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Clozapine v. chlorpromazine in treatment-naive, first-episode schizophrenia: 9-year outcomes of a randomised clinical trial

Published online by Cambridge University Press:  02 January 2018

Ragy R. Girgis
Affiliation:
Department of Psychiatry, Columbia University, College of Physicians & Surgeons and New York State Psychiatric Institute, New York, USA
Michael R. Phillips
Affiliation:
Department of Psychiatry, Columbia University, College of Physicians & Surgeons, New York, USA and Beijing Suicide Research and Prevention Center, Beijing Hui Long Guan Hospital, Beijing, China
Xiaodong Li
Affiliation:
Department of Psychiatry, Columbia University, College of Physicians & Surgeons and New York State Psychiatric Institute, New York, USA
Kejin Li
Affiliation:
Bachelor of Medicine, Beijing Suicide Research and Prevention Center, Beijing Hui Long Guan Hospital, Beijing, China
Huiping Jiang
Affiliation:
Department of Psychiatry, Columbia University, College of Physicians & Surgeons and New York State Psychiatric Institute, New York, USA
Chengjing Wu
Affiliation:
Bachelor of Medicine, Beijing Suicide Research and Prevention Center, Beijing Hui Long Guan Hospital, Beijing, China
Naihua Duan
Affiliation:
Department of Psychiatry, Columbia University, College of Physicians & Surgeons and New York State Psychiatric Institute, New York, USA
Yajuan Niu
Affiliation:
Bachelor of Medicine, Beijing Suicide Research and Prevention Center, Beijing Hui Long Guan Hospital, Beijing, China
Jeffrey A. Lieberman*
Affiliation:
Department of Psychiatry, Columbia University, College of Physicians & Surgeons and New York State Psychiatric Institute, New York, USA
*
Jeffrey A. Lieberman, MD, College of Physicians and Surgeons, Columbia University, New York State Psychiatric Institute, 1051 Riverside Dr., Unit 4, New York, NY 10032, USA. Email: [email protected]
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Abstract

Background

The differential effects of so-called ‘first- and second-generation’ antipsychotic medications, when given in the first episode, on the long-term outcome of schizophrenia remain to be elucidated.

Aims

We compared the 9-year outcomes of individuals initially randomised to clozapine or chlorpromazine.

Method

One-hundred and sixty individuals with treatment-naive, first-episode schizophrenia or schizophreniform disorder in a mental health centre in Beijing, China were randomised to clozapine or chlorpromazine treatment for up to 2 years, followed by up to an additional 7 years of naturalistic treatment. The primary outcome was remission status for individuals in each group.

Results

Individuals in both groups spent essentially equal amounts of time in each clinical state over the follow-up time period (remission, 78%; intermediate, 8%; relapse, 14%). There were no significant differences on other measures of illness severity. The clozapine group was more likely than the chlorpromazine group to remain on the medication to which they were originally assigned (26% v. 10%, P = 0.01). There were no significant differences between the two groups on other secondary efficacy outcomes.

Conclusions

These findings support the comparability in effectiveness between antipsychotic medications but with slightly greater tolerability of clozapine in the treatment of first-episode psychosis.

Type
Papers
Copyright
Copyright © Royal College of Psychiatrists, 2011 

Recent research has shown that antipsychotic medications may be able to affect the natural course of schizophrenia, Reference McGlashan and Johannessen1,Reference Wyatt2 particularly when given early during the course of the illness. Reference Emsley, Oosthuizen, Kidd, Koen, Niehaus and Turner3Reference Perkins, Gu, Boteva and Lieberman6 This suggests that antipsychotic medications may prevent disease progression in schizophrenia by a mechanism that is yet to be identified. Reference Lieberman, Tollefson, Charles, Zipursky, Sharma and Kahn7,Reference Lieberman, Bymaster, Meltzer, Deutch, Duncan and Marx8

Acute-phase efficacy results suggest that few differences in therapeutic efficacy exist between individual or classes of antipsychotic medications. Reference Crespo-Facorro, Perez-Iglesias, Ramirez-Bonilla, Martinez-Garcia, Llorca and Vazquez-Barquero9Reference Sanger, Lieberman, Tohen, Grundy, Beasley and Tollefson13 Fewer studies have examined the comparative effectiveness of antipsychotic drugs in first-episode psychosis and whether the initial exposure to one medication or another will differentially affect long-term outcome. Reference Gaebel, Riesbeck, Wolwer, Klimke, Eickhoff and von Wilmsdorff14Reference Kahn, Fleischhacker, Boter, Davidson, Vergouwe and Keet17

The ongoing debate about the relative merits of different classes (for example first- v. second-generation antipsychotics) or individual antipsychotic drugs has been waged in chronic, Reference Lieberman, Stroup, McEvoy, Swartz, Rosenheck and Perkins18,Reference Jones, Barnes, Davies, Dunn, Lloyd and Hayhurst19 first-episode, Reference Crespo-Facorro, Perez-Iglesias, Ramirez-Bonilla, Martinez-Garcia, Llorca and Vazquez-Barquero9Reference Kahn, Fleischhacker, Boter, Davidson, Vergouwe and Keet17 treatment-refractory Reference Kane, Honigfeld, Singer and Meltzer20 and adolescent Reference Sikich, Frazier, McClellan, Findling, Vitiello and Ritz21 populations. Despite the fact that there are marked differences in opinions and that the validity of the so-called classes of antipsychotic drugs has been questioned, Reference Leucht, Corves, Arbter, Engel, Li and Davis22 the predominant impression is that there are minimal differences across patient groups, except that clozapine (and to a lesser extent olanzapine Reference Breier and Hamilton23,Reference Tollefson, Birkett, Kiesler and Wood24 ) is superior in treatment-refractory illness.

