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Metabolic profile of antipsychotic-naive individuals with non-affective psychosis

Published online by Cambridge University Press:  02 January 2018

Emilio Fernandez-Egea
Affiliation:
Schizophrenia Program, Department of Psychiatry, Neuroscience Institute, Hospital Clinic, Barcelona, Spain
Miguel Bernardo
Affiliation:
Schizophrenia Program, Department of Psychiatry, Neuroscience Institute, Hospital Clinic and Institute of Biomedical Research Agusti Pi i Sunyer (IDIBAPS), Barcelona, Spain
Thomas Donner
Affiliation:
Department of Internal Medicine, Division of Endocrinology, Diabetes and Nutrition, University of Maryland Baltimore, Baltimore, Maryland, USA
Ignacio Conget
Affiliation:
Endocrinology and Diabetes Section, Institute of Digestive and Metabolic Diseases, Hospital Clinic and Institute of Biomedical Research, Agusti Pi i Sunyer (IDIBAPS), Barcelona, Spain
Eduard Parellada
Affiliation:
Schizophrenia Program, Department of Psychiatry, Neuroscience Institute, Hospital Clinic and Institute of Biomedical Research Agusti Pi i Sunyer (IDIBAPS), Barcelona, Spain
Azucena Justicia
Affiliation:
Schizophrenia Program, Department of Psychiatry, Neuroscience Institute, Hospital Clinic, Barcelona, Spain
Enric Esmatjes
Affiliation:
Endocrinology and Diabetes Section, Institute of Digestive and Metabolic Diseases, Hospital Clinic and Institute of Biomedical Research, Agusti Pi i Sunyer (IDIBAPS), Barcelona, Spain
Clemente Garcia-Rizo
Affiliation:
Schizophrenia Program, Department of Psychiatry, Neuroscience Institute, Hospital Clinic, Barcelona, Spain
Brian Kirkpatrick*
Affiliation:
Department of Psychiatry and Health Behavior, Medical College of Georgia, Augusta, Georgia, USA
*
Brian Kirkpatrick, Department of Psychiatry and Health Behavior, Medical College of Georgia, 929 St. Sebastian Way, Augusta, GA 30912, USA. Email: [email protected]
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Abstract

Background

Some studies suggest individuals with schizophrenia have an increased risk of diabetes prior to antipsychotic use. Small sample sizes and the potential for confounding by hypercortisolaemia have decreased confidence in those results.

Aims

To examine diabetes-related factors in newly diagnosed, antipsychotic-naive people with non-affective psychosis.

Method

Participants with psychosis (the psychosis group; n = 50) and matched controls (the control group; n = 50) were given a 2 h oral glucose tolerance test. Fasting concentrations were also determined for adiponectin, interleukin-6 and C-reactive protein.

Results

Compared with the control group, the psychosis group had significant increases in 2 h glucose and interleukin-6 concentrations, and in the prevalence of abnormal glucose tolerance (16% of psychosis group v. 0% of control group). Adiponectin and C-reactive protein concentrations did not differ significantly between the two groups. These findings could not be attributed to differences in cortisol concentrations, smoking, gender, neighbourhood of residence, body mass index, aerobic conditioning, ethnicity, socioeconomic status or age.

Conclusions

Individuals with non-affective psychosis appear to have an increased prevalence of abnormal glucose tolerance prior to antipsychotic treatment, as well as abnormalities in a related inflammatory molecule. These underlying problems may contribute to the metabolic side-effects of antipsychotic medications.

Type
Papers
Copyright
Copyright © Royal College of Psychiatrists, 2009 

Schizophrenia is associated with a marked increase in mortality. Reference Saha, Chant and McGrath1 An increased suicide rate, poor healthcare, poor health habits and medication side-effects all contribute to this problem. Cardiovascular disease accounts for the greatest number of early deaths. Reference Osby, Correia, Brandt, Ekbom and Sparen2 Consistent with this picture, cardiovascular risk factors such as type 2 diabetes, dyslipidaemia, hypertension, smoking and obesity have a much higher prevalence in people with schizophrenia than in the general population. Reference McEvoy, Meyer, Goff, Nasrallah, Davis and Sullivan3,Reference Strassnig, Brar and Ganguli4

