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Economic costs and preference-based health-related quality of life outcomes associated with childhood psychiatric disorders

Published online by Cambridge University Press:  02 January 2018

Stavros Petrou*
Affiliation:
Warwick Clinical Trials Unit, University of Warwick, Coventry
Samantha Johnson
Affiliation:
Division of Academic Neonatology, Institute for Women's Health, University College London, London
Dieter Wolke
Affiliation:
Department of Psychology and Health Science Research Institute, University of Warwick, Coventry
Chris Hollis
Affiliation:
Division of Psychiatry, School of Community Health Sciences, University of Nottingham, Nottingham
Puja Kochhar
Affiliation:
Division of Psychiatry, School of Community Health Sciences, University of Nottingham, Nottingham
Neil Marlow
Affiliation:
Division of Academic Neonatology, Institute for Women's Health, University College London, London, UK
*
Stavros Petrou, PhD, Warwick Clinical Trials Unit, University of Warwick, Coventry CV4 7AL, UK. Email: S.Petrou@warwick.ac.uk
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Abstract

Background

Childhood psychiatric disorders may have deleterious consequences through childhood and into adulthood.

Aims

To estimate costs and preference-based health-related quality of life outcomes (health utilities) associated with a broad range of childhood psychiatric disorders during the eleventh year of life.

Method

Participants in a whole-population study of extremely preterm children and term-born controls (EPICure) undertook psychiatric assessment using the Development and Well Being Assessment (DAWBA) and the Kaufman–Assessment Battery for Children. Questionnaires completed by parents and teachers described the children's utilisation of health, social and education services during the eleventh year of life. Parents also described their child's health status using the Health Utilities Index Mark 2 and Mark 3 health status classification systems. Descriptive and multiple regression techniques were used to explore the association between psychiatric disorders and economic outcomes.

Results

The study presents detailed costs and health utilities associated with psychiatric disorders for the preterm population, term-born population and pooled study population, following appropriate controls.

Conclusions

The results of this study should be used to inform future economic evaluations of interventions aimed at preventing childhood psychiatric disorders or alleviating their effects. Further research is required that identifies, measures and values the longer-term economic impacts of these disorders in a valid and reliable manner.

Type
Papers
Copyright
Copyright © Royal College of Psychiatrists, 2010 

The median prevalence of childhood psychiatric disorders has been reported as 12% for prepubescent school-age children and 15% among adolescents. Reference Roberts1 Among British children aged 5–15 years, it has been estimated that 10% have a psychiatric disorder, with 5% having conduct disorder and 4% having emotional disorders. Reference Meltzer, Gatward, Goodman and Ford2 A longitudinal community study of children aged 9–13 years from the American state of North Carolina estimated that the 3-month prevalence of any psychiatric disorder averaged 13.3% (95% CI 11.7–15.0%). Reference Costello, Mustillo, Erkanli, Keeler and Angold3 There is increasing evidence from longitudinal studies Reference Kovacs, Feinberg, Crouse-Novak, Palauskas and Finkelstein4Reference Biederman, Monuteaux, Mick, Spencer, Wilens and Silva14 and retrospective reports Reference Giaconia, Reinberg, Silverman, Pakiz, Frost and Cohen15 that childhood psychiatric disorders may have significant adverse consequences for mental health, educational outcomes and substance misuse through childhood and into adulthood. However, relatively little is known about their consequences in terms of costs or health utilities (preference-based measures of health outcome developed from economic theory), which can directly or indirectly inform resource-allocation decisions. Cost of illness studies have been conducted for a relatively small number of childhood psychiatric disorders, including childhood depression, Reference McCrone, Knapp and Fombonne16 separation anxiety Reference Bodden, Dirksen and Bögels17 and attention-deficit hyperactivity disorder (ADHD), Reference Leibson and Long18 and health utilities have been estimated for ADHD Reference Matza, Secnik, Rentz, Mannix, Sallee and Gilbert19,Reference Petrou and Kupek20 and autism-spectrum disorders. Reference Petrou and Kupek20 The purpose of this research is to augment the limited economic evidence in this area by estimating costs and health utilities associated with childhood psychiatric disorders during mid-childhood. This will provide a significant new resource for clinical decision-makers and budgetary and service planners and to analysts estimating the cost-effectiveness of preventive or treatment interventions for these disorders.

Method

Study population

Children who participated in the EPICure study represented the study population for this empirical investigation. The EPICure study is a whole-population longitudinal study of all infants born at 20 to 25 completed weeks of gestation in all 276 maternity units in the UK and Republic of Ireland from March to December 1995. Reference Wood, Marlow, Costeloe and Gibson21 Participants in the EPICure study were selected for this investigation as previous research had indicated higher prevalence rates of psychiatric disorders among children born preterm or with a low birth weight compared with general population samples. Reference Botting, Powls, Cooke and Marlow22Reference Johnson, Hollis, Kochhar, Hennessy, Wolke and Marlow25 Of the 307 surviving extremely preterm infants in the EPICure study, 241 (78.2%) were assessed at a median age of 6 years 4 months (range: 5 years 2 months to 7 years 3 months) Reference Marlow, Wolke and Bracewell26 and 219 (71.3%) again at a median age of 10 years 11 months (range: 10 years 1 month to 12 years 1 month). Reference Johnson, Hennessy, Smith, Trikic, Wolke and Marlow27 A control group of 153 mainstream school classmates who were born at full term and matched for age, gender and ethnic group was also evaluated at a median age of 10 years 11 months (range: 9 years 9 months to 12 years 3 months). A full description of the EPICure study is available elsewhere. Reference Wood, Marlow, Costeloe and Gibson21,Reference Johnson, Hennessy, Smith, Trikic, Wolke and Marlow27 The extremely preterm children and their classmate controls were analysed separately for the purposes of the empirical investigation reported in this paper. Additionally, we analysed the pooled study population controlled for clinical and sociodemographic confounders, including gestational age at birth and a measure of neurosensory or motor impairment. Ethical approval for the study was obtained from the Southampton and South West Hampshire Research Ethics Committee and approved by the Central Office for Research Ethics Committees (COREC).

Psychiatric assessments

Childhood psychiatric disorders were diagnosed using the Development and Well Being Assessment (DAWBA), Reference Goodman, Ford, Richards, Gatward and Meltzer28 a semi-structured interview conducted with the main parent (usually the mother) or completed online by the main parent around the child's eleventh birthday. Information obtained from the DAWBA was used to assign ICD–10 29 and DSM–IV–TR 30 diagnoses. Supplemental information was provided by teachers who completed a questionnaire-based version of the DAWBA. Multi-informant data were collated and potential diagnoses were computer-generated using scoring algorithms. These were reviewed by two child and adolescent psychiatrists (C.H. and P.K.) masked to group allocation who assigned final DSM–IV and ICD–10 consensus diagnoses by reviewing quantitative symptom data and qualitative transcripts. In this paper we primarily refer to psychiatric disorders defined using DSM–IV–TR criteria. 31 Diagnostic classifications were assigned to the categories of emotional, ADHD, conduct, autistic and tic disorders. In addition, the Kaufman–Assessment Battery for Children (K–ABC) was used to obtain IQ scores (range 40–160). Reference Kaufman and Kaufman32 Cognitive impairment was defined as either moderate (–3 standard deviations to –2 standard deviations or IQ scores of 71 to 81) or severe (< –3 standard deviations or IQ scores of ≤70) using the mean (s.d.) of classmates to account for the secular drift in IQ scores over time. Reference Johnson, Hennessy, Smith, Trikic, Wolke and Marlow27,Reference Wolke, Ratschinski, Ohrt and Riegel33