Given the superiority of clozapine to other antipsychotic drugs in refractory illness, we hypothesised that its superior effect would also be manifest in first-episode schizophrenia. We tested this hypothesis in a sample of first-episode, antipsychotic-naive individuals by randomising them to clozapine or chlorpromazine with long-term follow-up. The 52-week outcome results have been reported previously: we found that treatment with clozapine led to greater efficacy after 12 weeks of in-patient treatment, faster time to remission and greater time in remission, however, by 52 weeks these efficacy differences were no longer observed. Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 No outcome results from that trial beyond 1 year have been reported. In this paper, we report the 9-year follow-up results. We hypothesised that individuals originally randomised to clozapine as their first treatment exposure would have better long-term outcomes than those who were originally randomised to chlorpromazine, with the understanding that the majority of individuals would probably have taken several medications other than clozapine or chlorpromazine by the end of the study.

Method

Participants

A detailed description of the design for this study has been published previously. Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 This study was designed by the senior authors (J.A.L. and M.R.P.) and conducted at the Beijing Suicide Research and Prevention Center at the Beijing Hui Long Guan Hospital. It was approved by the Research Review Board of the Beijing Bureau of Health and conformed to the international standards for research ethics. All hospital admissions between October 1995 and December 1998 were screened for inclusion in this study. Inclusion criteria were: age between 16 and 40 years, diagnosis of schizophrenia or schizophreniform disorder, no previous antipsychotic treatment or a maximum of 14 days of prior use, maximum symptom duration of 60 months, current psychotic symptoms of moderate severity or greater for at least one of the five psychotic items assessed by the Brief Psychiatric Rating Scale (BPRS). Reference Phillips, Xiong and Zhao26 Written informed consent was provided by individuals and their families for those individuals who met the preceding criteria.

Diagnoses were established with a Chinese version of the Structured Clinical Interview for DSM–IV Axis I disorders, Reference First, Spitzer, Gibbon and Williams27 along with blood tests and physical examinations. Participants were initially randomised to either clozapine with a placebo benztropine or chlorpromazine with benztropine (2 mg twice daily) while in the hospital. For randomisation, the study nurse stratified eligible in-patients into six groups by gender and duration of positive symptoms (3–9 months, 9–24 months and 24–60 months). Participants in each of these six strata were randomised in blocks of four to either the clozapine or chlorpromazine treatment group. Participants remained in the hospital for 12 weeks, after which they were followed monthly as out-patients. They were maintained on their assigned medication under double-blind conditions for 2 years or up to the point that there was a clinical indication to change their medication regimen, whichever came first. After this point all participants were treated in an open-label, naturalistic manner. Treatment adherence was monitored via pill counting during both the randomised and open-label phases of the study.

Assessments

Efficacy assessments were performed at study entry, weekly for weeks 1–6, biweekly for weeks 6–12, at hospital discharge and every 3 months thereafter. Assessments included the Chinese versions of the BPRS, Reference Phillips, Xiong and Zhao26 the Scale for the Assessment of Negative Symptoms (SANS), Reference Phillips, Xiong, Wang, Gao, Wang and Zhang28 the Clinical Global Impression Scale (CGI) Reference Guy29 and the Global Assessment of Functioning Scale (GAF). Reference Jones, Thornicroft, Coffey and Dunn30 To assess side-effects, we used the Simpson Angus Extrapyramidal Symptoms Scale (SAESS) Reference Simpson and Angus31 (omitting sialorrhea given the use of clozapine in this trial) on the same schedule for the first 2 years and then every 6 months thereafter; and classification terms from the Coding Symbol and Thesaurus for Adverse Event Terminology (COSTART) at each assessment visit for the first year, every 3 months for the second and third years, and every 6 months thereafter. We assessed for tardive dyskinesia using the Tardive Dyskinesia Rating Scale. Reference Simpson, Lee, Zoubok and Gardos32 At periodic intervals two clinicians independently assessed participants, which allowed for verification of ratings. Electrocardiograms (ECGs) were performed at study entry, weeks 12 and 52 and yearly thereafter. White blood cell counts were done weekly during the in-patient phase of the study (i.e. approximately 12 weeks), monthly for the remainder of year 1 and year 2, and every 3 months thereafter. Fasting blood glucose values were assessed at study entry, week 12, every 3 months for the remainder of the first year and every six months thereafter. Weight was not regularly assessed during this study, so our analysis (see statistical methods below) only included weights for the 29 participants for whom we were able to calculate weight change. Additionally, the occurrence of seizures was not formally assessed during this study. However, none was reported in either group.

Statistical methods

Our primary analysis compared treatment efficacy for clozapine v. chlorpromazine for schizophrenia, following the intent-to-treat principle to compare patient outcomes according to the initial treatment assignment. Our primary analytical strategy employed generalised linear mixed models (GLMMs) for categorical repeated measures such as remission status, and mixed-effect models for continuous repeated measures such as the BPRS, SANS, CGI and GAF. The inference from these models is valid provided that the missing data are ‘missing at random’. Reference Little and Rubin33 The programs PROC GLIMMIX and MIXED in SAS (version 9.1.3) for Windows were used to estimate and test these models.

Following our previous publication from this study, Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 the primary outcome measure was participant’s remission status over the course of the 9-year observation period, classified into three ad hoc clinical states: remission, intermediate state and relapse. Remission was defined as a reduction in the total BPRS score of 50% or more from baseline, with scores of mild (3) or less on all five BPRS psychotic items (unusual thought content, suspiciousness, hallucinations, conceptual disorganisation, mannerisms and posturing) and a CGI-Severity item of mild (3) or less. Relapse was defined as having at least one BPRS psychotic item scored moderately severe (5) or higher, or at least two BPRS psychotic items scored moderate (4) or higher. The intermediate state was defined as everything else.

A three-category GLMM with logistic links was specified for the remission status as a function of initial treatment assignment, time, and other baseline covariates: baseline BPRS, gender, duration of untreated psychosis (DUP) and age at onset of psychosis. The effect of initial treatment assignment on the secondary outcome measures, including BPRS, SANS, CGI and GAF, which were all treated as continuous measures, were estimated and tested using an approach similar to that described above.

