this study.

LIMITATIONS

  1. Data were collected via retrospective examination of case notes, leading to incomplete information on smoking, alcohol use and illicit drugs, all of which may influence the risk of sudden death.

  2. The small size of the study limits conclusions about risks posed by drugs that were infrequently prescribed in the sample.

  3. Although the association with thioridazine appears robust and consistent, there remains the possibility that it may be explained by confounding factors.

Acknowledgements

This study was funded by a Northern Regional NHS Research and Development Fellowship (J. G. R.) and a Medical Research Council Project Grant. We thank the staff of the five participating psychiatric hospitals in the north-east of England for their help with the study.

Footnotes

See editorial, pp. 483–484, this issue.

Declaration of interest

None.

References

Appleby, L., Thomas, S., Ferrier, I., et al (2000) Sudden unexplained death in psychiatric in-patients. British Journal of Psychiatry, 176, 405406.CrossRefGoogle ScholarPubMed
Ballinger, B. & Ramsay, A. (1976) Death and drug therapy in a psychiatric hospital. Gerontology, 22, 220226.CrossRefGoogle ScholarPubMed
British Medical Association & Royal Pharmaceutical Society of Great Britain (2000) British National Formulary (September issue). London & Wallingford: BMJ Books & Pharmaceutical Press.Google Scholar
Buckley, N. A., Whyte, I. M. & Dawson, A. H. (1995) Cardiotoxicity more common in thioridazine overdose than with other neuroleptics. Journal of Toxicology – Clinical Toxicology, 33, 199204.Google Scholar
Committee on Safety of Medicines (2001) QT interval prolongation with antipsychotics. Current Problems in Pharmacovigilance, 27, 4.Google Scholar
Coull, D., Dingwall-Fordyce, I., Scott:, A., et al (1970) Amitriptyline and cardiac disease. Risk of sudden death identified by monitoring system. Lancet, 19, 590591.CrossRefGoogle Scholar
Davis, J. & Zhang, M. (1988) Sudden death in psychiatric patients. Psychiatric Annals, 18, 311319.Google Scholar
Denvir, M. A., Sood, A., Dow, R., et al (1998) Thioridazine, diarrhoea and torsades de pointe. Journal of the Royal Society of Medicine, 91, 145147.Google Scholar
Drolet, B., Vincent, F., Rail, J., et al (1999) Thioridazine lengthens repolarization of cardiac ventricular myocytes by blocking the delayed rectifier potassium current. Journal of Pharmacology & Experimental Therapeutics, 288, 12611268.Google ScholarPubMed
Fritze, J. & Bandelow, B. (1998) The QT-interval and the new, atypical neuroleptic sertindole. Psychopharmakotherapie, 5, 115120.Google Scholar
Fulop, G., Phillips, R., Shapiro, A., et al (1987) ECG changes during haloperidol and pimozide treatment of Tourette's Disorder. American Journal of Psychiatry, 144, 673675.Google ScholarPubMed
Harris, E. C. & Barraclough, B. (1998) Excess mortality of mental disorder. British Journal of Psychiatry, 173, 1153.Google Scholar
Jusic, N. & Lader, M. (1994) Post-mortem antipsychotic drug concentrations and unexplained deaths. British Journal of Psychiatry, 165, 787791.CrossRefGoogle ScholarPubMed
Kiriike, N., Maeda, Y., Nishiwaki, S., et al (1987) Iatrogenic torsade de pointes induced by thioridazine. Biological Psychiatry, 22, 99103.CrossRefGoogle ScholarPubMed
Lareya, J. (1995) Sudden death, neuroleptics and psychotic agitation. Progressin Neuropsychopharmacology and Biological Psychiatry, 19, 229241.CrossRefGoogle Scholar
Mehtonen, O. P., Aranko, K., Malkonen, L., et al (1991) A survey of sudden death associated with the use ofantipsychotic or antidepressantdrugs: 49 cases in Finland. Acta Psychiatrica Scandinavica, 84, 5864.CrossRefGoogle Scholar
Reilly, J., Ayis, S., Ferrier, I., et al (2000) QTc interval abnormalities and psychotropic drug therapy in psychiatric patients. Lancet, 355, 10481052.Google Scholar
Siscovick, D., Raghunathan, T., Rautaharju, P., et al (1996) Clinically silent electrocardiographic abnormalities and risk of primary cardiac arrest among hypertensive patients. Circulation, 94, 13291333.Google Scholar
Thomas, S. H. L. (1994) Drugs, QT interval abnormalities and ventricular arrhythmias. Adverse Drug Reactions & Toxicological Reviews, 13, 77102.Google ScholarPubMed
Ungvari, G. (1980) Neuroleptic-related sudden death: proven or a mere hypothesis? Pharmakopsychiatrie, 13, 2933.Google Scholar
Warner, J., Barnes, T. & Henry, J. (1996) Electrocardiographic changes in patients receiving neuroleptic medication. Acta Psychiatrica Scandinavica, 93, 311313.Google Scholar
World Health Organization (1992) Tenth Revision of the International Classification of Diseases and Related Health Problems (ICD-10). Geneva: WHO.Google Scholar
Figure 0

Table 1 Risk factors for ‘probable’ sudden death

Figure 1

Table 2 Risk factors for ‘probable’ sudden death

Figure 2

Table 3 Risk factors for ‘probable’ sudden death

Figure 3

Table 4 Thioridazine dose and ‘probable’ sudden death

Figure 4

Table 5 Risk factors for ‘confirmed’ sudden death

Submit a response

eLetters

No eLetters have been published for this article.