Estimation of costs

As part of the battery of assessments performed at 11 years, the main parent was asked to complete a detailed postal questionnaire about their child's resource utilisation over the previous year of life. The questionnaire was piloted to ascertain its acceptability, comprehension and reliability and reminder letters were sent to parents to increase the response and completion rates. The data collected from the main parent included their child's use of hospital in-patient and day care services, community health services, prescribed medications, social services and education services. The components of resource utilisation and the units in which they were measured are summarised in online Table DS1. Estimates of service provision were derived from these data and usually expressed in terms of contact hours. For all hospital admissions, estimates of service provision were expressed in terms of patient days with part of a day at each level of care counted as a 24-hour period. For education services, estimates of service provision reflected the level of educational assistance within each type of educational establishment (mainstream school, mainstream school with special unit attached, special school for the physically disabled and special school for children with intellectual disability or learning difficulties). In addition to information provided by parents, teachers were asked to identify children with special educational needs, defined in the educational context as those with intellectual disability or learning difficulties that make it harder for them to learn or access education than most children of the same age, and they were also asked to detail any special educational needs support the child received. Reference Johnson, Hennessy, Smith, Trikic, Wolke and Marlow27 This included information on the type and duration of individual education or behavioural plans, one-to-one special needs provision, small group special needs provision, outreach support and support from educational psychologists, clinical psychologists, physiotherapists, speech therapists and occupational therapists. All resource-use data were entered directly from the research instruments into a purpose-built data-collection program with in-built safeguards against inconsistent entries and then verified by dual coding.

United Kingdom unit costs were applied to each resource item to value total resource use for each study child over an annual period. All unit costs employed followed recent guidelines on costing public services as part of economic evaluation. Reference Allen, Beecham, Netten and Beecham3436 The calculation of these costs was underpinned by the concept of opportunity cost, which can be defined as the value of the next best alternative for using these resources. Reference Drummond, Sculpher, Torrance, O'Brien and Stoddart35 The costs of hospital in-patient and day care services were largely derived from English Department of Health reference costs based upon National Health Service trust financial returns. 37 The unit costs of community health and social services were largely derived from national sources, Reference Curtis38 and took account of time spent by professionals on indirect activities, such as travelling and paper work. Some unit costs of health and social services were calculated from first principles using established accounting methods. Reference Allen, Beecham, Netten and Beecham34 Drug costs were obtained from the British National Formulary. 39 Educational costs were based upon data for different types of educational establishment obtained from the Department of Education and Skills in England (details available from the author on request). These included salaries, employer on-costs and revenue and capital overheads associated with each form of special educational needs support described above. All costs were expressed in pounds sterling and reflected values for the financial year 2006–7.

Estimation of health utilities

The postal questionnaire completed by the main parent around the child's eleventh birthday included the Health Utilities Index (HUI), which can be described as a family of health status classification systems with preference weights (or multi-attribute utility scores) attached to each permutation of responses. Reference Torrance, Furlong, Feeny and Boyle40 The main parent was considered the appropriate subject for completing the HUI as related research had indicated that the comprehension level required for successful completion is somewhat higher for a paediatric sample where a number of children have developmental disabilities. Reference Eiser and Morse41 The main parent completed the unedited 15-item questionnaire for proxy-assessed usual health status assessment, which was obtained from the HUI developers and covers both Mark 2 (HUI2) and Mark 3 (HUI3) health status classification systems. The ‘usual’ health focus of the questions has previously been applied in population health surveys, where short-term illnesses such as influenza are not the major concern. Reference Furlong, Feeny, Torrance and Barr42 The HUI2 health status classification system covers seven attributes: sensation, mobility, emotion, cognition, self-care, pain and fertility. The HUI3 health status classification system covers eight attributes: cognition, vision, hearing, speech, ambulation, dexterity, emotion and pain. The HUI3 health status classification system is now recommended by the HUI developers as the preferred measure of primary analyses because of its broad applicability in both clinical and general population health studies, improvements in a number of definitions, and an increased orthogonality of its attributes for structural independence. Reference Furlong, Feeny, Torrance and Barr42,Reference Horsman, Furlong, Feeny and Torrance43 Consequently, our primarily analyses of preference-based health-related quality of life outcomes were based on the HUI3 health status classification system. Function within each HUI3 attribute is graded on a five- or six-point scale corresponding to the level of severity, ranging from normal function (level 1) to severe impairment (level 5 or 6). Responses to the HUI3 health status classification system were converted into multiplicative multi-attribute utility scores using a published utility function. Reference Feeny, Furlong, Torrance, Goldsmith, Zhu and DePauw44,Reference Furlong, Feeny, Torrance, Goldsmith, DePauw and Zhu45 These multi-attribute utility scores are based on the permutation of responses across the eight attributes and are expressed on an interval scale ranging from –0.36 (representing the health state with the lowest level of function for all attributes) to 1.00 (representing the health state with the highest level of function for all attributes). The multi-attribute utility scoring algorithm for the HUI3 can be summarised as

\batchmode \documentclass[fleqn,10pt,legalpaper]{article} \usepackage{amssymb} \usepackage{amsfonts} \usepackage{amsmath} \pagestyle{empty} \begin{document} \[\ u^{{\bigstar}}=1.371(b_{1}{\times}b_{2}{\times}b_{3}{\times}b_{4}{\times}b_{5}{\times}b_{6}{\times}b_{7}{\times}b_{8})-0.371\ \] \end{document}

where u* is the utility score for the overall health state being measured and the b j 's are substituted from a table of coefficients provided by the HUI developers for the appropriate attribute and level. Reference Furlong, Feeny, Torrance, Goldsmith, DePauw and Zhu45 To develop the multi-attribute utility scoring algorithm a random sample of 504 general population adults living in the city of Hamilton, Canada had previously been asked to value selected health states using both a visual analogue scaling technique and a standard gamble instrument. Reference Furlong, Feeny, Torrance, Goldsmith, DePauw and Zhu45 Analyses of preference-based health-related quality of life outcomes in our study were repeated using the HUI2 health status classification system and an underpinning multi-attribute utility scoring algorithm recently estimated on the basis of the preferences of 198 members of the UK general population. Reference McCabe, Stevens, Roberts and Brazier46 The latter measure and underpinning multi-attribute utility scoring algorithm might be considered to generate relevant values for UK policy purposes. 36

Statistical methods

Differences in baseline sociodemographic and clinical characteristics between children with and without a psychiatric disorder, as defined by DSM–IV–TR criteria, were tested using the Pearson chi-squared test.