The effect of initial treatment assignment on participants’ time to drop out (retention) and the time to stopping study medication was examined using Kaplan–Meier estimates for the respective survival curves, and tested using log-rank tests. This analysis was expanded further using a Cox proportional hazards model to adjust for the covariates listed above. We used Fisher’s exact test to compare the proportions of individuals in each group who remained in the study after 9 years, the proportions of individuals in each group who remained on the originally assigned study medication, and the proportion of individuals who switched from chlorpromazine to clozapine or vice versa. Individuals who stopped taking their originally assigned medication for less than 3 months and then resumed the same medication were not considered to have discontinued their study medication unless they were treated with another antipsychotic medication.

We used t-tests to compare the average percentage of time on any antipsychotic medication after the first year, the average dose of antipsychotic medications in terms of chlorpromazine equivalents between year 2 and year 9, and the average dose of antipsychotic medications after the first year during days on which antipsychotic medications were taken (clozapine doses were converted to chlorpromazine equivalents by multiplying the clozapine dose by 1.33). The effect of cumulative antipsychotic dosage on the improvement of the BPRS from year 2 through year 9 or drop-out was compared for the two treatments using a linear regression model adjusted for several baseline covariates: baseline BPRS score, participant gender, DUP and age at onset of psychosis. We also examined the average percentages of time that individuals in each group took various antipsychotic medications after discontinuing the originally assigned study medication.

We used Fisher’s exact test to compare the proportions of participants who developed tardive dyskinesia and agranulocytosis (absolute neutrophil count <500) for the two treatment groups, and the proportion of individuals who developed tardive dyskinesia, along with mean weight gain, for participants who remained on the originally assigned study medications for 9 years. Tardive dyskinesia was liberally defined as a score of ≥2 on any body part subscale from a version of the Tardive Dyskinesia Rating Scale. Reference Simpson, Lee, Zoubok and Gardos32

Analysis of covariance (ANCOVA) models were used to test the differences in laboratory parameters at the end of the study (percentage of neutrophils and lymphocytes, white blood cells, glucose, heart rate and ECG QT interval) between the two treatments after controlling for baseline BPRS, participant gender, DUP and age at onset of psychosis. Some of the laboratory measures were not collected at the end of the study, so we filled in the missing values (n = 5 for weight gain and n = 1 for glucose) with regression-based extrapolations. Finally, for demographic and clinical variables, Fisher’s exact test was used for categorical variables and t-test was used for continuous variables. All tests used a two-sided alpha-level of 0.05.

Results

Participants

The demographic and clinical data for the participants in this study have been previously published. Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 Briefly, there were no statistically significant differences between the participants in the clozapine and chlorpromazine groups on any demographic variable (i.e. diagnosis, age, gender, baseline symptom severity and duration, and age at onset of psychotic symptoms; see online Table DS1 for the between-group analyses for those variables used later in this analysis for which results were adjusted). The average age of participants at study entry was 28.7 years (s.d. = 6.9) with a range of 15 to 42. The majority of individuals were diagnosed with paranoid schizophrenia (53%), and the rest with either undifferentiated schizophrenia (23%) or schizophreniform disorder (24%). Participants experienced psychotic symptoms for an average of 18.4 months (s.d. = 17.8 months, median 10.7) at the time of study entry. The mean age at onset of psychotic symptoms was 27.2 years (s.d. = 6.5 years, median 26.9). The mean baseline symptom severity scores were 43.8 (s.d. = 5.1) for total BPRS, 5.6 (s.d. = 0.6) for CGI-severity and 35.8 (s.d. = 7.8) for GAF.

Retention and treatment status

The first-year outcome data have been reported previously. Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 Figure 1 presents the flow of participants in this study. Of the 160 participants who initially received treatment with clozapine (n = 80) or chlorpromazine (n = 80), 124 (77.5%) continued to be followed in the study for 9 years, 63 in the clozapine group (79%) and 61 in the chlorpromazine group (76%) (P = 0.85). There was no statistically significant difference in time to drop out between the two groups (P = 0.71) (Fig. 2). This outcome remained statistically insignificant after using a Cox proportional hazard regression analysis to adjust for baseline total BPRS score, age at onset of psychotic symptoms, gender and DUP. Of the 36 individuals who dropped out of the study during the 9-year period, 19 (clozapine 9; chlorpromazine 10) dropped out during the first year. (Notably, this result is different from that reported in the initial report Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 because in the current analysis drop-out was defined as leaving the study, whereas in the original analysis drop-out included individuals who discontinued the medication to which they were originally randomised but continued to be followed-up by study staff.) Reasons for drop-out from the study included: for the clozapine group – withdrew consent 6, adverse effects 1, lack of efficacy 0, death 2, lost to follow-up 7, elopement from the hospital 1, imprisonment 0; for the chlorpromazine group – withdrew consent 6, adverse effects 1, lack of efficacy 1, death 2, lost to follow-up 8, elopement from the hospital 0, imprisonment 1. The causes of the four deaths were viral encephalitis (or meningitis), accident, unknown illness and suicide. Overall, the mortality rates were 2.5% (2/80) in both treatment groups.

