The fact that mental disorders are associated with high societal burden is now well established both in terms of disability-adjusted life-years Reference Murray and Lopez1 and as a fraction of national budgets. Reference Gabriel and Liimatainen2 A large part of this burden consists of indirect costs such as those associated with reduced rates of labour force participation, Reference Zhang, Zhao and Harris3 unemployment among those in the labour force Reference Chatterji, Alegria, Lu and Takeuchi4 and underemployment among those who are employed. Reference Kessler, Heeringa, Lakoma, Petukhova, Rupp and Schoenbaum5 Mental disorders also have costs for employers, including high rates of sporadic absenteeism Reference Kessler and Frank6 and disability-related work leave Reference Kessler, Barber, Birnbaum, Frank, Greenberg and Rose7 as well as low levels of on-the-job work performance. Reference Berndt, Finkelstein, Greenberg, Howland, Keith and Rush8 The most commonly used approach to study these labour market costs is the human capital approach. Reference Tarricone9 This approach is based on the observation that wages and salaries are paid in direct return for productive services, making earnings a good indicator of the human capital accumulated by the individual and making earnings-equivalent time forgone because of an illness a good representation of the indirect costs of that illness to the employer. Although a considerable body of empirical research has used the human capital approach to document adverse societal effects of mental disorders, this research has been carried out largely in a small number of high-income countries. Reference Chatterji, Alegria, Lu and Takeuchi4,Reference Kessler, Barber, Birnbaum, Frank, Greenberg and Rose7 Yet epidemiological data show that mental disorders are common throughout the world. Reference Kessler, Aguilar-Gaxiola, Alonso, Angermeyer, Anthony, Brugha, Kessler and Üstün10 The purpose of the current paper is to use the survey data in the World Health Organization (WHO) World Mental Health (WMH) Surveys to make estimates of the human capital costs of mental disorders in a wider range of countries (population samples from 10 high-income and 9 low- and middle-income countries with a total of more than 100 000 respondents). We focus on serious mental illness because previous research has shown that earnings and long-term work incapacity are both much more strongly related to serious mental illness than to less serious forms of mental illness. Reference Kessler, Heeringa, Lakoma, Petukhova, Rupp and Schoenbaum5,Reference Shiels, Gabbay and Ford11
Method
Sample
Twenty surveys were carried out in 19 countries in the Americas (Brazil, Colombia, Mexico, USA), Europe (Belgium, Bulgaria, France, Germany, Italy, The Netherlands, Spain), the Middle East (Israel, Lebanon), Africa (Nigeria, South Africa), Asia (Japan, People's Republic of China: Beijing, Shanghai, Shenzhen, India: Pondicherry), and New Zealand (online Table DS1). The World Bank 12 classifies Brazil, Bulgaria, Colombia, India, Lebanon, Mexico, Nigeria, the People's Republic of China, and South Africa as low- and middle-income countries, and all the other surveyed countries as high-income countries. All surveys were based on either multistage clustered area probability samples of households, with one or two random respondents selected in each sample household, or multistage clustered area probability samples of individuals listed in a national population register. All interviews were carried out face to face by trained lay interviewers.
Recruitment began with a letter sent to the households of potential respondents describing the purpose of the study and answering commonly asked questions about how their household was selected, the voluntary nature of participation and the confidentiality of responses. Interviewers reviewed these issues with the potential respondents when they visited the households and obtained informed consent before beginning the interviews. Standard procedures for recording and storing the survey data in de-identified files were used to protect the confidentiality of respondents. A respondent safety plan was developed separately in each country consistent with local norms to address concerns about evidence of respondent danger to self or others. These recruitment, consent and respondent protection procedures were approved by the Human Subjects Committee of the lead organisation that carried out the survey in each country.