A number of statistical approaches were tested in order to impute costs for children with some missing data. Given the negligible level of missing cost data (<2%) in the final study sample, simple linear regression and simulation-based multiple imputation Reference Schafer47 for each psychiatric group produced similar results. Therefore, it was considered appropriate to use the estimates generated by the simple linear regression in this analysis. Reference Schafer47Reference Gray, Wolstenholme, Wordsworth and Clarke49

For the preterm population, term-born population and pooled study population, comparisons of each category of public sector costs and of total public sector costs were made between children with and without a psychiatric disorder as defined by DSM–IV–TR criteria. Similarly, for the preterm, term-born and pooled populations, comparisons of total public sector costs were made between children with and without varying levels of cognitive impairment. Comparisons of total public sector costs between children with and without individual psychiatric disorders (emotional, ADHD, conduct, autistic, tic) as defined by DSM–IV–TR criteria were restricted to the pooled population because of the relatively small sample sizes for some disorders (e.g. n = 4 for tic disorders). Comparisons of costs are reported as mean values with standard deviations and mean differences in costs between the comparison groups with 95% confidence intervals. As the data for costs were skewed, in addition to Student t-tests of cost differences, non-parametric bootstrap estimation was used to derive 95% confidence intervals for mean cost differences between the comparison groups. Reference Barber and Thompson50 The bootstrap method does not rely on parametric assumptions concerning the underlying distribution of data, hence its usefulness for generating confidence intervals for skewed data. Reference Briggs, Claxton and Sculpher51 Using a large number of simulations, and based on sampling with replacement from the original data, the bootstrap method estimates the distribution of a sampling statistic. Reference Briggs, Claxton and Sculpher51 Each of the confidence intervals surrounding mean cost differences was calculated using 10 000 bias-corrected bootstrap replications.

In addition, generalised linear regressions Reference Briggs, Claxton and Sculpher51 were performed for the preterm, term-born and pooled populations with total public sector costs over the previous year of life representing the dependent variable in the analyses. Three regression models were constructed for each population group. In the first model, the main independent variable was a dichotomous variable of whether or not the child had a psychiatric disorder as defined by DSM–IV–TR criteria. In the second model, the main independent variable was a dichotomous variable of whether or not the child had moderate cognitive impairment, whereas in the third model it was a dichotomous variable of whether or not the child had severe cognitive impairment. For each generalised linear regression model, a gamma distribution and linear (identity) link function for costs was selected on the basis of its low Akaike information criterion (AIC) statistic (AIC statistics of 19.24, 19.24 and 19.23 for models 1, 2 and 3 respectively for the pooled population) compared with alternative distributional forms (e.g. Gaussian, inverse Gaussian and Poisson distributional families) and link functions (e.g. log link function). For the preterm and term-born populations, covariates included in the generalised linear regressions were gender (male, female), maternal marital status (married, single, cohabiting, widowed, separated or divorced), respondent parent's current age (<30, 30–39, 40–49, ≥50 years), type of accommodation (owner occupied, rented, other), access to car (yes, no), highest parental qualification (vocational or equivalent, ordinary level or equivalent, advanced level or equivalent, diploma or equivalent, university degree, postgraduate qualification, other, none), highest parental occupational status (professional or managerial, intermediate, routine and manual, long-term unemployed), language spoken at home (English only, English and other language(s)), number of smokers at home (0, 1, ≥2) and a measure of neurosensory or motor impairment (no, yes). Reference Johnson, Fawke, Hennessy, Rowell, Thomas and Wolke52 For the pooled population, covariates includes in the generalised linear regressions additionally included gestational age at birth (≤23 weeks, 24 weeks, 25 weeks, term). In sensitivity analyses, the measure of neurosensory or motor impairment was replaced by an interaction term between gestational age at birth and psychiatric disorder for the pooled population.

For the preterm population, term-born population and pooled study population, we used Fisher's exact test for equality of proportions to compare the proportion of children with suboptimal levels of function (defined as below level 1 function) within each of the eight attributes of the HUI3 health status classification system between children with and without a psychiatric disorder as defined by DSM–IV–TR criteria. The same comparison groups used as a basis for analysing total public sector costs were also used as a basis for analysing health utilities. Differences in the HUI3 and UK HUI2 multi-attribute utility scores between the comparison groups were tested using two-sample t-tests for unequal variance. Finally, we performed Tobit regressions to explore the effects of psychiatric disorders on the HUI3 and UK HUI2 multi-attribute utility scores for the preterm, term-born and pooled populations. Tobit regression was required to account for the censoring of the dependent variable, the multi-attribute utility score, which has an upper value of 1.0. Reference Greene53 As with costs, three regression models were constructed for each population group, which differed in terms of the main psychiatric independent variable. The same covariates incorporated into the generalised linear regressions on costs were incorporated into the Tobit regressions on health utilities.

All analyses were performed with a microcomputer using the Statistical Package for the Social Sciences (SPSS) (version 15.0) software and STATA (version 10.0) software for Windows XP. P-values of 0.05 or less were considered statistically significant.

Results

Postal questionnaires reporting costs and health utilities were returned for a total of 331 study children, including 190 extremely preterm children (representing 86.8% of extremely preterm children undergoing neurodevelopmental assessments at a median age of 10 years 11 months) and 141 term-born classmates (representing 92.2% of term-born classmates undergoing neurodevelopmental assessments at this time point). Multi-informant psychiatric assessments were performed on 321 (97.0%) of these 331 study children, with multiple imputation techniques used to estimate psychiatric diagnoses for the remaining 10 children. Reference Johnson, Hollis, Kochhar, Hennessy, Wolke and Marlow25 Children for whom postal questionnaires were not returned were more likely to be born at between 25 weeks exactly and 25 weeks 6 days, be of Black and minority ethnic origin, have had an operation for necrotising enterocolitis, to have unemployed parents and to have had lower cognitive scores or cognitive impairment at 2.5 and 6 years (P≥0.05). There were a number of significant differences between the 50 children with and 281 without a DSM–IV–TR clinical diagnosis, for whom postal questionnaires were returned, in terms of sociodemographic and clinical characteristics. Notably, children with a DSM–IV–TR clinical diagnosis were more likely to be male, less likely to have married parents, less likely to live in owner-occupied accommodation, more likely to live with smokers and more likely to have been born preterm (online Table DS2).

Resource-use values for children with and without a psychiatric disorder as defined by DSM–IV–TR criteria are summarised in online Table DS1 for the pooled study population. This table highlights significant differences in mean utilisation of a number of mental and non-mental health and social care services between these groups.

Public sector costs over the previous year of life for the preterm population, term-born population and pooled study population are summarised in online Table DS3. Among the pooled study population, mean (s.d.) public sector costs over the 12-month period were £7188 (s.d. = £5869) for the 50 children with a psychiatric disorder, as defined by DSM–IV–TR criteria, and £5116 (s.d. = £4370) for the 281 children without a psychiatric disorder, generating a mean cost difference of £2072 (bootstrap 95% CI £349–£3795), which was statistically significant (P = 0.020). Among the preterm population, the mean public sector cost difference between the 39 children with and 151 children without a psychiatric disorder, as defined by DSM–IV–TR criteria, was estimated at £1998 (bootstrap 95% CI –£164 to £4160, P = 0.076). Among the term population, the respective public sector cost difference between the 11 children with and 130 children without a psychiatric disorder, as defined by DSM–IV–TR criteria, was estimated at £51 (bootstrap 95% CI –£752 to £854, P = 0.903). When the data were analysed by cost category, a DSM–IV–TR clinical diagnosis was associated with significantly higher community health and social care costs in all population groups and significantly higher total health and social care costs in the preterm population and pooled study population.