Twenty-nine participants (18%) remained on the originally assigned medication after 9 years, 21 in the clozapine group (26%) and 8 in the chlorpromazine group (10%) (P = 0.01). The median amount of time until first discontinuation of the originally assigned study medication was 39 months in the clozapine group and 23 months in the chlorpromazine group, a statistically significant advantage for clozapine (log-rank 7.49, d.f. = 1, P = 0.01) (Fig. 3). The result was similar when examined using a Cox proportional hazard regression to adjust for baseline total BPRS score, age at onset of psychotic symptoms, gender and DUP (hazard ratio 0.644, 95% CI 0.45–0.92, P = 0.01). Among individuals who remained in the study after 1 year (n = 70 for clozapine, 69 for chlorpromazine), there was a non-significant trend for those in the clozapine group to spend more time (in terms of cumulative percentage of days) on any antipsychotic medication than those in the chlorpromazine group (77% v. 66%, t(137) = –1.82, P = 0.07), whereas the average doses of any antipsychotic medications, in terms of chlorpromazine equivalents, used by patients were similar (219 v. 206, respectively, t(137) = –0.49, P = 0.62). The difference remained non-significant when the analysis was limited to days on which antipsychotic medications were taken (291 v. 319, respectively; t(126) = 1.08, P = 0.28; n = 65 for clozapine and n = 63 for chlorpromazine). Additionally, there were no significant demographic or baseline clinical differences between the group of participants who remained on their originally assigned medication for the duration of the study (n = 29) and the group of participants who remained in the study for 9 years and switched medications (n = 95) (online Table DS2).

Efficacy

As previously reported, Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 the clozapine group spent significantly more time in remission during the first year of the study and had a faster time to remission in terms of psychopathological response during the first year of treatment. However, the average percentage of time that individuals spent in the three clinical states from years 2 through to 9 were essentially identical for the clozapine and chlorpromazine groups: 78% (remission), 8% (intermediate) and 14% (relapse) (Fig. 4). There were no statistically significant differences across groups in the average percentages of time spent in each clinical state or on any efficacy measure (i.e. BPRS, SANS, CGI-Severity, GAF), either averaged over the entire study time period (i.e. years 2 through to 9) or at any individual follow-up time point (for example year 2, year 3) (Table 1). These results remained statistically non-significant after adjusting for baseline BPRS score, age at onset of psychotic symptoms, gender and DUP. In addition, there was no significant

Fig. 1 Consort diagram.

effect of cumulative antipsychotic dose on improvement on the BPRS (n = 139, t(1) = –0.07, P = 0.95) nor was there an interaction effect between drug group (i.e. clozapine or chlorpromazine) and cumulative dosage (t(1) = –0.02, P = 0.98).

As a result of the similarities on outcome and efficacy measures between the clozapine and chlorpromazine groups, additional analyses were performed to determine the percentages of participants from the chlorpromazine group who took

Fig. 2 Kaplan–Meier survival curves for time to drop out from the study for the clozapine and chlorpromazine groups. There is no statistically significant difference between the two groups (P = 0.71).

clozapine at some point during the 9-year study, and vice versa. Among individuals originally randomised to chlorpromazine, 30% (24/80) took clozapine at some point during the study; only 3.8% (3/80) of the clozapine group took chlorpromazine at some point during the study (P<0.01). In addition, we determined the average percentages of time that participants in each group took other antipsychotic medications or resumed the original medication, and report them here descriptively: after discontinuing

Fig. 3 Kaplan–Meier survival curves for time to first discontinuation of the original study medication for the clozapine and chlorpromazine groups. There is a statistically significant advantage for clozapine (P = 0.01).

Fig. 4 Curves showing the per cent of individuals in the (a) clozapine and (b) chlorpromazine groups who were in the remission (solid line), intermediate (dashed line), or relapsed (dotted line) states throughout the 9-year study period. These curves are essentially identical.

chlorpromazine (n = 72, median days 2091), chlorpromazine 2%, clozapine 13%, another first-generation antipsychotic 4%, another second-generation antipsychotic 19%, unspecified antipsychotic <1%, multiple antipsychotics 7%, no antipsychotic 55%; after discontinuing clozapine (n = 59, median days 1895), chlorpromazine <1%, clozapine 7%, another first-generation antipsychotic 6%, another second-generation antipsychotic 13%, unspecified antipsychotic <1%, multiple antipsychotics 1%, no antipsychotic 73%.

Safety

Of 160 participants enrolled in the study, four (2.5%) developed agranulocytosis (two were randomised to clozapine and two were randomised to chlorpromazine). At the time that their agranulocytosis developed, one of these individuals was taking clozapine alone, one was taking chlorpromazine and trihexyphenidyl, and one was taking risperidone. The fourth person developed agranulocytosis while on aripiprazole and

Table 1 Efficacy comparisons (mean (s.d.)) between clozapine and chlorpromazine for the complete follow-up time period