The total sample size was 101 825, with individual country sample sizes ranging from a low of 2372 in The Netherlands to a high of 12 992 in New Zealand. The weighted average response rate across countries was 72.2%. Internal subsampling was used to reduce respondent burden by dividing the interview into two parts. Part I included the core diagnostic assessment of mental disorders. Part II included a detailed risk-factor questionnaire, a series of diagnoses of secondary interest, and a series of questions about the correlates of mental illness. Earnings were assessed in Part II. All respondents completed Part I (n = 101 825), and all respondents who met criteria for any Part I mental disorder plus a probability sample of other Part I respondents were administered Part II (n = 51 007). (All respondents were administered Part II in Israel and South Africa.) The Part I data were weighted to adjust for differential probabilities of selection and for the undersampling of hard-to-reach respondents (a probability subsample of whom received special intensive recruitment efforts). The Part II data were additionally weighted to adjust for the undersampling of Part I respondents without a core disorder (i.e. weighting by the inverse of probability of selection into Part II) to remove any bias in Part II relative to Part I. A final Part II was weight adjusted for discrepancies between the sample distributions and the population census on a wide range of sociodemographic and geographic variables. The analyses reported here were based on the respondents in the weighted Part II sample who were of working age, which we defined for purposes of this analysis as 18–64 years of age (n = 44 561). A more detailed description of WMH sampling that includes an analysis of the effects of weights and weight trimming is presented elsewhere. Reference Heeringa, Wells, Hubbard, Mneimneh, Chiu, Sampson, Kessler and Üstün13
Interviewer training and fieldwork quality control
Each WMH interviewer was required to complete a 7-day training course and to pass an examination that included administering a series of practice interviews with scripted responses before beginning production work. During production, supervisors reviewed all interviews for completeness and made follow-up contacts with a random 5–10% of respondents to confirm household addresses, household enumeration, random selection procedures and the length of the interview. Supervisors repeated a random sample of questions during these interview audits in order to make sure interviewers administered the complete interview and that responses were recorded accurately. In addition, aggregate interviewer-level data were monitored on an ongoing basis to look for distinctive interviewer-specific data patterns that might indicate fabrication of data. A more detailed discussion of interviewer training and field quality-control procedures is presented elsewhere. Reference Pennell, Mneimneh, Bowers, Chardoul, Wells, Viana, Kessler and Üstün14
Measures
Mental illness
All surveys assessed mental illness with the WHO Composite International Diagnostic Interview (CIDI), Reference Kessler and Üstün15 a fully-structured diagnostic interview that assesses the prevalence of mental disorders according to the definitions and criteria of both the DSM–IV 16 and ICD–10 17 diagnostic systems. The DSM–IV criteria were used in the current report. We focused on prevalence at any time within the 12 months before the interview. The disorders considered include anxiety disorders (generalised anxiety disorder, panic disorder, phobias, post-traumatic stress disorder) and mood disorders (major depressive disorder, dysthymic disorder, bipolar disorder). In making diagnosis, CIDI organic exclusion rules were imposed. Clinical reappraisal studies carried out in conjunction with a number of WMH surveys using the Structured Clinical Interview for DSM–IV Reference First, Spitzer, Gibbon and Williams18 as the gold standard documented generally good concordance of masked clinical diagnoses with diagnoses based on the CIDI. Serious mental illness was defined following previous WMH analyses Reference Demyttenaere, Bruffaerts, Posada-Villa, Gasquet, Kovess and Lepine19 as either meeting criteria for bipolar I disorder or having any other 12-month diagnosis with evidence of serious role impairment. Serious role impairment was defined as either having a score in the severe range on one or more of the Sheehan Disability Scales, Reference Leon, Olfson, Portera, Farber and Sheehan20 which assess disability in work-role performance, household maintenance, social life or intimate relationships or attempting suicide. The CIDI also assessed DSM–IV alcohol and illicit drug use with or without dependence. Both lifetime prevalence of these conditions and prevalence in the 12 months before the interview were used as controls to adjust for comorbidity between mental and substance disorders. Other 12-month disorders that did not meet criteria for serious mental illness were not considered because preliminary analysis found that they are not significantly related to earnings. (Detailed results are available from the authors on request.)
Earnings
All Part II respondents were asked to report their personal earnings in the past 12 months before taxes. Respondents were instructed to count only wages and other stipends from employment, not pensions, investments or other financial assistance or income. As in most community surveys, the item-level non-response rate for this question was non-trivial (with a range of 0.8–18.3% and an interquartile range of 2.2–7.0% across surveys). Mean imputation was used to impute missing values. It is noteworthy that serious mental illness was not significantly related to having a missing value on the earnings variable either in high- or low- and middle-income countries (χ2(1) = 0.1–3.1, P = 0.08–0.71). This means that the decision about how to deal with these missing values (i.e. either by case deletion, imputation or introducing a control variable for having a missing value on this variable into the regression equations) would not meaningfully influence the magnitude of the serious mental illness coefficients in the regression analyses reported below.
Analysis methods
In order to facilitate pooling of results across countries, earnings reports were divided by the median earnings in the country. These transformed scores were then used as outcomes in pooled regression analyses estimated simultaneously across all countries. Prior to carrying out this analysis, earnings distributions were compared for respondents with and without serious mental illness. The earnings distributions among respondents with any earnings were divided for this purpose into four categories by defining low earnings as less than half the within-country median, low–average earnings as up to the median, high–average earnings as up to twice the median, and high earnings as greater than two times the median.