Mean public sector costs over the previous year of life and mean cost differences between children with and without individual psychiatric disorders are summarised in Table 1 for the preterm population, term-born population and pooled study population. Of particular note are the additional £3170 (P = 0.001) and £8877 (P<0.0001) annual public sector costs associated with moderate cognitive impairment and severe cognitive impairment, respectively, in the preterm population; and the additional £6745 (P = 0.014), £3375 (P<0.0001) and £8530 (P<0.0001) annual public sector costs associated with a diagnosis of an autistic disorder, moderate cognitive impairment and severe cognitive impairment, respectively, in the pooled study population.

Table 1 Mean public sector costs over the previous year of life and mean cost differences between children with and without psychiatric disorders (UK £ sterling, 2006–7 prices)

With disorder Without disorder Cost difference
Psychiatric disorder n Mean s.d. n Mean s.d. Mean 95% CIa P b
Preterm sample
    Any DSM–IV clinical diagnosis 39 8 071.8 6 358.5 151 6 073.8 5 264.9 1 998.0 –164.4 to 4 160.4 0.076
    Moderate cognitive impairmentc 67 8 536.1 6 665.3 123 5 366.0 4 481.2 3 170.0 1 384.4 to 4 955.7 0.001
    Severe cognitive impairmentd 18 1 4519.4 6 187.6 172 5 643.0 4 765.3 8 876.5 5 923.5 to 11 829.5 <0.0001
Term sample
    Any DSM–IV clinical diagnosis 11 4 053.9 1 127.7 130 4 003.3 2 624.7 50.6 –752.3 to 853.6 0.903
    Moderate cognitive impairmentc 2 3 333.0 121.6 139 4 017.0 2 554.5 e e e
    Severe cognitive impairmentd 0 141 4 007.3 2 537.5 e e e
Total sample
    Any emotional disorderf 16 6 860.1 5 259.2 315 5 433.4 4 738.9 1 426.8 –1 195.1 to 4 048.7 0.304
    Any ADHD diagnosisg 17 5 812.0 3 832.6 314 5 551.1 4 852.0 261.0 –1 656.8 to 2 178.7 0.792
    Any conduct disorderh 17 7 033.5 5 700.1 314 5 342.0 4 609.3 1 691.5 –1 006.2 to 4 389.2 0.246
    Any autistic disorderi 11 12 016.1 7 568.1 320 5 270.8 4 481.2 6 745.3 2 232.9 to 11 257.7 0.014
    Tic disorder 4 7 022.4 6 474.7 327 5 482.7 4 760.2 1 539.7 –4 815.1 to 7 894.5 0.667
    Any DSM–IV clinical diagnosis 50 7 187.8 5 868.6 281 5 115.9 4 369.5 2 071.9 348.7 to 3 795.2 0.020
    Moderate cognitive impairmentc 69 8 385.3 6 625.2 262 4 650.3 3 645.8 3 735.0 2 087.8 to 5 382.1 <0.0001
    Severe cognitive impairmentd 18 13 443.3 6 725.1 313 4 913.5 4 011.8 8 529.8 5 554.9 to 11 504.7 <0.0001

The results of generalised linear regressions exploring the relationship between psychiatric disorders and total public sector costs over the previous year of life are shown in Table 2 for the preterm population, term-born population and pooled study population. After controlling for clinical and sociodemographic confounders, a DSM–IV–TR clinical diagnosis was associated with increases of £1499 (95% CI –£758 to £3755, P = 0.193) and £1505 (95% CI –£40 to £3049, P = 0.056) in annual public sector costs for the preterm and pooled study populations, respectively. Moderate cognitive impairment and severe cognitive impairment were associated with increases in annual public sector costs of £915 (95% CI –£687 to £2517, P = 0.263) and £4852 (95% CI –£839 to £10 542, P = 0.095), respectively, for the preterm population, and £1402 (95% CI –£88 to £2891, P = 0.065) and £5662 (95% CI £238 to £11 086, P = 0.041), respectively, for the pooled study population. The only other factor associated with significantly increased public sector costs across the regression models was extremely preterm birth for the pooled study population. Replacing the measure of neurosensory or motor impairment Reference Johnson, Fawke, Hennessy, Rowell, Thomas and Wolke52 by an interaction term between gestational age at birth and psychiatric disorder had no discernible effects on the results of the generalised linear regressions.

Table 2 Relationship between psychiatric disorders and public sector costs (UK £ sterling, 2006–7 prices) over the previous year of life, generalised linear models with gamma distribution and linear (identity) link function

Psychiatric disorder Adjusted regression coefficienta Robust standard error 95% CI P
Preterm sample b
DSM–IV clinical diagnosis
    No (reference group)
    Yes 1 498.7 11 51.2 –757.7 to 3 755.0 0.193
Moderate cognitive impairmentc
    No (reference group)
    Yes 915.1 817.2 –686.6 to 2 516.8 0.263
Severe cognitive impairmentd
    No (reference group)
    Yes 4 851.5 2 903.5 –839.3 to 10 542.2 0.095
Term sample b
DSM–IV clinical diagnosis
    No (reference group)
    Yes –33.8 829.1 –1 658.8 to 1 591.2 0.967
Moderate cognitive impairmentc
    No (reference group)
    Yes e e e e
Severe cognitive impairmentd
    No (reference group)
    Yes e e e e
Total sample f
DSM–IV clinical diagnosis
    No (reference group)
    Yes 1 504.5 788.2 –40.3 to 3 049.3 0.056
Moderate cognitive impairmentc
    No (reference group)
    Yes 1 401.6 760.1 –88.1 to 2 891.2 0.065
Severe cognitive impairmentd
    No (reference group)
    Yes 5 662.2 2 767.4 238.2 to 11 086.3 0.041

In each population group, comparisons of the frequency and proportion of suboptimal levels of function were made between the children with and without a DSM–IV–TR clinical diagnosis for each of the eight attributes of the HUI3. These analyses revealed significantly higher proportions of suboptimal levels of function among the children with a DSM–IV–TR clinical diagnosis for four attributes (emotion, pain, dexterity and cognition) for the preterm population, three attributes (speech, emotion and dexterity) for the term population and five attributes (speech, emotion, pain, dexterity and cognition) for the pooled study population (P≤0.05).

Mean HUI3 multi-attribute utility scores and mean utility differences between children with and without individual psychiatric disorders are summarised in Table 3 for all three populations. Of particular note are the 0.165 (P = 0.003), 0.232 (P<0.0001) and 0.512 (P<0.0001) mean utility decrements associated with a psychiatric disorder as defined by DSM–IV–TR criteria, moderate cognitive impairment and severe cognitive impairment, respectively, in the preterm population; and the 0.198 (P = 0.027), 0.250 (P = 0.003), 0.261 (P = 0.011), 0.192 (P<0.0001), 0.273 (P<0.0001) and 0.571 (P<0.0001) mean utility decrements associated with an emotional disorder, an ADHD diagnosis, an autistic disorder, a psychiatric disorder as defined by DSM–IV–TR criteria, moderate cognitive impairment and severe cognitive impairment, respectively, in the pooled study population. Analogous results were generated using the alternative UK HUI2 multi-attribute utility measure with the exception that statistically significant utility decrements were also generated for a psychiatric disorder as defined by DSM–IV–TR criteria for the term-born population and a conduct disorder for the pooled study population (Table 4).