Brief Psychiatric Rating Scale Scale for Assessment of Negative Symptoms Clinical Global Impression Scale – Severity Global Assessment of Functioning Scale
Chlorpromazine Clozapine P Chlorpromazine Clozapine P Chlorpromazine Clozapine P Chlorpromazine Clozapine P
Baseline 44.44 (5.11) 43.25 (5.06) 0.454 16.60 (12.98) 14.78 (9.26) 0.467 5.61 (0.56) 5.56 (0.61) 0.483 35.44 (7.34) 36.2 (8.21) 0.480
Year 1 21.21 (0.48) 20.96 (0.48) 0.360 9.08 (1.13) 7.27 (1.15) 0.131 1.88 (0.11) 1.86 (0.11) 0.443 71.47 (1.22) 73.14 (1.23) 0.167
Year 2 22.12 (0.44) 21.82 (0.44) 0.314 9.04 (1.00) 8.61 (1.01) 0.381 1.98 (0.1) 1.96 (0.1) 0.447 70.14 (1.11) 71.16 (1.12) 0.258
Year 3 22.39 (0.40) 21.82 (0.40) 0.160 9.91 (0.93) 9.36 (0.93) 0.337 2.12 (0.09) 2.01 (0.09) 0.184 68.37 (1.04) 70.29 (1.04) 0.096
Year 4 22.57 (0.41) 21.85 (0.41) 0.109 10.60 (0.95) 9.96 (0.94) 0.318 2.24 (0.09) 2.06 (0.09) 0.088 67.09 (1.06) 69.49 (1.05) 0.054
Year 5 22.66 (0.43) 21.92 (0.43) 0.113 11.10 (1.05) 10.42 (1.03) 0.322 2.34 (0.1) 2.14 (0.1) 0.077 66.29 (1.15) 68.76 (1.13) 0.062
Year 6 22.66 (0.46) 22.02 (0.45) 0.159 11.43 (1.24) 10.74 (1.20) 0.345 2.42 (0.11) 2.23 (0.11) 0.117 65.97 (1.28) 68.1 (1.25) 0.118
Year 7 22.57 (0.49) 22.15 (0.48) 0.269 11.57 (1.51) 10.91 (1.47) 0.377 2.48 (0.13) 2.34 (0.13) 0.226 66.14 (1.49) 67.5 (1.45) 0.256
Year 8 22.40 (0.55) 22.31 (0.54) 0.456 11.53 (1.89) 10.94 (1.84) 0.411 2.52 (0.16) 2.46 (0.16) 0.402 66.79 (1.8) 66.98 (1.75) 0.470
Year 9 22.13 (0.65) 22.51 (0.64) 0.660 11.31 (2.37) 10.82 (2.31) 0.441 2.54 (0.2) 2.60 (0.20) 0.589 67.92 (2.22) 66.52 (2.16) 0.675
Average (Y1–Y9) 22.40 (0.41) 21.97 (0.41) 0.231 10.66 (1.06) 10.02 (1.03) 0.331 2.29 (0.10) 2.18 (0.10) 0.215 67.54 (1.13) 68.99 (1.11) 0.180
Raw average 22.43 (0.54) 22.26 (0.75) 0.484 10.43 (1.09) 10.10 (1.53) 0.512 2.26 (0.10) 2.18 (0.15) 0.464 68.02 (1.23) 68.71(1.70) 0.390

a. There were no statistically significant differences between the two groups on any efficacy measure for the follow-up time period.

clonazepam, and then while on clozapine along with aripiprazole and propranolol. The white blood cell counts of all of these people returned to normal with appropriate modification of their medications.

Of the 160 participants, a total of 26 (16%) developed tardive dyskinesia. Nine (11.3%) of these were randomised to clozapine and 17 (21.3%) were randomised to chlorpromazine (P = 0.02). Of the 21 individuals who remained on clozapine and the 8 who remained on chlorpromazine for the entire 9 years of this study, one person on clozapine (4.8%) developed tardive dyskinesia, as did two participants on chlorpromazine (25%) (P = 0.18). Each of these three participants was on antipsychotic monotherapy with either clozapine or chlorpromazine for the entire study period before development of their tardive dyskinesia, and one of the individuals in the chlorpromazine group had taken lorazepam, chlorpheniramine and benzhexol, each for 1–2 months, approximately 2 years before development of tardive dyskinesia.

Among the 29 participants who remained on either clozapine (n = 21) or chlorpromazine (n = 8) for the complete study, there were no significant differences in weight gain (clozapine 11.39 kg, chlorpromazine 12.74 kg, P = 0.79), white blood cell count (clozapine 5933, chlorpromazine 5225, P = 0.28), per cent of neutrophils (clozapine 64.3, chlorpromazine 62.4, P = 0.73), per cent of lymphocytes (clozapine 31.3, chlorpromazine 32.5, P = 0.82), ECG heart rate (clozapine 85, chlorpromazine 79, P = 0.49), ECG QT interval (clozapine 0.34, chlorpromazine 0.34, P = 0.98) or fasting glucose level (clozapine 6.8 mmol/l, chlorpromazine 5.8 mmol/l, P = 0.21) at the 9-year end-point.

Discussion

Main findings

This study extends the paper by Lieberman et al Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 on the first year of randomised treatment to either clozapine or chlorpromazine of 160 individuals with first-episode psychosis. In contrast to our hypothesis, we found that the initial exposure of individuals with first-episode psychosis to either chlorpromazine or clozapine did not alter the long-term outcome of their illness. Clozapine and chlorpromazine do not appear to have substantially differential effects on the long-term course of schizophrenia, and presumably therapeutic efficacy, when used as the initial treatment strategies in the first episode. Outcomes in individuals treated initially with clozapine and chlorpromazine were essentially identical on the primary outcome variable, remission status, and demonstrated minimal differences on all measures of psychopathology, including negative symptoms, at every follow-up time period (Table 1). The only differences in outcome were seen in treatment continuation and retention, and these are believed to reflect the relative tolerability of the medications. These results are consistent with the results reported for the first year of this study in that the advantages seen at 12 weeks for clozapine were not sustained at 52 weeks Reference Lieberman, Phillips, Gu, Stroup, Zhang and Kong25 or thereafter. Finally, there was no effect of cumulative antipsychotic dosage on long-term outcome in this study.

The design of this study systematically addressed the question of whether clozapine has a putative disease-modifying effect (possibly neuroprotective) when administered in the first psychotic episode and confers a lasting value to individuals in the subsequent course of their illness. These results suggest that it is equally effective to wait until individuals demonstrate themselves to be non- or poorly responsive to antipsychotic medications before employing clozapine in first-episode patients, Reference Agid, Remington, Kapur, Arenovich and Zipursky34 rather than using it prophylactically. This finding remained unchanged throughout the randomised, double-blind portion of the study (i.e. through 2 years) and for the subsequent 7-year period of naturalistic treatment, at every follow-up time period (Table 1). Although more individuals stayed on clozapine for the extent of the study, this was a small proportion of the first-episode participants initially treated with clozapine and did not translate into clinical advantages, despite the overall high retention and good antipsychotic exposure in this study. These results are consistent with the findings from CATIE, Reference Lieberman, Stroup, McEvoy, Swartz, Rosenheck and Perkins18 CUtLASS Reference Jones, Barnes, Davies, Dunn, Lloyd and Hayhurst19 and EUFEST Reference Kahn, Fleischhacker, Boter, Davidson, Vergouwe and Keet17 that found few substantial differences in effectiveness between second- and first-generation antipsychotics in non-refractory illness, and therefore add to the body of evidence tempering the assertions that second-generation antipsychotics are greatly superior to first-generation ones.

