Endogenous and Antipsychotic-Related Risks for Diabetes Mellitus in Young People With Schizophrenia: A Danish Population-Based Cohort Study

This population-based cohort study included people from the Danish Civil Registration System (39), which has recorded data on all Danish citizens since 1968. Each Danish citizen is assigned a unique 10-digit personal identification number at birth. This number is used in all Danish registries, enabling unambiguous linkage among them. The registration system provides data on gender, date of birth, date of death, date of migration, and parental identity. Our cohort included all people who were born in Denmark on or after Jan. 1, 1977. They were followed up until Jan. 1, 2013.

Information on diabetes was derived from the Danish National Patient Register (40) and the Danish National Prescription Registry (41). The Danish National Patient Register, established in 1977, collects data on all hospitalizations from nonpsychiatric hospitals, including dates of admission and discharge and discharge diagnoses, coded by the treating physicians according to the 8th revision of the International Classification of Diseases (ICD-8) (42) until the end of 1993 and the 10th revision (ICD-10) (43) thereafter. Since 1995, outpatient visits have also been recorded. We identified all hospital discharge diagnoses of diabetes. In ICD-8 these included codes 249 (insulin-dependent diabetes [type 1]) and 250 (non-insulin-dependent diabetes [type 2]). In ICD-10 these included codes E10 (brittle, juvenile, and ketoacidosis prone diabetes), E11 (adult-onset, maturity-onset, nonketotic, and stable diabetes), E12–14 (malnutrition, other specified and unspecified diabetes), H36.0 (diabetic retinopathy), and O24 (diabetes in pregnancy, childbirth, and puerperium) excluding O24.4 (gestational diabetes). Neither the ICD-8 nor ICD-10 provides specific codes for late-onset type 1 diabetes in adults or drug-induced diabetes. Because people with schizophrenia may develop type 2 diabetes at younger ages than the general population, and because the Danish registers include more frequent use of unspecified diabetes codes in people with schizophrenia, we examined the complete spectrum of ICD diabetes codes. Although using the Danish National Patient Register and Danish National Prescription Registry to identify people with diabetes has proven to yield high-quality and almost complete (44, 45) data, we cannot reliably distinguish type 1 and type 2 diabetes by using the registers (46, 47).

In addition to hospital contacts involving diabetes, we identified antidiabetic prescriptions from the Danish National Prescription Registry, because many people with diabetes are treated only in primary care. The prescription registry contains data from 1995 on all prescription drugs dispensed at all Danish pharmacies, and the information includes the Anatomical Therapeutic Chemical (ATC) classification system codes, dispensing dates, drug names, dose units, number of dose units in package, number of daily defined doses sold (48), and dispensing pharmacy codes. Antidiabetic drugs are available only by prescription in Denmark, so we identified all prescription redemptions for antidiabetic drugs (ATC code: A10). However, women with polycystic ovary syndrome may be treated with metformin (ATC code: A10BA02). Thus, to avoid inclusion of these nondiabetic people, we excluded all metformin prescriptions redeemed by women age 20 or more years in this cohort. Onset of diabetes was defined as the date of first admission with diabetes since birth or as the date of the first prescription for an antidiabetic drug since 1995 or later, whichever came first.

The Danish Psychiatric Central Research Register (49) was established as an electronic database in 1969 and has been recording data on all psychiatric admissions since 1969. Diagnoses in the Danish Psychiatric Central Research Register were coded in accordance with the ICD-8 (42) until the end of 1993 and ICD-10 (43) thereafter. This register includes data on all outpatient visits since 1995. We identified all hospital discharge diagnoses of schizophrenia (ICD-8: 295 [excluding 295.79] and ICD-10: F20). These diagnoses have been validated (50) and have contributed substantially to epidemiological research (49). As the data in the Danish National Prescription Registry have been complete only since 1995, we excluded all people (N=97) who developed schizophrenia before Jan. 1, 1996, to ensure that we had complete psychopharmacological data and at least 1 year of prescription use history for all people with schizophrenia after they had been diagnosed. Hence, we included all incident schizophrenia cases since Jan. 1, 1996.

We traced all oral and depot antipsychotic prescriptions (ATC code: N05A, excluding N05AN [lithium]) since 1995 using information from the Danish National Prescription Registry (48). The prescription registry is a powerful pharmacoepidemiological tool that provides complete high-quality data on all filled prescriptions for antipsychotics prescribed by various psychiatric departments, general practitioners, or other specialists after 1995. It does not record the drugs that are dispensed within hospitals. All Danish pharmacies are obliged to register all dispensed prescriptions, and they have a high economic incentive for completeness of prescription registration because of the universal reimbursement system for prescription drugs in Denmark. Antipsychotics were subdivided into first-generation antipsychotics, second-generation antipsychotics (ATC codes: N05AD03, N05AE03–4, N05AH04, N05AL01, N05AL05, N05AX08, and N05AX13), olanzapine, aripiprazole, and clozapine (see Appendix S1 in the data supplement accompanying the online version of this article).