In recent years, the metabolic side-effects of antipsychotic medications have received a great deal of attention, as they increase the risk of diabetes, and perhaps hyperlipidaemia as well. 5 These problems in turn increase the mortality rate among people who take antipsychotic medications. However, individuals with schizophrenia may have an increased risk of diabetes independently of antipsychotic medications. Studies that antedate the use of modern antipsychotics found glucose abnormalities had an increased prevalence in people with schizophrenia, Reference Kohen6 although poor matching to controls and lack of clear diagnostic criteria weakened those studies. More recent studies of antipsychotic-naive individuals with non-affective psychosis also showed a higher prevalence of diabetes or impaired glucose tolerance (glucose blood levels ≥7.8 mmol/l (140 mg/dl) 2 h after ingesting 75 g of glucose) in a glucose tolerance test. These studies were limited by a small sample size; Reference Cohn, Remington, Zipursky, Azad, Connolly and Wolever7 a relative hypercortisolaemia in the individuals with psychosis, which may contribute to glucose intolerance; Reference Ryan, Collins and Thakore8 or a lack of matching for the potentially confounding factors of smoking and body mass index (BMI). Reference Spelman, Walsh, Sharifi, Collins and Thakore9 A study with a larger sample size Reference Arranz, Rosel, Ramírez, Dueñas, Fernàndez and Sanchez10 did not find a difference in glucose metabolism indices between participants with psychosis and controls, but the groups in that study were not well matched for age, smoking or BMI; moreover, in the same study, only fasting glucose values were assessed, rather than the results of a glucose tolerance test, which is more sensitive to glucose abnormalities. Reference Tai, Lim, Tan, Chew, Heng and Tan11

Given the limitations of the previous studies, the evidence is not conclusive that people with schizophrenia have an increased risk of diabetes independently of antipsychotic use. In addition, it is not known whether other abnormalities that are associated with diabetes are also present. These include increased inflammatory markers Reference Haffner12 and abnormalities in hormones associated with glucose metabolism, fat metabolism and inflammation. Reference Tilg and Moschen13

We hypothesised that antipsychotic-naive people with non-affective psychosis would have an increase in the prevalence of impaired glucose tolerance or diabetes when newly diagnosed, as well as abnormalities in other markers associated with an increased risk of diabetes: increases in interleukin-6 and C-reactive protein, and a decrease in adiponectin. We compared individuals with non-affective psychosis – that is, schizophrenia and related disorders – to healthy controls, as these disorders share clinical and genetic factors with schizophrenia, and most newly diagnosed individuals with these disorders receive a diagnosis of schizophrenia within the first year after first clinical contact. Reference Addington, Saeedi and Addington14

Method

Participants

People with psychosis (the psychosis group) were recruited at the time of their first clinical contact for psychotic symptoms at a general academic hospital (the Hospital Clinic of Barcelona). As part of the Spanish national health system, the hospital offers psychiatric services for all who live in the surrounding catchment area, Esquerra Eixample, in the city of Barcelona. Esquerra Eixample is a relatively homogeneous middle/upper-middle class neighbourhood in the centre of the city. Although it is also possible to seek private care outside of the assigned catchment area, the Hospital Clinic is a regional referral center for psychosis, and in a survey of 2968 admissions to the emergency department of a large general hospital in an adjoining catchment area, there were no individuals with psychosis from Esquerra Eixample.

The psychosis group had a maximum cumulative (lifetime) antipsychotic exposure of 1 week, and no antipsychotic use in the 30 days prior to the study. Participants with psychosis were allowed to receive anti-anxiety medication (lorazepam) the night before blood was drawn, to a maximum of 3 mg, but not on the day of assessment.

The healthy control group (the control group) were recruited using advertisements. We attempted to match the control group to the psychosis group on BMI, age, gender, smoking habit (average number of cigarettes per day), and residence in the catchment area (yes/no) of the Hospital Clinic. All of the participants were White residents of Spain except for one Asian and one North African person in each of the groups. The control group had no current or prior diagnosis of any Axis I DSM–IV 15 psychiatric disorder, after being assessed with the structured clinical interview for Axis I DSM–IV psychiatric disorders (SCID–I). Reference First, Spitzer, Blanch and Andreu16

Additional inclusion and exclusion criteria for all participants were: age from 18 to 64 years; no history of diabetes or other serious medical or neurological condition associated with glucose intolerance or insulin resistance (e.g. Cushing's disease); not taking a medication associated with insulin resistance (hydrochlorothiazide, furosemide, ethacrynic acid (available in the USA), metolazone, chlortalidone, beta blockers, glucocorticoids, phenytoin, nicotinic acid, ciclosporine, pentamidine or narcotics); no history of cocaine use in the previous 30 days; and have not previously received an antipsychotic or antidepressant medication. Additional exclusion criteria for the control group were no lifetime diagnosis of schizophrenia or major depressive disorder and no current diagnosis of adjustment disorder. All participants gave informed consent for participation in the study, which was conducted under the supervision of the institutional review boards of the authors' institutions.