It is notable that nearly 80% of individuals remained in the study in open, naturalistic treatment with any of a variety of antipsychotic medications and on appropriate dosages (averages of 219 mg/day, in terms of chlorpromazine equivalents, in the clozapine group and 206 mg/day in the chlorpromazine group over the entire maintenance period) for 9 years. Furthermore, these individuals were in the remitted state for approximately 78% of that time – a remarkable outcome, even in the era of antipsychotic medications. Reference Gitlin, Nuechterlein, Subotnik, Ventura, Mintz and Fogelson35,Reference Robinson, Woerner, Alvir, Bilder, Goldman and Geisler36 This may be related to the medication adherence achieved during this study and is consistent with previous results that report that medication adherence is critical for the relief of symptoms in first-episode patients, Reference Szymanski, Cannon, Gallacher, Erwin and Gur37 including data from one trial showing an almost fivefold greater chance of relapse when medications are discontinued. Reference Robinson, Woerner, Alvir, Bilder, Goldman and Geisler36 This may also be related to the active involvement of the staff at the Beijing Suicide Research and Prevention Center who maintained close contact with participants and their families – so that medications could be restarted quickly if the individual’s condition deteriorated. The value of such psychosocial interventions has been demonstrated and documented Reference Lehman, Lieberman, Dixon, McGlashan, Miller and Perkins38,Reference Penn, Waldheter, Perkins, Mueser and Lieberman39 and cannot be overstated. These results also demonstrate what can be accomplished in settings where retention can be maintained, which is, unfortunately, not available to the majority of individuals with schizophrenia and therefore limits the generalisability of these findings.

Side-effects

Among the 29 individuals who remained on clozapine or chlorpromazine for the entire 9 years of the study, rates of tardive dyskinesia were greater in the chlorpromazine than in the clozapine group, as expected, Reference Kane40 although it should be noted that this difference was not statistically significant, likely the result of the small sample size in this subsample. Second, agranulocytosis occurred only once among individuals treated with clozapine monotherapy, consistent with previous reports of the prevalence of agranulocytosis (approximately 1%). Reference Alvir, Lieberman, Safferman, Schwimmer and Schaaf41 Finally, the degree of metabolic and other side-effects were similar between the two groups, which is consistent with the data on clozapine and chlorpromazine, both of which are known to induce metabolic effects. Reference Allison, Mentore, Heo, Chandler, Cappelleri and Infante42,Reference Newcomer43

Limitations

There are several limitations to this study. Participants were in open, naturalistic treatment for the majority of the follow-up period after initially receiving randomised, double-blind treatment, and there was notable crossover between the two groups. This naturalistic treatment may also have confounded the effect of dosing on long-term outcome.

Implications

In terms of the question, does the type of antipsychotic medication to which a patient is first exposed influence their long-term outcome, regardless of the type of treatment to which they are later exposed, the answer from this study appears to be no. To the extent that there are any differences, these appear to be related to side-effects and tolerability and not therapeutic efficacy. The findings from this 9-year investigation of treatment-naive, first-episode participants originally randomised to clozapine or chlorpromazine suggest that the long-term outcomes of individuals with first-episode psychosis are no different whether their initial exposure is to clozapine or chlorpromazine. Further, these findings support the growing body of literature that shows few differences in effectiveness between antipsychotic medications in non-treatment refractory schizophrenia.

Funding

This work was supported by funds from the Novartis Pharmaceutical Company, which also supplied medications.

Acknowledgements

We would like to acknowledge the support of the staff at the Beijing Suicide Research and Prevention Center and the Beijing Hui Long Guan Hospital and the participation of the patients who enrolled in this study.

Footnotes

Aspects of this study have been presented at the 2009 Annual Meeting of the American Psychiatric Association (San Francisco, USA, 17 May), the 2009 Annual Meeting of the New York County District Branch of the American Psychiatric Association (New York, USA, 30 April) and the 11th Annual Symposium on Statistics in Psychiatry (Philadelphia, USA, 11 May 2009).

See editorials, pp. 266–268 and 269–271, this issue.

This work was supported by funds from the Novartis Pharmaceutical Company, which also supplied medications.

Declaration of interest

R.R.G. has received research support from Janssen and Lilly through APIRE and a travel stipend from Lilly, Forest, and Elsevier Science through the Society of Biological Psychiatry. N.D. has received research support from Pfizer. J.A.L. has received research grant support from Acadia, Allon, AstraZeneca, Bristol-Myers Squibb, Forest Labs, GlaxoSmithKline, Janssen, Merck, Organon, Pfizer, and Wyeth. He has acted as a consultant and an advisory board member for Astra-Zeneca, Bristol-Myers Squibb, GlaxoSmithKline, Eli Lilly, and Pfizer; has been a consultant for Cephalon, Johnson & Johnson and Novartis; an advisory board member for Bioline, Forest Labs, Lundbeck, Organon and Wyeth; and a DSMB member for Solvay. J.A.L. has received no direct financial compensation or salary support for participation in research, consulting, advisory board or DSMB activities. J.A.L. holds a patent from Repligen.