The regression analyses were then carried out using a dummy variable for serious mental illness as the predictor of primary interest. The outcome was the transformed continuous earnings score. Control variables were included for sociodemographics (age, gender), country (19 dummy variables to distinguish respondents across the 20 surveys), substance disorders and interactions between gender and all other predictors. The gender interactions were included because previous research has shown that the predictors of earnings are different for males than females. Reference Kessler, Heeringa, Lakoma, Petukhova, Rupp and Schoenbaum5,Reference Rice and Miller21
A major statistical problem in estimating regression equations of this sort is that the earnings distribution is highly skewed, with a meaningful minority of the sample in each country reporting no earnings and a much higher proportion of other respondents having high earnings than would be found in a normal distribution. This makes ordinary least squares regression analysis both biased and inefficient. Economists have developed special statistical procedures to address this problem that involve using either two-part models (i.e. a first logistic regression model to predict having any earnings and a second linear regression model to predict amount of earnings among those with any earnings) Reference Duan, Manning, Morris and Newhouse22,Reference Manning23 or special one-part non-linear models. Reference Manning and Mullahy24,Reference McCullagh and Nelder25 We used both approaches in addition to conventional ordinary least squares regression analysis (with linear, square root and logarithmic link functions) and selected the best approach based on standard empirical model comparison procedures. Reference Buntin and Zaslavsky26 The details of the modelling approaches are discussed elsewhere, Reference Kessler, Heeringa, Lakoma, Petukhova, Rupp and Schoenbaum5 but the final best-fitting model was a one-part generalised linear model that assumed a logarithmic link function between predictors and the outcome with prediction error variance proportional to the predicted values.
As the best-fitting model used a non-linear transformation of the outcome in conjunction with an interaction between serious mental illness and gender, model-based simulation was needed to interpret the coefficients. This was done by predicting earnings twice for each respondent from the model coefficients, once using the actual characteristics of the respondent and a second time recoding all respondents with serious mental illness to assume that they did not have serious mental illness. Individual-level differences between these estimates were averaged across all respondents with serious mental illness to estimate the mean individual-level decrease in earnings associated with serious mental illness. Societal-level estimates were then obtained by multiplying this individual-level estimate by the prevalence of serious mental illness. Demographic rate standardisation Reference Schempf and Becker27 was then used to decompose the societal-level estimates into components due to the associations of serious mental illness with probability of having any earnings and with the amount earned by those with any earnings. Because the WMH sample design featured weighting and clustering, the standard errors of the model coefficients and the simulated estimates were obtained using the design-based jackknife repeated replications method. Reference Wolter28 In this method, each model and each simulation is replicated many times in pseudo-samples to generate a distribution of each coefficient that is then used to calculate an empirical estimate of the standard error of the coefficient. Multivariate significance was estimated using design-adjusted Wald χ2-tests. Reference Engle, Griliches and Intriligator29 Statistical significance was consistently evaluated using two-sided tests at the 0.05 level of significance.
Results
Sample distributions
Consistent with their population distributions, the age distribution of the sample is different in high-income countries from that in low- and middle-income countries (χ2(3) = 553.1, P<0.001) (Table 1). Larger proportions of respondents are in the age ranges 18–24 (24.5% v. 15.6%) and 25–39 (40.8% v. 35.0%) in low- and middle-income than high-income countries, whereas larger proportions are in the age ranges 40–54 (34.0% v. 24.8%) and 55–64 (15.4% v. 10.0%) in high-income than low- and middle-income countries. Females have a somewhat older age distribution than males in low- and middle-income countries (χ2(3) = 9.2, P = 0.026), but there is no gender difference in the age distribution in high-income countries (χ2(3) = 1.3, P = 0.74). Serious mental illness is estimated to be significantly more prevalent in high-income than low- and middle-income countries both in the total sample (4.3% v. 3.0%, t = 6.4, P<0.001) and separately among males (3.5% v. 2.2%, t = 5.1, P<0.001) and females (5.0% v. 3.9%, t = 4.3, P<0.001) (Table 1). Serious mental illness is estimated to be significantly more common among females than males in both high-income and low- and middle-income countries (t = 6.1–6.6, P<0.001).