Masked to glucose measures, individuals from the two groups that had been recruited were chosen in such a way to assure good matching as a group on gender, age, BMI and smoking habit, and to have an equal number of people in each group. This entailed omitting 6 people from the psychosis group, primarily because of a lower BMI, as well as 22 people in the control group, for purposes of matching.

A secondary, confirmatory analysis was also conducted in which all of the participants who had been recruited were included, and the matching variables were used as covariates.

Metabolic and psychiatric assessment

All participants were given a 2 h, 75 g oral glucose tolerance test, which began between 08.00 and 09.00 after an overnight fast. Fasting insulin, glycosylated haemoglobin (HbA1c), C-reactive protein, interleukin-6, adiponectin, and cortisol blood concentrations were also recorded. Adiponectin was recorded for 38 participants in the psychosis group and 48 in the control group, as it was included after the study began. Height, weight, and waist and hip circumference, when wearing underwear and without shoes, were recorded between the baseline and two blood samples.

Serum insulin concentrations were measured in duplicate by monoclonal immunoradiometric assay (Medgenix Diagnostics, Fleunes, Belgium). No cross-reaction with proinsulin was detected. Glycosylated haemoglobin (HbA1c) was determined by high-performance liquid chromatography (HA 8121, Menarini Diagnostici, Firenze, Italy; normal range 3.4–5.5%). Cortisol was measured using a radioimmunoassay (Immuchem, Ivoz-Ramet, Belgium). Body mass index was calculated using the formula (weight (kg)/height (m2)). Homoeostatic model assessments (HOMA) of steady state beta-cell function, insulin sensitivity and insulin resistance were calculated as percentages of a normal reference population of young people without diabetes. The HOMA calculator version 2.2 (www.dtu.ox.ac.uk) was used to calculate the HOMA indices.

Glucose tolerance was categorised according to American Diabetes Association guidelines:

  1. (a) normal tolerance was defined by a fasting plasma glucose concentration at baseline <5.6 mmol/l (100 mg/dl) and a 2 h concentration <7.8 mmol/l (140 mg/dl);

  2. (b) impaired fasting glucose was defined as glucose levels of 5.6–7.0 mmol/l (100–125 mg/dl) in fasting individuals;

  3. (c) impaired glucose tolerance was defined as 2 h glucose levels of 7.8–11.1 mmol/l (140–199 mg/dl) on the 75 g oral glucose tolerance test; and

  4. (d) a diagnosis of diabetes was defined by a fasting plasma glucose ≥7.0 mmol/l (126 mg/dl) or a 2 h glucose equal or greater to 11.1 mmol/l (200 mg/dl).

All participants were interviewed using the Spanish translation of the Structured Clinical Interview for DSM–IV Axis I disorders, clinician version (SCID–I). Reference First, Spitzer, Blanch and Andreu16 They were also administered the Dartmouth Assessment of Lifestyle Inventory, Reference Rosenberg, Drake, Wolford, Mueser, Oxman and Vidaver17 which quantifies substance misuse. Socioeconomic status of the family of origin was assessed with the Hollingshead–Rendlich scale. Reference Hollinshead and Rendlich18

Statistical analysis

The two matched groups were compared using the non-paired Student's t-test, or the χ2 test for comparisons of proportions. Significance was defined as P<0.05 for all statistical tests, and these were performed using SPSS version 12.0 for Windows.

Two multiple regression analyses were performed. In the first, the two matched groups (n=50 in each group) were included, whereas in the second analysis, all of the individuals who had been recruited (i.e. not only those in the two matched groups; n=56 people with psychosis and n=72 controls) were included. The dependent variable was glucose concentration at 2 h; the independent variables were diagnosis (individuals with psychosis v. controls as a 0/1 variable), age, gender, BMI, smoking (average number of cigarettes per day), residence in the catchment area (as a 0/1 variable), cortisol blood levels and socioeconomic status.

As interleukin-6 values were not normally distributed, we evaluated this variable as a category, with high or abnormal values defined as interleukin-6 >5 μ/ml and low or normal values <5 μ/ml. Reference Bremmer, Beekman, Deeg, Penninx, Dik and Hack19

Results

The psychosis group (n = 50) included 35 people with schizophrenia, 8 with schizophreniform disorder, 4 with brief psychotic disorder, 2 with delusional disorder and 1 with psychosis not otherwise specified; there were 50 people in the control group. The two groups were very similar with regard to demographics, BMI, smoking (which in our sample population was correlated with measures of misuse of other drugs, including alcohol; data not shown) and percentage living in the catchment area (Table 1). Socioeconomic status differed between the two groups, being lower for the psychosis group (mean 37.4 (s.d. = 15.5) v. mean 44.1 (s.d. = 14.2); P = 0.042).