Table 3 Health Utilities Index Mark 3 multi-attribute utility scores for children with and without psychiatric disorders

With disorder Without disorder Cost difference
Psychiatric disorder n Mean s.d. n Mean s.d. Mean 95% CI P a
Preterm sample
    Any DSM–IV clinical diagnosis 39 0.656 0.270 151 0.820 0.254 0.165 0.061 to 0.269 0.003
    Moderate cognitive impairmentb 67 0.635 0.331 123 0.867 0.180 0.232 0.140 to 0.324 <0.0001
    Severe cognitive impairmentc 18 0.318 0.390 172 0.830 0.207 0.512 0.285 to 0.739 <0.0001
Term sample
    Any DSM–IV clinical diagnosis 11 0.826 0.251 130 0.967 0.070 0.141 –0.027 to 0.310 0.093
    Moderate cognitive impairmentb 2 0.884 0.165 139 0.957 0.102 d d d
    Severe cognitive impairmentc 0 141 0.956 0.102 d d d
Total sample
    Any emotional disordere 16 0.672 0.296 315 0.871 0.220 0.198 0.026 to 0.371 0.027
    Any ADHD diagnosisf 17 0.629 0.271 314 0.879 0.215 0.250 0.099 to 0.402 0.003
    Any conduct disorderg 17 0.727 0.260 314 0.870 0.221 0.143 –0.008 to 0.294 0.062
    Any autistic disorderh 11 0.609 0.257 320 0.870 0.222 0.261 0.076 to 0.446 0.011
    Tic disorder 4 0.675 0.292 327 0.866 0.224 0.190 –0.529 to 0.909 0.376
    Any DSM–IV clinical diagnosis 50 0.698 0.273 281 0.890 0.203 0.192 0.105 to 0.278 <0.0001
    Moderate cognitive impairmentb 69 0.643 0.329 262 0.916 0.149 0.273 0.187 to 0.359 <0.0001
    Severe cognitive impairmentc 18 0.318 0.390 313 0.889 0.178 0.571 0.345 to 0.797 <0.0001

Table 4 Health Utilities Index UK Mark 2 multi-attribute utility scores for children with and without psychiatric disorders

With disorder Without disorder Cost difference
Psychiatric disorder n Mean s.d. n Mean s.d. Mean 95% CI P a
Preterm sample
    Any DSM–IV clinical diagnosis 39 0.759 0.148 151 0.858 0.157 0.098 0.041 to 0.155 0.001
    Moderate cognitive impairmentb 67 0.754 0.186 123 0.883 0.123 0.130 0.077 to 0.182 <0.0001
    Severe cognitive impairmentc 18 0.612 0.245 172 0.861 0.130 0.249 0.117 to 0.381 0.001
Term sample
    Any DSM–IV clinical diagnosis 11 0.854 0.131 130 0.948 0.077 0.094 0.005 to 0.183 0.040
    Moderate cognitive impairmentb 2 0.871 0.105 139 0.941 0.085 d d d
    Severe cognitive impairmentc 0 141 0.940 0.086 d d d
Total sample
    Any emotional disordere 16 0.760 0.161 315 0.888 0.139 0.127 0.037 to 0.218 0.009
    Any ADHD diagnosisf 17 0.792 0.120 314 0.888 0.142 0.096 0.028 to 0.164 0.008
    Any conduct disorderg 17 0.802 0.129 314 0.888 0.141 0.085 0.009 to 0.161 0.030
    Any autistic disorderh 11 0.721 0.152 320 0.887 0.140 0.165 0.056 to 0.275 0.007
    Tic disorder 4 0.801 0.156 327 0.884 0.141 0.083 –0.164 to 0.329 0.367
    Any DSM–IV clinical diagnosis 50 0.782 0.149 281 0.901 0.133 0.118 0.071 to 0.165 <0.0001
    Moderate cognitive impairmentb 69 0.757 0.185 262 0.915 0.108 0.158 0.109 to 0.206 <0.0001
    Severe cognitive impairmentc 18 0.612 0.245 313 0.898 0.118 0.286 0.155 to 0.417 <0.0001

Finally, the separate Tobit regressions revealed that, even after controlling for clinical and sociodemographic confounders, a psychiatric disorder as defined by DSM–IV–TR criteria, moderate cognitive impairment and severe cognitive impairment were associated with significant decrements in the HUI3 multi-attribute utility score of 0.226 (P<0.0001), 0.205 (P<0.0001) and 0.342 (P<0.0001), respectively, for the preterm population, and 0.213 (P<0.0001), 0.198 (P<0.0001) and 0.324 (P<0.0001), respectively, for the pooled study population (Table 5). Analogous results were generated using the alternative UK HUI2 multi-attribute utility measure (Table 6); the decrements in these utility scores were smaller in magnitude, but remained statistically significant. The only other factor associated with statistically significant decrements in utility scores across the regression models was extremely preterm birth for the pooled study population. Replacing the measure of neurosensory or motor impairment Reference Greene53 by an interaction term between gestational age at birth and psychiatric disorder had no discernible effects on the results of the Tobit regressions.

Table 5 Relationship between psychiatric disorders and Health Utilities Index Mark 3 multi-attribute utility scores, Tobit regressions

Psychiatric disorder Adjusted regression coefficienta Robust standard error 95% CI P
Preterm sample b
DSM–IV clinical diagnosis
    No (reference group)
    Yes –0.226 0.053 –0.332 to –0.120 <0.0001
Moderate cognitive impairmentc
    No (reference group)
    Yes –0.205 0.046 –0.297 to –0.113 <0.0001
Severe cognitive impairmentd
    No (reference group)
    Yes –0.342 0.093 –0.526 to –0.158 <0.0001
Term sample b
DSM–IV clinical diagnosis
    No (reference group)
    Yes –0.144 0.088 –0.317 to 0.030 0.104
Moderate cognitive impairmentc
    No (reference group)
    Yes e e e e
Severe cognitive impairmentd
    No(reference group)
    Yes e e e e
Total sample f
DSM–IV clinical diagnosis
    No (reference group)
    Yes –0.213 0.045 –0.302 to –0.124 <0.0001
Moderate cognitive impairmentc
    No (reference group)
    Yes –0.198 0.043 –0.282 to –0.113 <0.0001
Severe cognitive impairmentd
    No (reference group)
    Yes –0.324 0.090 –0.501 to –0.146 <0.0001

Table 6 Relationship between psychiatric disorders and UK Health Utilities Index Mark 2 multi-attribute utility scores, Tobit regressions