% (s.e.) | ||||||
---|---|---|---|---|---|---|
High-income countries | Low- and middle-income countries | |||||
Total (n = 23457) | Male (n = 10 114) | Female (n = 13 343) | Total (n = 21 104) | Male (n = 9040) | Female (n = 12 064) | |
Age, yearsb | ||||||
18–24 | 15.6 (0.4) | 16.0 (0.5) | 15.3 (0.5) | 24.5 (0.4) | 24.6 (0.7) | 24.5 (0.6) |
25–39 | 35.0 (0.5) | 34.7 (0.6) | 35.2 (0.6) | 40.8 (0.5) | 41.3 (0.7) | 40.2 (0.6) |
40–54 | 34.0 (0.4) | 34.0 (0.6) | 34.0 (0.6) | 24.8 (0.4) | 25.1 (0.6) | 24.4 (0.5) |
55–64 | 15.4 (0.3) | 15.3 (0.5) | 15.5 (0.4) | 10.0 (0.3) | 9.1 (0.4) | 10.8 (0.4) |
12-month serious mental illnessc | 4.3 (0.1) | 3.5 (0.2) | 5.0 (0.2) | 3.0 (0.1) | 2.2 (0.2) | 3.9 (0.2) |
Earnings distributions among respondents with and without serious mental illness
The proportion of respondents with non-zero earnings is significantly lower among those with than those without serious mental illness in both high-income (61.9% v. 75.6%, t = 8.6, P<0.001) and low- and middle-income (51.6% v. 63.1%, t = 5.9, P<0.001) countries (Table 2). Similar differences are found when we look separately at males (t = 4.8–2.8, P≤0.001–0.005) and females (t = 5.9–3.2, P≤0.001). These overall differences are because of the proportions of respondents with low and low–average earnings being significantly higher among those with than those without serious mental illness in both high-income (40.4% v. 23.8%, t = 9.0, P<0.001 low earnings; 25.1% v. 20.5%, t = 2.8, P = 0.005 low–average earnings) and low- and middle-income (low–average only; 45.6% v. 32.7%, t = 4.4, P<0.001) countries and the proportions of respondents with high–average and high incomes being significantly higher among those without than those with serious mental illness in both high-income (28.5% v. 21.9%, t = 3.7, P<0.001 high–average earnings; 27.3% v. 12.7%, t = 11.2, P<0.001 high earnings) and low- and middle-income (15.8% v. 11.6%, t = 2.5, P = 0.013 high–average earnings; 25.8% v. 18.9%, t = 3.8, P<0.001 high earnings) countries. Similar patterns are found when we look separately at men and women.
High-income countries | Low- and middle-income countries | |||||
---|---|---|---|---|---|---|
Total (n = 23 457) | Male (n = 10 114) | Female (n = 13 343) | Total (n = 21 104) | Male (n = 9040) | Female (n = 12 064) | |
Any earnings, % (s.e.) | ||||||
Total sample | 75.0 (0.4) | 82.6 (0.6) | 67.7 (0.6) | 62.8 (0.5) | 72.9 (0.7) | 53.3 (0.6) |
Serious mental illness | 61.9* (1.6) | 70.6* (2.6) | 56.2* (2.0) | 51.6 (1.9) | 62.9*,† (3.6) | 45.6*,† (2.4) |
Others | 75.6* (0.4) | 83.1* (2.6) | 68.3* (0.6) | 63.1 (0.5) | 73.1*,† (0.7) | 53.6*,† (0.6) |
Low earnings among the employed, % (s.e.) | ||||||
Total sample | 24.3 (0.5) | 16.8 (0.6) | 33.2 (0.8) | 25.7 (0.6) | 23.0 (0.8) | 29.0 (0.9) |
Serious mental illness | 40.4* (1.8) | 34.6* (3.0) | 45.2* (2.2) | 23.9 (2.5) | 22.2 (3.9) | 25.1 (3.0) |
Others | 23.8* (0.5) | 16.3* (0.6) | 32.7* (0.8) | 25.7 (0.6) | 23.0 (0.8) | 29.2 (0.9) |
Low-average earnings among the employed, % (s.e.) | ||||||
Total sample | 20.6 (0.5) | 16.0 (0.6) | 26.0 (0.7) | 33.0 (0.7) | 30.1 (0.8) | 36.8 (1.0) |
Serious mental illness | 25.1* (1.6) | 21.0* (2.5) | 28.4 (2.1) | 45.6* (3.0) | 39.1*,† (4.1) | 50.4*,† (3.9) |
Others | 20.5* (0.5) | 15.9* (0.6) | 25.9 (0.7) | 32.7* (0.7) | 29.9*,† (0.8) | 36.3*,† (1.0) |
High-average earnings among the employed, % (s.e.) | ||||||
Total sample | 28.2 (0.5) | 29.2 (0.7) | 27.1 (0.7) | 15.7 (0.5) | 16.2 (0.6) | 15.0 (0.7) |
Serious mental illness | 21.9* (1.7) | 25.7 (2.8) | 18.8* (1.8) | 11.6* (1.6) | 13.8 (3.1) | 10.0*,† (2.2) |
Others | 28.5* (0.5) | 29.3 (0.7) | 27.4* (0.7) | 15.8* (0.5) | 16.3 (0.7) | 15.2*,† (0.7) |
High earnings among the employed, % (s.e.) | ||||||
Total sample | 26.8 (0.5) | 37.9 (0.8) | 13.8 (0.5) | 25.6 (0.6) | 30.7 (0.8) | 19.1 (0.7) |
Serious mental illness | 12.7* (1.2) | 18.8* (2.2) | 7.6* (1.2) | 18.9* (1.7) | 24.9*,† (2.7) | 14.5* (2.2) |
Others | 27.3* (0.5) | 38.5* (0.8) | 14.1* (0.5) | 25.8* (0.6) | 30.8*,† (0.8) | 19.3* (0.8) |
χ2(3) | 141.2† | 76.0† | 47.9† | 28.8† | 6.2 | 16.9† |
Individual-level regression models of the association between serious mental illness and earnings