Table 1 Characteristics of the psychosis and control groups

Psychosis group (n=50) Control group (n=50) Statisticsa
Age, years: mean (s.d.) 29.4 (8.8) 28.8 (7.7) t=0.391
Male:female 35:15 35:15 χ2=1.000
Body mass index, mean (s.d.) 22.9 (3.9) 23.9 (3.1) t=-1.483
Cigarettes per day, n: mean (s.d.) 8.5 (9.6) 7.2 (8.6) t=0.716
Residing in hospital catchment area, n (%) 35 (70.0) 32 (64.0) χ2=0.407
Waist:hip ratio, mean (s.d.) 0.87 (0.08) 0.84 (0.06) t=1.768
Heart rate, mean (s.d.) 77.4 (10.9) 75.1 (11.7) t=1.011

Glucose metabolism

Fasting measures of glucose metabolism were very similar for the two groups. Baseline glucose concentration were 4.55 mmol/l (s.d. = 0.66) (83 mg/dl (s.d. = 12.1)) for the psychosis group and 4.65 mmol/l (s.d. = 0.38) (84 mg/dl (s.d. = 6.9)) for the control group (P = 0.313). One individual with psychosis (fasting plasma glucose = 7.48 mmol/l (136 mg/dl)) and one person in the control group (fasting plasma glucose = 5.55 mmol/l (101 mg/dl)) did not have a normal fasting glucose. The values for fasting insulin were 10.3 mU/l (s.d. = 7.3) v. 9.6 mU/l (s.d. = 3.8) (P = 0.576), and the values for HbA1c were 4.4% (s.d. = 0.38) v. 4.5% (s.d. = 0.29) (P = 0.197). The homoeostasis model measures of insulin sensitivity, insulin release and insulin resistance were also not significantly different (P>0.26 for all three variables; Table 2).

Table 2 Metabolic measures in newly diagnosed, antipsychotic-naïve individuals with non-affective psychosis and the control group

Psychosis group (n=50) Control group (n=50) Statistics P
Fasting glucose
    mmol/l, mean (s.d.) 4.55 (0.66) 4.65 (0.38) t=-1.015 0.313
    mg/dl, mean (s.d.) 83 (12.1) 84 (6.9)
Fasting insulin, mU/l: mean (s.d.) 10.3 (7.3) 9.6 (3.8) t=0.644 0.576
% glycosylated haemoglobin, mean (s.d.) 4.4 (0.38) 4.5 (0.29) t=-1.298 0.197
HOMA-%B, mean (s.d.) 145.3 (44.5) 136.5 (32.1) t=1.014 0.262
HOMA-%S, mean (s.d.) 88.9 (45.0) 81.3 (28.7) t=1.014 0.313
Insulin resistance, mean (s.d.) 1.48 (1.08) 1.40 (0.56) t=0.509 0.612
2h glucose
    mmol/l, mean (s.d.) 6.10 (1.93) 4.49 (1.06) t=5.148 <0.001
    mg/dl, mean (s.d.) 111 (35.2) 82 (19.3)
Impaired glucose tolerance or diabetes, % 16 0 χ2=8.696 0.003
Cortisol, mg/dl: mean (s.d.) 19.0 (4.98) 20.2 (4.57) t=-1.269 0.208
Interleukin-6, g/ml: mean (s.d.) 3.63 (6.91) 1.02 (2.10) t=2.548 0.012
C-reactive protein, mg/l: mean (s.d.) 0.21 (0.28) 0.20 (0.18) t=0.209 0.835
Adiponectin,a mg/dl: mean (s.d.) 12.1 (5.9) 12.9 (5.6) t=-0.627 0.533

In contrast, 2 h glucose differed significantly (P<0.001) between the two groups: the psychosis group had a mean concentration of 6.10 mmol/l (s.d. = 1.93) (111 mg/dl (s.d. = 35.2)) whereas the control group had a mean of 4.49 mmol/l (s.d. = 1.06) (82 mg/dl (s.d. = 19.3)). Eight people with psychosis had impaired glucose tolerance (n = 7) or type 2 diabetes (n = 1), whereas none of the control group did (combined percentages, 16% v. 0% for the psychosis and control groups, respectively; P = 0.003).