Psychiatric disorder Adjusted regression coefficienta Robust standard error 95% CI P
Preterm sample b
DSM–IV clinical diagnosis
    No (reference group)
    Yes –0.130 0.033 –0.196 to –0.064 <0.0001
Moderate cognitive impairmentc
    No (reference group)
    Yes –0.124 0.029 –0.181 to –0.067 <0.0001
Severe cognitive impairmentd
    No (reference group)
    Yes –0.177 0.057 –0.290 to –0.065 0.002
Term sample b
DSM–IV clinical diagnosis
    No (reference group)
    Yes –0.103 0.067 –0.237 to 0.030 0.128
Moderate cognitive impairmentc
    No (reference group)
    Yes e e e e
Severe cognitive impairmentd
    No (reference group)
    Yes e e e e
Total sample f
DSM–IV clinical diagnosis
    No (reference group)
    Yes –0.121 0.030 –0.180 to –0.063 <0.0001
Moderate cognitive impairmentc
    No (reference group)
    Yes –0.123 0.028 –0.178 to –0.068 <0.0001
Severe cognitive impairmentd
    No (reference group)
    Yes –0.171 0.058 –0.285 to –0.057 0.004

Discussion

Main findings

This paper augments the limited published evidence on the economic consequences of childhood psychiatric disorders. Reference McCrone, Knapp and Fombonne16Reference Petrou and Kupek20 Its unique contribution is twofold. First, it focuses on a broader range of childhood psychiatric disorders than has hitherto been studied by health economists within one sample, from relatively rare tic disorders to more common emotional and behavioural disorders, such as ADHD. Second, it reports both cost and preference-based health-related quality of life (or health utility) outcomes for these disorders. In the process, it provides a broader set of data inputs for directly or indirectly informing resource-allocation decisions than has hitherto been provided.

The study revealed an average annual cost difference of over £2000 across the pooled study population between children with and without a psychiatric disorder as defined by DSM–IV–TR criteria. This exceeds that identified for several other childhood conditions, Reference Ungar54 including childhood asthma Reference To, Dell, Dick and Cicutto55 and juvenile idiopathic arthritis, Reference Thornton, Lunt, Ashcroft, Baildam, Foster and Davidson56 and compares with additional annual cost burdens reported elsewhere of £890 (1996–7 prices) for childhood depression, Reference McCrone, Knapp and Fombonne16 e2748 (2003 prices) for separation anxiety Reference Bodden, Dirksen and Bögels17 and between US$1100 and 1800 (1996 prices) for ADHD. Reference Leibson and Long18 The study also revealed mean differences in the HUI3 and UK HUI2 multi-attribute utility scores of 0.192 and 0.118, respectively, across the pooled study population between these comparison groups, which far exceeds the 0.03 minimally important difference in utility score postulated in the literature as clinically important for evaluative purposes. Reference Drummond57 Notably, the difference in the mean HUI3 multi-attribute utility scores between children with (0.698) and without (0.890) a psychiatric disorder can be interpreted as a difference between being in a state of severe overall disability rather than a mild overall disability according to the classification of HUI3 multi-attribute utility scores published by the HUI developers. Reference Feeny, Furlong, Saigal and Sun58

Strengths and limitations

The study population was drawn from participants in the EPICure study, a whole-population longitudinal study of all infants born extremely preterm in the UK and Republic of Ireland over a 10-month period and a contemporaneous classroom control group born at full term and matched for age, gender and ethnic group. As such, the study population consists of two distinct groups of children: one that can be characterised as at high risk for psychiatric disorders and a more representative general population sample. The two groups were analysed separately for the purposes of our empirical investigation. Of particular note were the mean adjusted additional costs of £915 and £4852, the mean adjusted HUI3 utility decrements of 0.205 and 0.342 and the mean adjusted UK HUI2 utility decrements of 0.124 and 0.177 associated with cognitive impairment and severe cognitive impairment, respectively, in the extremely preterm children. Analyses of the term-born children were restricted by the limited number of children in this population who were diagnosed with a psychiatric disorder (n = 11). Nevertheless, separate economic results for this population are presented for completeness. Additionally, analyses of the pooled study population controlled for clinical and sociodemographic confounders, including gestational age at birth and, alternatively, either a measure of neurosensory or motor impairment or an interaction term between gestational age at birth and psychiatric disorder. Consequently, we adopted a strategy that disentangled the effects of psychiatric disorders on economic outcomes from those that might be attributable to comorbidities. The study has a number of other strengths. Multi-informant psychiatric data were collected using the DAWBA for all children, rather than a subset identified at high risk, and diagnoses were made by consensus between two expert clinical raters who were masked to group allocation. The DAWBA has excellent reliability and validity Reference Goodman, Ford, Richards, Gatward and Meltzer28 and was the principal measure of psychopathology in the British mental health surveys. Reference Green, McGinnity, Meltzer, Ford and Goodman59 Cognitive ability was assessed by psychologists who achieved ≥95% interrater reliability across standardised tests, and neurosensory function was evaluated by experienced paediatricians. As loss to follow-up was more common among high-risk children, multiple imputation was used to estimate psychiatric diagnoses for 10 of the 331 study children for whom multi-informant psychiatric diagnoses were not performed. Reference Johnson, Hollis, Kochhar, Hennessy, Wolke and Marlow25 Other strengths of the study include validated and reliable approaches to measuring and valuing costs and preference-based health-related quality of life outcomes during childhood and a comprehensive analytical strategy.

There are a number of caveats to the study findings. First, the children included in the EPICure study, but excluded from our analyses because of loss to follow-up, were more likely to have had lower cognitive scores or cognitive impairment at 2.5 and 6 years. This suggests that we might have underestimated the true extent of psychiatric disorders in the study population. Second, the study population was too small to present cost and utility estimates at a granulated level for all childhood psychiatric disorders. A number of disorders, such as panic disorder, agoraphobia, obsessive–compulsive disorder, elective mutism, disinhibited attachment disorder of childhood, reactive attachment disorder, eating disorder, schizophrenia, manic episodes, ADHD hyperactive–impulsive subtype and Asperger syndrome, were not diagnosed in our study population. In addition, individual disorders had to be grouped into relatively broad categories, which might reflect disparate experiences in terms of resource utilisation and health-related quality of life. A much larger study population would be required to estimate costs and health utilities with sufficient statistical power for all childhood psychiatric disorders. Indeed, McClellan and colleagues have argued that a longitudinal study of 10 000 children, consisting of 5000 characterised as at high risk of neurodevelopmental disabilities and 5000 randomly selected from the entire childhood population, is required to generate subtle information for the broad spectrum of conditions. Reference McClellan, Bresnahan, Echeverria, Knox and Susser60 A third caveat to the study findings is that the analysis of cost differences was conducted from a public sector perspective and encompassed costs of health, social and education services. It is likely that many psychiatric disorders have an impact on other sectors of the economy and on families and carers, Reference McCrone, Knapp and Fombonne16 suggesting that adopting a broader perspective would increase the cost differences between the study groups. A fourth caveat is that our cost estimates are based on parental reports of their child's resource utilisation over the previous year of life. Previous research has indicated that parents accurately recall their child's hospital service utilisation over extended periods when validated against medical records, but tend to underreport their child's community service utilisation. Reference Petrou, Murray, Cooper and Davidson61 If this were the case for our study our absolute costs for community service utilisation may be underestimates. A fifth caveat is that, given the large number of children in our study with serious cognitive impairment and learning difficulties, the main parent rather than the child was considered the appropriate person to complete the HUI. Empirical evidence of the concordance between child and parent ratings of attributes of children's health-related quality of life suggests that parents are able to accurately rate observable behaviours, such as physical functioning and physical symptoms, but are less successful at identifying social or emotional impairments. Reference Petrou62,Reference Verrips, Stuifbergen, den Ouden, Bonsel, Gemke and Paneth63 However, there is no consistent evidence to suggest that parents consistently either underreport or overreport social or emotional impairments, Reference Eiser and Morse64 which suggests that there are unlikely to be systematic biases in the measurement of health-related quality of life in our study. A final caveat is that the underlying preference weights for the HUI3 and UK HUI2 multi-attribute utility measures have been derived from surveys of adults rather than of children. Reference Feeny, Furlong, Torrance, Goldsmith, Zhu and DePauw44Reference McCabe, Stevens, Roberts and Brazier46 The cognitive requirements entailed in directly estimating preference weights among our study population, many of whom had developmental disabilities, was considered too burdensome. Nevertheless, our approach of valuing health outcomes using population-based preferences is in line with the recommendations of many decision-making bodies, such as the National Institute for Health and Clinical Excellence in England and Wales. 36