We chose our covariates a priori on the basis of their availability, previous research associating them with diabetes or schizophrenia, and their influence on the prescribing pattern of antipsychotics. From the Danish National Prescription Registry, we identified other potentially diabetogenic psychotropic medications, such as tricyclic (ATC code: N06AA) and tetracyclic (ATC codes: N06AA21, N06AX03, N06AX11) antidepressants (36) and valproate (ATC code: N03AG01) (37, 38). Data on gender, urbanicity, and calendar period were derived from the Danish Civil Registration System and the Danish National Patient Register (40). Using the parental identity from the civil registration system, we identified siblings and half-siblings, and we linked them to the national patient register and prescription register to establish family history of diabetes.

We calculated age-specific and gender-specific incidence rates of diabetes and their 95% CIs. In order to investigate the endogenous risk for diabetes, we used Cox proportional hazards regression models to compute the adjusted hazard ratio for diabetes in antipsychotic-naive people with schizophrenia, compared with antipsychotic-naive people without schizophrenia. Follow-up began on the date of birth and ended on the date of diabetes diagnosis, first prescription of antipsychotics, emigration, or death or on Jan. 1, 2013. The first registered diagnosis of schizophrenia during follow-up was included as a time-dependent variable. Gender, family history of diabetes, urbanicity, and exposure to valproate and tricyclic or tetracyclic antidepressants were included as covariates.

We assessed antipsychotic-related risk for diabetes by including only people with schizophrenia who were antipsychotic naive at the time of their diagnosis. We employed Cox proportional hazard regression models estimating the adjusted hazard ratio by comparing the rates of diabetes in people with schizophrenia with and without antipsychotics. Follow-up began on the date of first diagnosis of schizophrenia and ended on the date of diabetes diagnosis, emigration, or death or on Jan. 1, 2013. Age was chosen as the time scale. Our Cox regression model included gender, family history of diabetes, and urbanicity as time-independent covariates and calendar period and daily defined doses of antipsychotics, valproate, and tricyclic or tetracyclic antidepressants as time-varying covariates. Moreover, we estimated adjusted hazard ratios and their 95% CIs that compared the risks for diabetes before and after starting selected antipsychotics in people with schizophrenia. Furthermore, we performed sensitivity analyses that followed the patients until their first type 2 diabetes contact (ICD-8: 250; ICD-10: E11, O24.1) and/or oral antidiabetic drug (ATC code: A10B), ignoring any previous contacts due to type 1 diabetes or insulin prescriptions. We tested the proportional hazards assumption by repeating the Cox regression models and including the primary independent variable as one of the time-varying covariates, and we did not find any violations. All analyses were performed by using the statistical software STATA 13.1 (StataCorp, College Station, Tex.).

We followed 2,736,510 young people for a total of 49,582,279 person-years. The median duration of follow-up was 18.80 years (interquartile range, 16.99 years). The maximum period of follow-up was 35.96 years; thus, the oldest person in our cohort was less than 36 years old. A total of 8,945 (0.33%) people developed schizophrenia during follow-up. The mean duration of follow-up after the diagnosis of schizophrenia was 5.07 (SD=4.24) years, and the mean duration of follow-up after the first antipsychotic drug prescription was 6.40 (SD=4.34) years. Table 1 presents the sociodemographic and clinical characteristics of our cohort. People with schizophrenia were significantly more likely to have a family history of diabetes than other people (χ²>1300, df=1, p<0.001).

A total of 14,118 (0.52%) people developed diabetes in this cohort (see Figure S1 in the online data supplement). Age-specific incidence rates of diabetes in people with and without schizophrenia are presented in Table 2 (see also Figure S2 in the supplemental data). Gender-specific incidence rates of diabetes for men and women without schizophrenia were 0.26 (95% CI, 0.26–0.27) and 0.30 (95% CI, 0.29–0.31) per 1,000 person-years, respectively. Gender-specific incidence rates of diabetes for men and women with schizophrenia were 4.02 (95% CI, 3.35–4.83) and 4.69 (95% CI, 3.81–5.77) per 1,000 person-years, respectively.

Among the people who were not exposed to any antipsychotics, 12,976 (0.5%) without schizophrenia and 11 (0.9%) with schizophrenia developed incident diabetes during our follow-up. Table 3 presents the incidence rates and the adjusted hazard ratios for diabetes in antipsychotic-naive people with schizophrenia. Family history of diabetes significantly increased the risk of diabetes (adjusted hazard ratio, 3.96; 95% CI, 3.82–4.11). People with schizophrenia had a higher incidence rate of diabetes, and they had an approximately threefold higher risk of diabetes (adjusted hazard ratio, 3.07; 95% CI, 1.71–5.41), compared with people without schizophrenia, after adjustment for the effects of potential confounders, including family history of diabetes.