References

1 McGlashan, TH, Johannessen, JO. Early detection and intervention with schizophrenia: rationale. Schizophr Bull 1996; 22: 201–22.Google Scholar
2 Wyatt, RJ. Neuroleptics and the natural course of schizophrenia. Schizophr Bull 1991; 17: 325–51.Google Scholar
3 Emsley, R, Oosthuizen, PP, Kidd, M, Koen, L, Niehaus, DJ, Turner, HJ. Remission in first-episode psychosis: predictor variables and symptom improvement patterns. J Clin Psychiatry 2006; 67: 1707–12.Google Scholar
4 Marshall, M, Lewis, S, Lockwood, A, Drake, R, Jones, P, Croudace, T. Association between duration of untreated psychosis and outcome in cohorts of first-episode patients: a systematic review. Arch Gen Psychiatry 2005; 62: 975–83.Google Scholar
5 Perkins, D, Lieberman, J, Gu, H, Tohen, M, McEvoy, J, Green, A, et al. Predictors of antipsychotic treatment response in patients with first-episode schizophrenia, schizoaffective and schizophreniform disorders. Br J Psychiatry 2004; 185: 1824.Google Scholar
6 Perkins, DO, Gu, H, Boteva, K, Lieberman, JA. Relationship between duration of untreated psychosis and outcome in first-episode schizophrenia: a critical review and meta-analysis. Am J Psychiatry 2005; 162: 1785–804.Google Scholar
7 Lieberman, JA, Tollefson, GD, Charles, C, Zipursky, R, Sharma, T, Kahn, RS, et al. Antipsychotic drug effects on brain morphology in first-episode psychosis. Arch Gen Psychiatry 2005; 62: 361–70.Google Scholar
8 Lieberman, JA, Bymaster, FP, Meltzer, HY, Deutch, AY, Duncan, GE, Marx, CE, et al. Antipsychotic drugs: comparison in animal models of efficacy, neurotransmitter regulation, and neuroprotection. Pharmacol Rev 2008; 60: 358403.Google Scholar
9 Crespo-Facorro, B, Perez-Iglesias, R, Ramirez-Bonilla, M, Martinez-Garcia, O, Llorca, J, Vazquez-Barquero, JL. A practical clinical trial comparing haloperidol, risperidone, and olanzapine for the acute treatment of first-episode nonaffective psychosis. J Clin Psychiatry 2006; 67: 1511–21.Google Scholar
10 Emsley, RA. Risperidone in the treatment of first-episode psychotic patients: a double-blind multicenter study. Risperidone Working Group. Schizophr Bull 1999; 25: 721–9.CrossRefGoogle ScholarPubMed
11 Moller, HJ, Riedel, M, Jager, M, Wickelmaier, F, Maier, W, Kuhn, KU, et al. Short-term treatment with risperidone or haloperidol in first-episode schizophrenia: 8-week results of a randomized controlled trial within the German Research Network on Schizophrenia. Int J Neuropsychopharmacol 2008; 11: 985–97.Google Scholar
12 Lieberman, JA, Tollefson, G, Tohen, M, Green, AI, Gur, RE, Kahn, R, et al. Comparative efficacy and safety of atypical and conventional antipsychotic drugs in first-episode psychosis: a randomized, double-blind trial of olanzapine versus haloperidol. Am J Psychiatry 2003; 160: 1396–404.Google Scholar
13 Sanger, TM, Lieberman, JA, Tohen, M, Grundy, S, Beasley, C Jr, Tollefson, GD. Olanzapine versus haloperidol treatment in first-episode psychosis. Am J Psychiatry 1999; 156: 7987.CrossRefGoogle ScholarPubMed
14 Gaebel, W, Riesbeck, M, Wolwer, W, Klimke, A, Eickhoff, M, von Wilmsdorff, M, et al. Maintenance treatment with risperidone or low-dose haloperidol in first-episode schizophrenia: 1-year results of a randomized controlled trial within the German Research Network on Schizophrenia. J Clin Psychiatry 2007; 68: 1763–74.Google Scholar
15 Schooler, N, Rabinowitz, J, Davidson, M, Emsley, R, Harvey, PD, Kopala, L, et al. Risperidone and haloperidol in first-episode psychosis: a long-term randomized trial. Am J Psychiatry 2005; 162: 947–53.CrossRefGoogle ScholarPubMed
16 Green, AI, Lieberman, JA, Hamer, RM, Glick, ID, Gur, RE, Kahn, RS, et al. Olanzapine and haloperidol in first episode psychosis: two-year data. Schizophr Res 2006; 86: 234–43.Google Scholar
17 Kahn, RS, Fleischhacker, WW, Boter, H, Davidson, M, Vergouwe, Y, Keet, IP, et al. Effectiveness of antipsychotic drugs in first-episode schizophrenia and schizophreniform disorder: an open randomised clinical trial. Lancet 2008; 371: 1085–97.Google Scholar
18 Lieberman, JA, Stroup, TS, McEvoy, JP, Swartz, MS, Rosenheck, RA, Perkins, DO, et al. Effectiveness of antipsychotic drugs in patients with chronic schizophrenia. N Engl J Med 2005; 353: 1209–23.Google Scholar
19 Jones, PB, Barnes, TR, Davies, L, Dunn, G, Lloyd, H, Hayhurst, KP, et al. Randomized controlled trial of the effect on Quality of Life of second- vs first-generation antipsychotic drugs in schizophrenia: Cost Utility of the Latest Antipsychotic Drugs in Schizophrenia Study (CUtLASS 1). Arch Gen Psychiatry 2006; 63: 1079–87.Google Scholar
20 Kane, J, Honigfeld, G, Singer, J, Meltzer, H. Clozapine for the treatment-resistant schizophrenic. A double-blind comparison with chlorpromazine. Arch Gen Psychiatry 1988; 45: 789–96.Google Scholar
21 Sikich, L, Frazier, JA, McClellan, J, Findling, RL, Vitiello, B, Ritz, L, et al. Double-blind comparison of first- and second-generation antipsychotics in early-onset schizophrenia and schizo-affective disorder: findings from the treatment of early-onset schizophrenia spectrum disorders (TEOSS) study. Am J Psychiatry 2008; 165: 1420–31.Google Scholar