In a multiple regression analysis, with 2 h glucose as the dependent variable and age, gender, smoking habit (average number of cigarettes per day), diagnosis, BMI, cortisol and socioeconomic status as the independent variables, diagnosis was significantly associated with 2 h glucose concentration (Table 3). Body mass index, and waist and hip ratio were correlated (r = 0.287, P = 0.004), and substituting waist:hip ratio for BMI gave the same pattern of results.

Table 3 Association between non-affective psychosis and increased 2 h glucose concentrations: confirmatory multiple regression

Standardised coefficients t-test P
Diagnosis (psychosis/control) -0.540 -5.799 <0.001
Average number cigarettes per day -0.240 -2.601 0.011
Age 0.118 1.228 0.223
Gender 0.011 0.116 0.908
Body mass index 0.266 2.600 0.011
Cortisol concentration 0.087 0.950 0.345
Socioeconomic status -0.079 -0.865 0.390
Catchment area -0.210 -2.320 0.023

The multiple regression analysis that included the whole sample showed similar results: diagnosis (P<0.0001) remained significant, as did smoking (P = 0.005), BMI (P = 0.004) and catchment area (P = 0.008); however, cortisol concentration, age, gender and socioeconomic status were not significant.

Inflammatory markers

Significantly more people in the psychosis group than in the control group had an abnormal interleukin-6 (23% v. 8%; P = 0.034); mean interleukin-6 blood levels were 3.63 (s.d. = 6.91) v. 1.02 (s.d. = 2.10) for the psychosis and control groups respectively. C-reactive protein was not significantly different between the groups (0.21 (s.d. = 0.28) v. 0.20 (s.d. = 0.18); P = 0.835). Cortisol blood levels were slightly lower in the psychosis group (19.0 (s.d. = 4.98) v. 20.2 (s.d. = 4.57)). Similar results were obtained using the whole sample (data not shown).

Adiponectin

Adiponectin did not differ significantly between the two groups; the concentrations were 12.1 mg/dl (s.d. = 5.9) in the psychosis group and 12.9 mg/dl (s.d. = 5.6) in the control group (P = 0.53). Multiple regression analysis of adiponectin, using gender, age, BMI, diagnosis, smoking habits and socioeconomic status failed to find statistically significant group differences (data not shown).

Discussion

We found that newly diagnosed antipsychotic-naive people with schizophrenia and related disorders had a higher prevalence of abnormal glucose tolerance or diabetes, and higher interleukin-6 blood concentrations, than did matched controls. These differences could not be attributed to confounding by BMI, gender, age, psychotropic medications, cortisol concentration, socioeconomic status, smoking, aerobic conditioning (as measured by resting heart rate) or drugs that affect glucose tolerance. In our primary analysis, the study sample was chosen from a larger data-set and some people were excluded; however, a multiple regression analysis of the entire sample showed a similar pattern of results.

Limitations

A limitation of this study was that we did not perform a formal evaluation of the diet of the participants, which influences both glucose and adiponectin levels. However, dietary differences seem unlikely to explain the higher glucose levels in the psychosis group, as they were slightly thinner than those in the control group, and glucose intolerance tends to increase with BMI. Moreover, the psychosis group did not appear to have a recent and substantial decrease in weight, an important cause of an increase in adiponectin, as adiponectin blood levels did not differ between the two groups. In addition, all of the participants came from Barcelona, and to the extent that diet was related to socioeconomic status, covarying for that variable did not change the pattern of our results. Socioeconomic status was lower in the psychosis group, but it is unlikely that this variable confounded these differences, as diagnosis was still significantly related to glucose concentration when socioeconomic status was included in the confirmatory multiple regression analysis.

Glucose abnormalities

Other studies have also found an increase in 2 h glucose concentrations in a glucose tolerance test and/or an increase in the prevalence of glucose intolerance defined categorically, in newly diagnosed, antipsychotic-naive people with schizophrenia. Reference Cohn, Remington, Zipursky, Azad, Connolly and Wolever7Reference Spelman, Walsh, Sharifi, Collins and Thakore9 In some studies, an abnormality was found in the glucose tolerance test Reference Spelman, Walsh, Sharifi, Collins and Thakore9 but none was found in either fasting glucose or HbA1C; Reference Spelman, Walsh, Sharifi, Collins and Thakore9,Reference Arranz, Rosel, Ramírez, Dueñas, Fernàndez and Sanchez10 there were limitations in these studies with regard to matching or hypercortisolaemia, as noted above. Studies in other populations have shown that the glucose tolerance test, which entails a physiological challenge, is a more sensitive measure of abnormalities in glucose metabolism. Reference Tai, Lim, Tan, Chew, Heng and Tan11