Implications

How might the results of our study be used? Given recent evidence of the increasing incidence of some childhood psychiatric disorders, Reference McClellan, Bresnahan, Echeverria, Knox and Susser60 it is imperative that clinical decision-makers and budgetary and service planners recognise the overall economic impact of each condition in their service planning, as well as the potential contribution of clinical and sociodemographic factors to economic outcomes. More pertinently, in our opinion, our mean cost and utility estimates and their associated distributions can act as data inputs for cost-effectiveness models of preventive or treatment interventions for childhood psychiatric disorders. Economic analysts who construct decision-analytic models are often faced with estimating costs and health utilities for a large number of health conditions or states with limited resources or time. Under these circumstances our catalogue can be viewed as a significant new resource that can act as data inputs or be pooled with the totality of the existing evidence base. It should be noted, however, that analysts may face a particular methodological challenge when the time horizon for the cost-effectiveness model spans the entire period of childhood or further into adulthood. Under these circumstances, the impact of age on costs and health utilities should be estimated from data gathered in large-scale longitudinal studies as they become available. When such data are not available, techniques such as meta-regression of data across a number of studies should be considered as a means of disentangling the impact of age.

Acknowledgements

We are indebted to the EPICure Study Group, which includes paediatricians in 276 maternity units in the UK and Republic of Ireland who identified the original cohort, contributed perinatal data and whose help was invaluable. We would also like to thank the children who participated in the EPICure Study and the parents who completed the relevant research instruments.

Footnotes

The EPICure Study was funded by the Medical Research Council, UK. S.P. was funded by a MRC Senior Non-Clinical Research Fellowship during the course of this study.

Declaration of interest

None.