The model-based simulations estimate that serious mental illness is associated with a reduction in earnings equal to 32% of the median within-country earnings in high-income countries and 33% of median within-country earnings in low- and middle-income countries (Table 3). The association is considerably larger among men than women in high-income countries (53% v. 19%, t = 4.8, P<0.001) but more comparable for men and women in low- and middle-income countries (29% v. 35%, t = 0.2, P = 0.85). Decomposition shows that 39% of the total association between serious mental illness and earnings in high-income countries and 27% in low- and middle-income countries is as a result of the reduced probability of having any earnings among people with serious mental illness. This component is smaller for men than women in high-income countries (31% v. 55%, t = 2.4, P = 0.020) but larger for men than women in low- and middle-income countries (50% v. 18%, t = 0.5, P = 0.60). A larger component of the total association, 49% of the total in high-income countries and 66% in low- and middle-income countries, is as a result of the lower mean level of earnings among people with than without serious mental illness who have any earnings. This component is larger for men than women in high-income countries (56% v. 36%, t = 2.1, P = 0.030) but larger for women than men in low- and middle-income countries (75% v. 45%, t = 0.5, P = 0.61).
Estimate (s.e.) | ||||||
---|---|---|---|---|---|---|
High-income countries | Low- and middle-income countries | |||||
Total | Male | Female | Total | Male | Female | |
Overall association | ||||||
Association between serious mental illness and earnings in the total sampleb | 0.32* (0.03) | 0.53* (0.07) | 0.19* (0.02) | 0.33* (0.14) | 0.29 (0.23) | 0.35 (0.18) |
Component effects | ||||||
Effect of serious mental illness on probability of non-zero earningsc | 0.14* (0.02) | 0.16* (0.02) | 0.14* (0.02) | 0.05 (0.03) | 0.07 (0.05) | 0.05 (0.04) |
Estimated effect of serious mental illness on earnings given non-zero earningsb | 0.26* (0.04) | 0.42* (0.08) | 0.12* (0.03) | 0.42 (0.28) | 0.21 (0.30) | 0.57 (0.44) |
Decomposition of overall effectd | ||||||
Due to difference in probability of non-zero earnings | 0.39* (0.05) | 0.31* (0.06) | 0.55* (0.08) | 0.27 (0.19) | 0.50 (0.58) | 0.18 (0.18) |
Due to difference in earnings given non-zero earnings | 0.49* (0.05) | 0.56* (0.07) | 0.36* (0.07) | 0.66* (0.20) | 0.45 (0.53) | 0.75* (0.23) |
Due to the interaction between the two components | 0.12* (0.01) | 0.13* (0.02) | 0.09* (0.02) | 0.07* (0.03) | 0.05 (0.06) | 0.08 (0.06) |
Country-specific, individual-level and societal-level projections
It is instructive to compare results across countries and to put the individual-level estimates into perspective by considering them in their natural metrics projected to the societal level. This was done by estimating the coefficients in the best-fitting model separately in each of the 20 surveys, expressing the estimates in terms of mean rather than median earnings, multiplying these estimates by the prevalence of serious mental illness, and then multiplying this product by the population size of the country in the age range of the sample to obtain societal-level estimates (Table 4). Serious mental illness is associated with a reduction in earnings in all 19 countries, with a statistically significant weighted average value of 19.4% of mean earnings in high-income countries and 10.9% of mean earnings in low- and middle-income countries. Between-country differences in these individual-level estimates are not significant either in high-income (χ2(9) = 8.1, P = 0.52) or low- and middle-income (χ2(9) = 5.5, P = 0.79) countries. At the societal level, the estimate averages 0.8% of all national earnings in high-income countries and 0.3% of all national earnings in low- and middle-income countries. Between-country differences are statistically significant in high-income countries (χ2(9) = 30.4, P<0.001), with much lower estimates in Italy, Japan and Spain (0.0–0.3%) than the other countries (0.7–1.7%). Between-country differences in the societal-level estimates are not statistically significant, in comparison, in low- and middle-income countries (χ2(9) = 4.7, P = 0.86).