Inflammatory markers and adiponectin

Our finding of an increase in interleukin-6, which is associated with diabetes and risk of the subsequent development of diabetes, supports the conclusion that prior to antipsychotic treatment, people with schizophrenia have an increased risk of diabetes. Reference Kristiansen and Mandrup-Poulsen20 However, the other marker of inflammation that we examined, C-reactive protein, was not significantly greater in the psychosis group than in the control group. A recent meta-analysis by Potvin et al Reference Potvin, Stip, Sepehry, Gendron, Bah and Kouassi21 that compared more than 2000 people with chronic schizophrenia and controls also found an increase in interleukin-6 without an increase in C-reactive protein. Studies in other populations have also found that interleukin-6 may be a more sensitive marker of the inflammation associated with diabetes than is C-reactive protein. Reference Kristiansen and Mandrup-Poulsen20

We found no difference between the psychosis group and the control group in the concentration of adiponectin, which is also involved in glucose and fat metabolism. Reference Tilg and Moschen13 Two other studies have also failed to find a difference in adiponectin between newly diagnosed, antipsychotic-naive individuals and controls, Reference Ryan, Collins and Thakore8,Reference Arranz, Rosel, Ramírez, Dueñas, Fernàndez and Sanchez10 although one preliminary study did find a difference. Reference Cohn, Remington, Zipursky, Azad, Connolly and Wolever7 A study with a larger sample size might find an increase in C-reactive protein and/or other inflammatory markers. It is not known whether baseline measures will predict the metabolic side-effects of antipsychotic medications, nor is it yet clear whether newly diagnosed, antipsychotic-naive people with non-affective psychosis have abnormalities in lipids, as is often found in people with diabetes.

Diabetes and schizophrenia

Should an association between schizophrenia and glucose intolerance be confirmed, this might occur because diabetes and schizophrenia share some common risk factors and/or genetics. An increase in inflammatory markers has been reported in both schizophrenia and diabetes. Reference Kristiansen and Mandrup-Poulsen20 Some studies have also found an increased prevalence of family history of type 2 diabetes among relatives of people with psychosis Reference Arranz, Rosel, Ramírez, Dueñas, Fernàndez and Sanchez10,Reference Mukherjee, Schnur and Reddy22,Reference Fernandez-Egea, Miller, Bernardo, Donner and Kirkpatrick23 and two recent studies also found abnormal glucose tolerance among the first-degree relatives of schizophrenia probands. Reference Spelman, Walsh, Sharifi, Collins and Thakore9,Reference Fernandez-Egea, Bernardo, Parellada, Justica, Garcia-Rizo and Esmatjes24 Birth and gestational problems also appear to be risk factors for both schizophrenia and diabetes, low birth weight being the most notable example. Reference Kunugi, Nanko and Murray25Reference Wahlbeck, Forsen, Osmond, Barker and Eriksson28 Exposure to prenatal stress during the second or early third trimester of pregnancy appears to confer on the offspring an increased risk of developing schizophrenia later in life, a finding that is consistent with findings in animals. Reference Koenig, Kirkpatrick and Lee29 Prenatal stress and abnormal early development have also become the focus of research in diabetes and other aspects of the metabolic syndrome. Reference Ozanne, Fernandez-Twinn and Hales27,Reference Hales and Barker30,Reference Ravelli, van der Meulen, Michels, Osmond, Barker and Hales31

As a group, people with schizophrenia suffer premature death compared with the general population. No doubt, medication side-effects, an increased suicide rate, poor healthcare and poor health habits all make substantial contributions to this increased mortality. However, the existence of these factors does not exclude the possibility of a pre-existing vulnerability to glucose intolerance that is associated with a pro-inflammatory state. Our results and those of others Reference Cohn, Remington, Zipursky, Azad, Connolly and Wolever7Reference Spelman, Walsh, Sharifi, Collins and Thakore9,Reference Venkatasubramanian, Chittiprol, Neelakantachar, Naveen, Thirthall and Gangadhar32 suggest that even prior to antipsychotic treatment, schizophrenia is associated with metabolic abnormalities. The interaction of these problems with antipsychotics merits investigation.

Funding

Supported in part by grant RO1 DK069265 from the National Institute of Diabetes and Digestive and Kidney Diseases (B.K), NARSAD Young Investigator Award (E.F.-E.), and the Spanish Ministry of Health, Instituto de Salud Carlos III, CIBERSAM CB7/09/0005 and Catalonia Government DURSI 2005GR00223 (M.B.).