22 Leucht, S, Corves, C, Arbter, D, Engel, RR, Li, C, Davis, JM. Second-generation versus first-generation antipsychotic drugs for schizophrenia: a meta-analysis. Lancet 2009; 373: 3141.Google Scholar
23 Breier, A, Hamilton, SH. Comparative efficacy of olanzapine and haloperidol for patients with treatment-resistant schizophrenia. Biol Psychiatry 1999; 45: 403–11.Google Scholar
24 Tollefson, GD, Birkett, MA, Kiesler, GM, Wood, AJ. Double-blind comparison of olanzapine versus clozapine in schizophrenic patients clinically eligible for treatment with clozapine. Biol Psychiatry 2001; 49: 5263.Google Scholar
25 Lieberman, JA, Phillips, M, Gu, H, Stroup, S, Zhang, P, Kong, L, et al. Atypical and conventional antipsychotic drugs in treatment-naive first-episode schizophrenia: a 52-week randomized trial of clozapine vs chlorpromazine. Neuropsychopharmacology 2003; 28: 9951003.Google Scholar
26 Phillips, MR, Xiong, W, Zhao, ZA. Issues Involved in the Use of Scales for the Assessment of Negative and Positive Symptoms in Psychotic Patients [in Chinese]. Hubei Science and Technology Publishing House, 1990.Google Scholar
27 First, MB, Spitzer, RL, Gibbon, M, Williams, JBW. Structured Clinical Interview for DSM-IV Axis I Disorders, Clinician Version (SCID-CV). American Psychiatric Press, 1996.Google Scholar
28 Phillips, MR, Xiong, W, Wang, RW, Gao, YH, Wang, XQ, Zhang, NP. Reliability and validity of the Chinese versions of the Scales for Assessment of Positive and Negative Symptoms. Acta Psychiatr Scand 1991; 84: 364–70.Google Scholar
29 Guy, W. ECDEU Assessment Manual for Psychopharmacology. Revised DHEW Pub. (ADM). National Institute for Mental Health, 1976.Google Scholar
30 Jones, SH, Thornicroft, G, Coffey, M, Dunn, G. A brief mental health outcome scale – reliability and validity of the Global Assessment of Functioning (GAF). Br J Psychiatry 1995; 166: 654–9.Google Scholar
31 Simpson, GM, Angus, JW. A rating scale for extrapyramidal side effects. Acta Psychiatr Scand Suppl 1970; 212: 11–9.Google Scholar
32 Simpson, GM, Lee, JH, Zoubok, B, Gardos, G. A rating scale for tardive dyskinesia. Psychopharmacology (Berl) 1979; 64: 171–9.Google Scholar
33 Little, RJA, Rubin, DB. Statistical Analysis with Missing Data. John Wiley & Sons, 2002.Google Scholar
34 Agid, O, Remington, G, Kapur, S, Arenovich, T, Zipursky, RB. Early use of clozapine for poorly responding first-episode psychosis. J Clin Psychopharmacol 2007; 27: 369–73.Google Scholar
35 Gitlin, M, Nuechterlein, K, Subotnik, KL, Ventura, J, Mintz, J, Fogelson, DL, et al. Clinical outcome following neuroleptic discontinuation in patients with remitted recent-onset schizophrenia. Am J Psychiatry 2001; 158: 1835–42.CrossRefGoogle ScholarPubMed
36 Robinson, D, Woerner, MG, Alvir, JM, Bilder, R, Goldman, R, Geisler, S, et al. Predictors of relapse following response from a first episode of schizophrenia or schizoaffective disorder. Arch Gen Psychiatry 1999; 56: 241–7.Google Scholar
37 Szymanski, SR, Cannon, TD, Gallacher, F, Erwin, RJ, Gur, RE. Course of treatment response in first-episode and chronic schizophrenia. Am J Psychiatry 1996; 153: 519–25.Google Scholar
38 Lehman, AF, Lieberman, JA, Dixon, LB, McGlashan, TH, Miller, AL, Perkins, DO, et al. Practice guideline for the treatment of patients with schizophrenia, second edition. Am J Psychiatry 2004; 161: 156.Google ScholarPubMed
39 Penn, DL, Waldheter, EJ, Perkins, DO, Mueser, KT, Lieberman, JA. Psychosocial treatment for first-episode psychosis: a research update. Am J Psychiatry 2005; 162: 2220–32.Google Scholar
40 Kane, JM. Tardive dyskinesia rates with atypical antipsychotics in adults: prevalence and incidence. J Clin Psychiatry 2004; 65 (suppl 9): 1620.Google Scholar
41 Alvir, JM, Lieberman, JA, Safferman, AZ, Schwimmer, JL, Schaaf, JA. Clozapine-induced agranulocytosis. Incidence and risk factors in the United States. N Engl J Med 1993; 329: 162–7.CrossRefGoogle ScholarPubMed
42 Allison, DB, Mentore, JL, Heo, M, Chandler, LP, Cappelleri, JC, Infante, MC, et al. Antipsychotic-induced weight gain: a comprehensive research synthesis. Am J Psychiatry 1999; 156: 1686–96.Google Scholar
43 Newcomer, JW. Antipsychotic medications: metabolic and cardiovascular risk. J Clin Psychiatry. 2007; 68 (suppl 4): 813.Google Scholar
Figure 0

Fig. 1 Consort diagram.

Figure 1

Fig. 2 Kaplan–Meier survival curves for time to drop out from the study for the clozapine and chlorpromazine groups. There is no statistically significant difference between the two groups (P = 0.71).

Figure 2

Fig. 3 Kaplan–Meier survival curves for time to first discontinuation of the original study medication for the clozapine and chlorpromazine groups. There is a statistically significant advantage for clozapine (P = 0.01).

Figure 3

Fig. 4 Curves showing the per cent of individuals in the (a) clozapine and (b) chlorpromazine groups who were in the remission (solid line), intermediate (dashed line), or relapsed (dotted line) states throughout the 9-year study period. These curves are essentially identical.

Figure 4

Table 1 Efficacy comparisons (mean (s.d.)) between clozapine and chlorpromazine for the complete follow-up time period

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