Serious mental illness | The associations expressed as a proportion of mean national earningsa | The associations expressed in local currencyb | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
Prevalence | Individual-levelc | Societal-leveld | Individual-level | Societal-level (in Billions) | ||||||
% | (s.e.) | Estimate | (s.e.) | Estimate | (s.e.) | Estimate | (s.e.) | Estimate | (s.e.) | |
High-income | ||||||||||
Belgium | 4.9 | (1.0) | 27.3 | (17.3) | 1.3 | (0.8) | 211 807 | (135 679) | 65.8 | (42.2) |
France | 3.8 | (0.5) | 38.9* | (18.7) | 1.5* | (0.7) | 42 660* | (20 473) | 56.7* | (27.0) |
Germany | 2.7 | (0.5) | 36.8 | (36.8) | 1.0 | (1.0) | 11 908 | (11 886) | 16.8 | (16.7) |
Israel | 3.7 | (0.3) | 23.8* | (10.0) | 0.9* | (0.4) | 1516* | (622) | 0.2* | (0.0) |
Italy | 1.3 | (0.2) | 1.5 | (7.9) | 0.0 | (0.1) | 409 686 | (2 107 357) | 194.1 | (998.7) |
Japan | 1.2 | (0.4) | 19.1 | (30.0) | 0.2 | (0.4) | 611 752 | (959 881) | 5.4 | (8.7) |
The Netherlands | 4.4 | (0.7) | 16.2* | (6.2) | 0.7* | (0.3) | 7404* | (2901) | 3.5* | (1.4) |
New Zealand | 4.9 | (0.3) | 25.3 | (15.5) | 1.3 | (0.8) | 10 031 | (6275) | 1.2 | (1.3) |
Spain | 1.9 | (0.3) | 18.0 | (15.2) | 0.3 | (0.3) | 353 356 | (294 691) | 177.2 | (147.6) |
United States | 6.5 | (0.4) | 25.5* | (6.5) | 1.7* | (0.4) | 8519* | (2100) | 99.5* | (24.6) |
Low- and middle-income | ||||||||||
Brazil | 9.3 | (0.7) | 1.5 | (2.5) | 0.1 | (0.2) | 17 | (30) | 0.0 | (0.0) |
Bulgaria | 1.5 | (0.3) | 26.6 | (18.7) | 0.4 | (0.3) | 638 | (441) | 0.0 | (0.0) |
Colombia | 4.1 | (0.4) | 20.1 | (13.0) | 0.8 | (0.5) | 1 051 625 | (675 762) | 1042.9 | (670.3) |
India (Pondicherry) | 1.0 | (0.2) | 39.4 | (125.9) | 0.4 | (1.3) | 17 478 | (55 715) | 0.1* | (0.0) |
Lebanon | 4.1 | (0.7) | 2.1 | (1.1) | 0.1* | (0.0) | 141* | (70) | 0.0 | (0.0) |
Mexico | 2.3 | (0.2) | 5.9 | (4.6) | 0.1 | (0.1) | 2022 | (1622) | 2.4 | (1.5) |
Nigeria | 0.5 | (0.2) | 34.5 | (56.5) | 0.2 | (0.3) | 23 599 | (38 745) | 7.5 | (12.4) |
People's Republic of China (Beijing, Shanghai) | 0.6 | (0.2) | 28.9 | (57.4) | 0.2 | (0.3) | 413 | (826) | 0.0 | (0.0) |
Shenzhen | 0.9 | (0.3) | 3.6 | (10.9) | 0.0 | (0.1) | 1141 | (3413) | 0.0 | (0.0) |
South Africa | 3.3 | (0.3) | 18.8 | (22.3) | 0.6 | (0.7) | 4798 | (5585) | 3.9 | (4.8) |
Pooled | ||||||||||
High-income | 4.3 | (0.1) | 19.4* | (1.8) | 0.8* | (0.1) | ||||
Low- and middle-income | 3.1 | (0.1) | 10.9* | (4.6) | 0.3* | (0.1) |
Discussion
Main findings
We found that serious mental illness is associated with a reduction in population-level earnings equivalent to 0.8% of all earnings in high-income countries and 0.3% of all earnings in low- and middle-income countries. We are aware of no other comparable studies of the societal costs of mental disorders with which these estimates can be compared with other than US studies that are broadly consistent with the results reported here for the US WMH sample. Reference Harwood, Ameen, Denmead, Englert, Fountain and Livermore30,Reference Rice, Kelman, Miller and Dunmeyer31 An excellent benchmark for putting these values into perspective is the recent US government stimulus package in the American Recovery and Reinvestment Act (ARRA; www.recovery.gov), an unprecedented series of US government investments in education, energy, healthcare and national infrastructure implemented in an effort to stimulate the flagging US economy. The 0.8% decrement in societal-level earnings associated with serious mental illness in high-income countries is roughly equivalent to the total planned ARRA investment in national infrastructure, whereas the 0.3% decrement in societal-level earnings associated with serious mental illness in low- and middle-income countries is roughly equivalent to the total planned ARRA investment in all of healthcare. These comparisons make it clear that mental disorders are associated with massive losses of productive human capital not only at the individual level (32–33% of median national earnings, 11–19% of mean national earnings) but also at the societal level in the WMH countries.