Footnotes

Declaration of interest

E.F.-E. received consulting fees and honoraria from Pfizer. T.D. received honoraria from Sanofi Aventis, Pfizer, Merck, Novartis and Amylin, and has received research grants from Eli Lilly. M.B. received consultant fees from Bristol-Myers Squibb and Wyeth, and honoraria from Janssen-Cilag, Eli Lilly, Pfizer, Synthelabo, GlaxoSmithKline and AstraZeneca. E.P. received research grants and consultant fees from Janssen-Cilag and GlaxoSmithKline, and served on the speakers/advisory boards for Janssen-Cilag. E.E. received consulting or speaking fees from Sanofi-Aventis, GlaxoSmithKline, Merck, Sharpe & Dohme, Servier, Bristol-Myers Squibb, Abbott and Novartis. I.C. received consulting or speaking fees from Sanofi-Aventis, GlaxoSmithKline, Merck, Sharpe & Dohme, Novartis, Bayer, Eli-Lilly. B.K. received consulting and/or speaking fees from Pfizer, Organon, AstraZeneca, Wyeth, Bristol-Myers Squibb, and Solvay.

References

1 Saha, S, Chant, D, McGrath, J. A systematic review of mortality in schizophrenia: is the differential mortality gap worsening over time? Arch Gen Psychiatry 2007; 64: 1123–31.CrossRefGoogle ScholarPubMed
2 Osby, U, Correia, N, Brandt, L, Ekbom, A, Sparen, P. Mortality and causes of death in schizophrenia in Stockholm county, Sweden. Schizophr Res 2000; 45: 21–8.Google Scholar
3 McEvoy, JP, Meyer, JM, Goff, DC, Nasrallah, HA, Davis, SM, Sullivan, L, et al. Prevalence of the metabolic syndrome in patients with schizophrenia: baseline results from the Clinical Antipsychotic Trials of Intervention Effectiveness (CATIE) schizophrenia trial and comparison with national estimates from NHANES III. Schizophr Res 2005; 80: 1932.CrossRefGoogle ScholarPubMed
4 Strassnig, M, Brar, JS, Ganguli, R. Increased caffeine and nicotine consumption in community-dwelling patients with schizophrenia. Schizophr Res 2006; 86: 269–75.CrossRefGoogle ScholarPubMed
5 American Diabetes Association, American Psychiatric Association, American Association of Clinical Endocrinologists, North American Association for the Study of Obesity. Consensus development conference on antipsychotic drugs and obesity and diabetes. J Clin Psychiatry 2004; 65: 267–72.Google Scholar
6 Kohen, D. Diabetes mellitus and schizophrenia: historical perspective. Br J Psychiatry 2004; 184 (suppl 47): s646.Google Scholar
7 Cohn, TA, Remington, G, Zipursky, RB, Azad, A, Connolly, P, Wolever, TM. Insulin resistance and adiponectin levels in drug-free patients with schizophrenia. A preliminary report. Can J Psychiatry 2006; 51: 382–6.CrossRefGoogle ScholarPubMed
8 Ryan, MC, Collins, P, Thakore, JH. Impaired fasting glucose tolerance in first-episode, drug-naïve patients with schizophrenia. Am J Psychiatry 2003; 160: 284–9.Google Scholar
9 Spelman, LM, Walsh, PI, Sharifi, N, Collins, P, Thakore, JH. Impaired glucose tolerance in first-episode drug-naïve patients with schizophrenia. Diabet Med 2007; 24: 481–5.CrossRefGoogle ScholarPubMed
10 Arranz, B, Rosel, P, Ramírez, N, Dueñas, R, Fernàndez, P, Sanchez, JM, et al. Insulin resistance and increased leptin concentrations in noncompliant schizophrenia patients but not in antipsychotic-naive first-episode schizophrenia patients. J Clin Psychiatry 2004; 65: 1335–42.CrossRefGoogle ScholarPubMed
11 Tai, ES, Lim, SC, Tan, BY, Chew, SK, Heng, D, Tan, CE. Screening for diabetes mellitus – a two-step approach in individuals with impaired fasting glucose improves detection of those at risk of complications. Diabet Med 2000; 17: 771–5.CrossRefGoogle ScholarPubMed
12 Haffner, SM. The metabolic syndrome: inflammation, diabetes mellitus, and cardiovascular disease. Am J Cardiol 2006; 97: 3A11A.CrossRefGoogle ScholarPubMed
13 Tilg, H, Moschen, AR. Adipocytokines: mediators linking adipose tissue, inflammation and immunity. Nat Rev Immunol 2006; 6: 772–83.CrossRefGoogle ScholarPubMed