A total of 4,322 (48.3%) people with schizophrenia were antipsychotic naive at the time of their diagnosis, and the remaining 4,623 (51.7%) had received an antipsychotic drug before schizophrenia was diagnosed. A total of 83 (1.9%) people with schizophrenia who were antipsychotic naive at diagnosis developed diabetes during follow-up. Gender-specific incidence rates of diabetes for antipsychotic-treated men and women with schizophrenia were 4.22 (95% CI, 3.17–5.62), and 3.33 (95% CI, 2.23–4.96) per 1,000 person-years, respectively. Table 4 presents the incidence rates and the adjusted hazard ratios for diabetes in people with schizophrenia, comparing their risks before and after they started treatment with selected antipsychotics. The rate for diabetes significantly increased by more than threefold (adjusted hazard ratio, 3.64; 95% CI, 1.95–6.82) in people with schizophrenia after starting any antipsychotic, compared with their rate before receiving antipsychotics, when the analysis accounted for the effects of potential confounders, including family history of diabetes.

Compared with the people with schizophrenia who remained antipsychotic naive until the end of follow-up, those with schizophrenia who received monotherapy with either first-generation antipsychotics (adjusted hazard ratio, 3.06; 95% CI, 1.32–7.05) or second-generation antipsychotics (except clozapine) (adjusted hazard ratio, 3.44; 95% CI, 1.73–6.83) as their first-line treatment had significantly higher antipsychotic-related rates for diabetes after adjustment for the effects of potential confounders, including family history of diabetes. The first-line therapeutic decision of choosing between first-generation and second-generation antipsychotics did not make a statistically significant difference (χ²=0.13, df=1, p=0.72) in the rate for diabetes in people with schizophrenia. We repeated these analyses after excluding olanzapine from the class of second-generation antipsychotics and confirmed the earlier findings.

Starting either olanzapine (adjusted hazard ratio, 1.88; 95% CI, 1.36–2.59) or aripiprazole (adjusted hazard ratio, 2.35; 95% CI, 1.70–3.26) significantly increased the rate of diabetes by almost twofold in people with schizophrenia, after adjustment for the effects of potential confounders. We repeated these analyses including the duration of antipsychotic treatment before the start of either olanzapine (adjusted hazard ratio, 1.91; 95% CI, 1.37–2.65) or aripiprazole (adjusted hazard ratio, 1.69; 95% CI, 1.19–2.39) in the models and confirmed the earlier findings. Among 861 (9.6%) people with schizophrenia who received clozapine after their diagnosis, 39 (0.4%) developed incident diabetes after starting clozapine. Treatment with clozapine significantly increased the rate of diabetes by nearly fourfold (adjusted hazard ratio, 3.98; 95% CI, 2.77–5.73) in people with schizophrenia, compared with people with schizophrenia not receiving clozapine, when the analysis accounted for the potential confounders, including the family history of diabetes (see Appendix S5 in the online data supplement).

We conducted sensitivity analyses limited to potential type 2 diabetes diagnoses in this cohort (N=5,488, 0.20%) and confirmed the earlier findings of a higher rate of diabetes in antipsychotic-naive people with schizophrenia compared with the general population (adjusted hazard ratio, 4.71; 95% CI, 2.60–8.51) and an increased rate of diabetes after the start of any antipsychotic drug in people with schizophrenia (adjusted hazard ratio, 3.79; 95% CI, 1.97–7.26) without statistically significant differences between first-generation and second-generation antipsychotics (χ²=0.04, df=1, p=0.85) (see Appendixes S2, S3, and S5 in the online data supplement). We performed more sensitivity analyses after excluding 19 people who developed diabetes more than 12 months after the last prescription for any antipsychotic, to distinguish direct antipsychotic effects from the potential effects of antipsychotic-related weight gain. The results of this sensitivity analysis also corroborated our earlier findings. The antipsychotic-related risk for diabetes after starting any antipsychotic was significantly higher (adjusted hazard ratio, 3.28; 95% CI, 1.74–6.17) than the risk in people with schizophrenia not treated with antipsychotics, and the first-line therapeutic decision of treatment with either first-generation or second-generation antipsychotic monotherapy did not make a statistically significant difference (χ²=0.78, df=1, p=0.38). Moreover, we performed sensitivity analyses by including women ages 20 or more years receiving treatment only with metformin (N=8,551). We confirmed our findings of endogenous risk of diabetes in antipsychotic-naive schizophrenia (adjusted hazard ratio, 2.10; 95% CI, 1.30–3.38) and increased rate of diabetes after the start of any antipsychotic drug in people with schizophrenia (adjusted hazard ratio, 3.56; 95% CI, 2.09–6.06) without a statistically significant difference (χ²=2.03, df=1, p=0.15) between the first-line therapeutic decision of treatment with either first-generation antipsychotics (adjusted hazard ratio, 4.27; 95% CI, 2.21–8.27) or second-generation antipsychotics (adjusted hazard ratio, 2.98; 95% CI, 1.67–5.32) monotherapy.