Implications
This finding of a strong association between mental disorders and low earnings adds to a growing body of evidence that the impaired functioning associated with mental disorders carries an enormous societal burden. 12,Reference Pennell, Mneimneh, Bowers, Chardoul, Wells, Viana, Kessler and Üstün14 Comparative cost-of-illness studies suggest that the magnitude of this burden at the individual level is higher than that of many other classes of illness. For example, another recent WMH report showed that mental disorders are associated with higher levels of individual-level disability than any of the wide variety of commonly occurring physical disorders examined in the WMH surveys, including arthritis, asthma, cancer, diabetes and heart disease. Reference Ormel, Petukhova, Chatterji, Aguilar-Gaxiola, Alonso and Angermeyer32 This pattern held in both high-income and low- and middle-income countries. Health policy makers need to be made aware of these comparative illness burden data along with information about comparative treatment effectiveness to help guide decisions about resource allocation in disorder-specific screening and treatment programmes.
Controlled intervention trials have shown that employment rates and earnings among the employed can both be increased among people with severe-persistent mental illness, the vast majority of whom have a history of psychosis, using such methods as prevocational training and supported employment. Reference Crowther, Marshall, Bond and Huxley33,Reference Latimer34 It is important to note, though, that only a minority of people with serious mental illness have severe-persistent mental illness. Reference Kessler, Berglund, Zhao, Leaf, Kouzis, Bruce, Manderscheid and Sonnenschein35 Little is known about the effects of treatment on occupational outcomes among the much larger proportion of people with serious mental illness who do not have severe-persistent mental illness, the majority of whom suffer from chronic anxiety or behaviour disorders or recurrent depression. The fact that low earnings among people who have earnings accounts for a larger component of the total effect of serious mental illness on earning than having no earnings raises the question whether out-patient interventions for employed people with a serious mental illness, but one that is a non-severe-persistent mental illness, might be a useful remedy. A handful of controlled studies have documented that such interventions can reduce job loss and sickness absence, Reference Rost, Smith and Dickinson36,Reference Wang, Simon, Avorn, Azocar, Ludman and McCulloch37 but we are aware of no controlled intervention studies that have documented an effect on earnings among the employed. Long-term follow-up would likely be required to document such an effect. A useful preliminary step might be to examine naturalistic longitudinal data to increase our understanding of the occupational career dynamics associated with serious mental illness that is non-severe-persistent mental illness in nature and the extent to which the high unemployment rate of people with serious mental illness is as a result of a high long-term unemployment rate versus a high short-term circulating unemployment rate. Intervention implications differ depending on the mix of these two kinds of unemployment, which cannot be distinguished with the data examined here.
Limitations
This study has a number of limitations in measurement, including that mental disorders were assessed with fully structured lay interviews rather than clinical interviews, that earnings were assessed with self-report rather than administrative records, that missing income reports were based on mean imputations, and that results were pooled across samples that varied in inclusion criteria and response rates. Bias could be introduced by any of these measurement characteristics. A limitation of a more conceptual sort is that the productive labour of women in domestic activities was not assigned a monetary value even though it clearly has value. In a related way, the productive labour of individuals who receive compensation for their labour in the form of goods or services (e.g. food and housing) rather than money, such as subsistence farmers, is underestimated in our analysis because we did not measure labour directly but rather inferred the existence of labour from earning. This limitation could be of special importance in low- and middle-income countries, as a larger proportion of workers are in the informal sector than in high-income countries. Reference Standing38 This limitation might explain the fact that estimates of gender differences are less pronounced in low- and middle-income than high-income countries.
Limitations also existed in the analysis approach, most notably that a dynamic association was estimated with cross-sectional data. The most significant implication of this fact was that we were unable to adjust for the effect of low earnings on risk of mental disorder. There is good reason to believe that such a reciprocal effect exists. Reference Charles and Decicca39 Because of this limitation, although we can state that serious mental illness is associated with low earnings we cannot say that this association is the result of serious mental illness causing low earnings. Virtually all cost-of-illness studies Reference Tarricone9 have this same limitation. There is no definitive way to correct estimates for this limitation with non-experimental data. Controlling for mediating variables, such as education and marital status, which might themselves be reciprocally related to mental disorders, is not a corrective, as this can lead to overcorrection. Longitudinal analysis can sometimes help. For example, a 5-year longitudinal follow-up of 5000 initially employed respondents aged 18–30 in the Cardia study in four US cities found that high baseline depression symptom scores significantly predicted subsequent unemployment and decreases in income even after controlling for baseline education, marital status and history of prior unemployment. Reference Whooley, Kiefe, Chesney, Markovitz, Matthews and Hulley40 Even here, though, high baseline depression symptom scores could have been influenced by knowledge of job insecurity that turned out to predict subsequent job loss.