14 Addington, J, Saeedi, H, Addington, D. The course of cognitive functioning in first episode psychosis: changes over time and impact on outcome. Schizophr Res 2005; 78: 3543.CrossRefGoogle ScholarPubMed
15 American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorder (4th edn) (DSM–IV). APA, 1994.Google Scholar
16 First, M, Spitzer, RL. SCID–I Structured Clinical Interview for the DSM–IV Axis I Disorders [Spanish] (trans. Blanch, J, Andreu, I). Masson, 1999.Google Scholar
17 Rosenberg, SD, Drake, RE, Wolford, GL, Mueser, KT, Oxman, TE, Vidaver, RM, et al. Dartmouth Assessment of Lifestyle Instrument (DALI): a substance use disorder screen for people with severe mental illness. Am J Psychiatry 1998; 155: 232–8.Google Scholar
18 Hollinshead, AB, Rendlich, S. Social Class and Mental Illness. John Wiley, 1958.CrossRefGoogle Scholar
19 Bremmer, MA, Beekman, AT, Deeg, DJ, Penninx, BW, Dik, MG, Hack, CE, et al. Inflammatory markers in late-life depression. Results from a population-based study. J Affect Disord 2008; 106: 249–55.CrossRefGoogle ScholarPubMed
20 Kristiansen, OP, Mandrup-Poulsen, T. Interleukin-6 and diabetes: the good, the bad, or the indifferent? Diabetes 2005; 54 (suppl 2): s11424.Google Scholar
21 Potvin, S, Stip, E, Sepehry, AA, Gendron, A, Bah, R, Kouassi, E. Inflammatory cytokine alterations in schizophrenia: a systematic quantitative review. Biol Psychiatry 2007; 13: 801–8.Google Scholar
22 Mukherjee, S, Schnur, DB, Reddy, R. Family history of type 2 diabetes in schizophrenic patients. Lancet 1989; 8636: 495.Google Scholar
23 Fernandez-Egea, E, Miller, B, Bernardo, M, Donner, T, Kirkpatrick, B. Parental history of type 2 diabetes in patients with nonaffective psychosis. Schizophr Res 2008; 98: 302–6.Google Scholar
24 Fernandez-Egea, E, Bernardo, M, Parellada, E, Justica, A, Garcia-Rizo, C, Esmatjes, E, et al. Glucose abnormalities in the siblings of people with schizophrenia. Schizophr Res 2008; 103: 110–3.Google Scholar
25 Kunugi, H, Nanko, S, Murray, RM. Obstetric complications and schizophrenia: prenatal underdevelopment and subsequent neurodevelopmental impairment. Br J Psychiatry 2001; 178 (suppl 40): s259.Google Scholar
26 Osmond, C, Barker, DJ. Fetal, infant, and childhood growth are predictors of coronary heart disease, diabetes, and hypertension in adult men and women. Environ Health Perspect 2000; 108: s54553.Google Scholar
27 Ozanne, SE, Fernandez-Twinn, D, Hales, CN. Fetal growth and adult diseases. Semin Perinatol 2004; 28: 81–7.CrossRefGoogle ScholarPubMed
28 Wahlbeck, K, Forsen, T, Osmond, C, Barker, DJ, Eriksson, JG. Association of schizophrenia with low maternal body mass index, small size at birth, and thinness during childhood. Arch Gen Psychiatry 2001; 58: 4852.CrossRefGoogle ScholarPubMed
29 Koenig, JI, Kirkpatrick, B, Lee, P. Glucocorticoid hormones and early brain development in schizophrenia. Neuropsychopharmacology 2002; 27: 309–18.Google Scholar
30 Hales, CN, Barker, DJ. The thrifty phenotype hypothesis. Br Med Bull 2001; 60: 520.CrossRefGoogle ScholarPubMed
31 Ravelli, AC, van der Meulen, JH, Michels, RP, Osmond, C, Barker, DJ, Hales, CN, et al. Glucose tolerance in adults after prenatal exposure to famine. Lancet 1998; 351: 173–7.Google Scholar
32 Venkatasubramanian, G, Chittiprol, S, Neelakantachar, N, Naveen, MN, Thirthall, J, Gangadhar, BN, et al. Insulin and insulin-like growth factor-1 abnormalities in antipsychotic-naive schizophrenia. Am J Psychiatry 2007; 164: 1557–60.Google Scholar
Figure 0

Table 1 Characteristics of the psychosis and control groups

Figure 1

Table 2 Metabolic measures in newly diagnosed, antipsychotic-naïve individuals with non-affective psychosis and the control group

Figure 2

Table 3 Association between non-affective psychosis and increased 2 h glucose concentrations: confirmatory multiple regression

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