Sophisticated statistical models can sometimes be used to reduce the range of uncertainty about reciprocal influences if information is available on third variables that influence one but not the other variable in a reciprocal pair Reference Angrist, Imbens and Rubin41 or if other assumptions can reasonably be made to justify the assumption of implicit conditional randomisation, Reference Rosenbaum42 but such models are highly sensitive to misspecification. As a result, experimental interventions are ultimately the only reliable way to resolve the uncertainty about the causal effects of mental disorders on earnings. Controlled studies of these sorts, when combined with information about the prevalence and course of illness from epidemiological studies, provide the greatest hope of obtaining more definitive data about the effects of serious mental illness on earnings and other aspects of productive role functioning.
Funding
This paper was prepared under the auspices of the World Health Organization World Mental Health (WMH) Survey Initiative. These activities were supported by the United States National Institute of Mental Health (NIMH; R01MH070884), the Mental Health Burden Study: Contract number HHSN271200700030C, the John D. and Catherine T. MacArthur Foundation, the Pfizer Foundation, the US Public Health Service (R13-MH066849, R01-MH069864, and R01 DA016558), the Fogarty International Center (FIRCA R03-TW006481), the Pan American Health Organization (PAHO), the Eli Lilly & Company Foundation, Ortho-McNeil Pharmaceutical Inc, GlaxoSmithKline, Bristol-Myers Squibb, and Shire. The São Paulo Megacity Mental Health Survey is supported by the State of São Paulo Research Foundation (FAPESP) Thematic Project Grant 03/00204-3. The Epidemiological survey in Bulgaria (EPIBUL) as part of the WMH is supported by the Ministry of Health of Bulgaria in the frame of the National Program for Mental Health 2001–2006. The Chinese WMH Survey Initiative is supported by the Pfizer Foundation. The Shenzhen Mental Health Survey is supported by the Shenzhen Bureau of Health and the Shenzhen Bureau of Science, Technology, and Information. The Colombian National Study of Mental Health (NSMH) is supported by the Ministry of Social Protection. The ESEMeD project is funded by the European Commission (Contracts QLG5-1999-01042; SANCO 2004123), the Piedmont Region (Italy), Fondo de Investigación Sanitaria, Instituto de Salud Carlos III, Spain (FIS 00/0028), Ministerio de Ciencia y Tecnología, Spain (SAF 2000-158-CE), Departament de Salut, Generalitat de Catalunya, Spain, Instituto de Salud Carlos III (CIBER CB06/02/0046, RETICS RD06/0011 REM-TAP), and other local agencies and by an unrestricted educational grant from GlaxoSmithKline. The WMHI was funded by WHO (India) and helped by Dr R Chandrasekaran, JIPMER. The Israel National Health Survey is funded by the Ministry of Health with support from the Israel National Institute for Health Policy and Health Services Research and the National Insurance Institute of Israel. The World Mental Health Japan (WMHJ) Survey is supported by the Grant for Research on Psychiatric and Neurological Diseases and Mental Health (H13-SHOGAI-023, H14-TOKUBETSU-026, H16-KOKORO-013) from the Japan Ministry of Health, Labour and Welfare. The Lebanese National Mental Health Survey (LEBANON) is supported by the Lebanese Ministry of Public Health, the WHO (Lebanon), Fogarty International, anonymous private donations to IDRAAC, Lebanon, and unrestricted grants from Janssen Cilag, Eli Lilly, GlaxoSmithKline, Roche, and Novartis. The Mexican National Comorbidity Survey (MNCS) is supported by The National Institute of Psychiatry Ramon de la Fuente (INPRFMDIES 4280) and by the National Council on Science and Technology (CONACyT-G30544-H), with supplemental support from PAHO. Te Rau Hinengaro: The New Zealand Mental Health Survey (NZMHS) is supported by the New Zealand Ministry of Health, Alcohol Advisory Council, and the Health Research Council. The Nigerian Survey of Mental Health and Wellbeing (NSMHW) is supported by the WHO (Geneva), the WHO (Nigeria), and the Federal Ministry of Health, Abuja, Nigeria. The South Africa Stress and Health Study (SASH) is supported by the US NIMH (R01-MH059575) and National Institute of Drug Abuse (NIDA) with supplemental funding from the South African Department of Health and the University of Michigan. The US National Comorbidity Survey Replication (NCS-R) is supported by the NIMH (U01-MH60220) with supplemental support from the NIDA, the Substance Abuse and Mental Health Services Administration (SAMHSA), the Robert Wood Johnson Foundation (Grant 044708) and the John W. Alden Trust.
Acknowledgements
We thank the World Mental Health (WMH) Survey Initiative staff for assistance with instrumentation, fieldwork, and data analysis. A complete list of WMH publications can be found at http://www.hcp.med.harvard.edu/wmh/.
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