References

1 Roberts, R. Prevalence of psychopathology among children and adolescents. Am J Psychiatry 1998; 155: 715–25.Google ScholarPubMed
2 Meltzer, H, Gatward, R, Goodman, R, Ford, T. Mental health of children and adolescents in Great Britain. Int Rev Psychiatry 2003; 15: 185–7.CrossRefGoogle ScholarPubMed
3 Costello, EJ, Mustillo, S, Erkanli, A, Keeler, G, Angold, A. Prevalence and development of psychiatric disorders in childhood and adolescence. Arch Gen Psychiatry 2003; 60: 837–44.CrossRefGoogle ScholarPubMed
4 Kovacs, M, Feinberg, TL, Crouse-Novak, M, Palauskas, SL, Finkelstein, R. Depressive disorders in childhood: I. A longitudinal prospective study of characteristics and recovery. Arch Gen Psychiatry 1984; 41: 229–37.Google Scholar
5 Kovacs, M, Feinberg, TL, Crouse-Novak, M, Palauskas, SL, Pollack, M, Finkelstein, R. Depressive disorders in childhood: II. A longitudinal study of the risk for a subsequent major depression. Arch Gen Psychiatry 1984; 41: 643–9.Google Scholar
6 Weiss, G, Hechtman, L, Milroy, T, Perlman, T. Psychiatric status of hyperactives as adults: a controlled prospective 15-year follow-up of 63 hyperactive children. J Am Acad Child Psychiatry 1985; 24: 211–20.CrossRefGoogle ScholarPubMed
7 Lambert, N. Adolescent outcomes for hyperactive children. Am Psychol 1988; 43: 786–99.CrossRefGoogle ScholarPubMed
8 Keller, MB, Lavori, PW, Wunder, J, Beardslee, WR, Schwartz, CE, Roth, J. Chronic course of anxiety disorders in children and adolescents. J Am Acad Child Psychiatry 1992; 31: 595–99.Google ScholarPubMed
9 Cohen, P, Cohen, J, Brook, J. An epidemiological study of disorders in late childhood and adolescence: II. Persistence of disorders. J Child Psychol Psychiatry 1993; 34: 869–77.Google ScholarPubMed
10 Cohen, P, Cohen, J, Kasen, S, Velez, CN, Hartmarh, C, Johnson, J, et al. An epidemiological study of disorders in late childhood and adolescence: I. Age- and gender-specific prevalence. J Child Psychol Psychiatry 1993; 34: 851–67.Google ScholarPubMed
11 Fergusson, DM, Horwood, LJ, Lynskey, MT. Prevalence and comorbidity of DSM-III-R diagnoses in a birth cohort of 15 year olds. J Am Acad Child Psychiatry 1993; 32: 1127–34.CrossRefGoogle Scholar
12 Loeber, R, Green, S, Keenan, K, Lahey, BB. Which boys will fare worse? Early predictors of the onset of conduct disorder in a six-year longitudinal study. J Am Acad Child Psychiatry 1995; 34: 499509.CrossRefGoogle Scholar
13 Mannuzza, S, Klein, RG, Bessler, A, Malloy, P, LaPadula, M. Adult psychiatric status of hyperactive boys grown up. Am J Psychiatry 1998; 155: 493–8.CrossRefGoogle ScholarPubMed
14 Biederman, J, Monuteaux, MC, Mick, E, Spencer, T, Wilens, TE, Silva, JM, et al. Young adult outcome of attention deficit hyperactivity disorder: a controlled 10-year follow-up study. Psychol Med 2006; 36: 167–79.CrossRefGoogle ScholarPubMed
15 Giaconia, RM, Reinberg, HZ, Silverman, AB, Pakiz, B, Frost, AK, Cohen, E. Age on onset of psychiatric disorders in a community population of older adolescents. J Am Acad Child Psychiatry 1994; 33: 706–17.CrossRefGoogle Scholar
16 McCrone, P, Knapp, M, Fombonne, E. The Maudsley long-term follow-up of child and adolescent depression: predicting costs in adulthood. Eur Child Adolesc Psychiatry 2005; 14: 407–13.CrossRefGoogle ScholarPubMed
17 Bodden, DH, Dirksen, CD, Bögels, SM. Societal burden of clinically anxious youth referred for treatment: a cost-of-illness study. J Abnorm Child Psychol 2008; 36: 487–97.CrossRefGoogle ScholarPubMed
18 Leibson, CL, Long, KH. Economic implications of attention-deficit hyperactivity disorder for healthcare systems. Pharmacoeconomics 2003; 21: 1239–62.CrossRefGoogle ScholarPubMed
19 Matza, LS, Secnik, K, Rentz, AM, Mannix, S, Sallee, FR, Gilbert, D, et al. Assessment of health state utilities for attention-deficit/hyperactivity disorder in children using parent proxy report. Qual Life Res 2005; 14: 735–47.CrossRefGoogle ScholarPubMed
20 Petrou, S, Kupek, E. Estimating preference-based Health Utilities Index Mark 3 utility scores for childhood conditions in England and Scotland. Med Decis Making 2009; 29: 291303.CrossRefGoogle Scholar
21 Wood, NS, Marlow, N, Costeloe, K, Gibson, AT Wilkinson AR for the EPICure Study Group. Neurologic and developmental disability after extremely preterm birth. New Engl J Med 2000; 343: 378–84.CrossRefGoogle ScholarPubMed
22 Botting, N, Powls, A, Cooke, R, Marlow, N. Attention deficit hyperactivity disorder and other psychiatric outcomes in very low birthweight children at 12 years. J Child Psychol Psychiatry 1997; 38: 931–41.CrossRefGoogle Scholar
23 Elgen, I, Sommerfelt, K, Markestad, T. Population based, controlled study of behavioural problems and psychiatric disorders in low birthweight children at 11 years of age. Arch Dis Child Fetal Neonatal Ed 2002; 87: F12832.CrossRefGoogle Scholar
24 Indredavik, MS, Vik, T, Heyerdahl, S, Kulseng, S, Fayers, P, Brubakk, AM. Psychiatric symptoms and disorders in adolescents with low birth weight. Arch Dis Child Fetal Neonatal Ed 2004; 89: F44550.CrossRefGoogle ScholarPubMed
25 Johnson, S, Hollis, C, Kochhar, P, Hennessy, E, Wolke, D, Marlow, N. Psychiatric disorders in extremely preterm children: longitudinal finding at age 11 years in the EPICure study. J Am Acad Child Adolesc Psychiatry 2010; 49: 453–63.Google ScholarPubMed
26 Marlow, N, Wolke, D, Bracewell, MA, Samara M for the EPICure Study Group. Neurologic and developmental disability at six years of age after extremely preterm birth. New Engl J Med 2005; 352: 919.CrossRefGoogle ScholarPubMed
27 Johnson, S, Hennessy, EM, Smith, R, Trikic, R, Wolke, D, Marlow, N. Academic attainment and special educational needs in extremely preterm children at 11 years of age: the EPICure Study. Arch Dis Child Fetal Neonatal Ed 2009; 94: F2839.CrossRefGoogle ScholarPubMed
28 Goodman, R, Ford, T, Richards, H, Gatward, R, Meltzer, H. The Development and Well-Being Assessment: description and initial validation of an integrated assessment of child and adolescent psychopathology. J Child Psychol Psychiatry 2000; 41: 645–55.CrossRefGoogle ScholarPubMed
29 World Health Organization. The ICD-10 Classification of Mental and Behavioural Disorders. World Health Organization, 1992.Google Scholar
30 American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders (4th edn) (DSM–IV). APA, 1994.Google Scholar
31 American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders (4th edn) Text Revision (DSM–IV–TR). APA, 2000.Google Scholar
32 Kaufman, AS, Kaufman, NL. Kaufman Assessment Battery for Children. American Guidance Service, 1983.Google Scholar
33 Wolke, D, Ratschinski, G, Ohrt, B, Riegel, K. The cognitive outcome of very preterm infants may be poorer than often reported: an empirical investigation of how methodological issues make a big difference. Eur J Pediatr 1994; 153: 906–15.CrossRefGoogle ScholarPubMed
34 Allen, C, Beecham, J. Costing services: ideals and reality. In Costing Community Care: Theory and Practice (eds Netten, A, Beecham, J): 2542. Ashgate Publishing, 1993.Google Scholar
35 Drummond, MF, Sculpher, MJ, Torrance, GW, O'Brien, BJ, Stoddart, GL. Methods for the Economic Evaluation of Health Care Programmes, 3rd edn. Oxford University Press, 2005.CrossRefGoogle Scholar
36 National Institute for Health and Clinical Excellence. Guide to the Methods of Technology Appraisal. NICE, 2008.Google Scholar
37 Department of Health, England. NHS Reference Costs 2006–07. The Information Centre, Department of Health, 2007.Google Scholar
38 Curtis, L. Unit Costs of Health and Social Care. Personal Social Services Research Unit (PSSRU), University of Kent, 2007.Google Scholar
39 Paediatric Formulary Committee. BNF for Children, 2007. BMJ Publishing Group, Pharmaceutical Press, and RCPCH Publications, 2007.Google Scholar
40 Torrance, GW, Furlong, W, Feeny, D, Boyle, M. Multi-attribute preference functions: Health Utilities Index. Pharmacoeconomics 1995; 7: 503–20.CrossRefGoogle ScholarPubMed
41 Eiser, C, Morse, R. Quality-of-life measures in chronic diseases of childhood. Health Technol Assess 2001; 5: 1156.CrossRefGoogle ScholarPubMed
42 Furlong, WJ, Feeny, DH, Torrance, GW, Barr, RD. The Health Utilities Index (HUI) system for assessing health-related quality of life in clinical studies. Ann Med 2001; 33: 375–84.CrossRefGoogle ScholarPubMed
43 Horsman, J, Furlong, W, Feeny, D, Torrance, GW. The Health Utilities Index (HUI): concepts, measurement properties and applications. Health Qual Life Outcomes 2003; 1: 54.CrossRefGoogle ScholarPubMed
44 Feeny, D, Furlong, W, Torrance, GW, Goldsmith, CH, Zhu, Z, DePauw, S, et al. Multiattribute and single-attribute utility functions for the Health Utilities Index Mark 3 system. Med Care 2002; 40: 113–28.CrossRefGoogle ScholarPubMed
45 Furlong, W, Feeny, D, Torrance, GW, Goldsmith, CH, DePauw, S, Zhu, Z, et al. Multiplicative Multi-attribute Utility Function for the Health Utilities Index Mark 3 (HUI3) System: A Technical Report. Working Paper 98–11. Centre for Health Economics and Policy Analysis, McMaster University, Canada, 1998.Google Scholar
46 McCabe, C, Stevens, K, Roberts, J, Brazier, J. Health state values for the HUI 2 descriptive system: results from a UK survey. Health Econ 2005; 14: 231–44.CrossRefGoogle ScholarPubMed
47 Schafer, JL. Multiple imputation: a primer. Stat Methods Med Res 1999; 8: 315.CrossRefGoogle ScholarPubMed
48 Briggs, A, Clark, T, Wolstenholme, J, Clarke, P. Missing … presumed at random: cost-analysis of incomplete data. Health Econ 2003; 12: 377–92.CrossRefGoogle ScholarPubMed
49 Gray, A, Wolstenholme, J, Wordsworth, S, Clarke, P. Applied Methods of Cost-Effectiveness Analysis. Oxford University Press, 2010.Google Scholar
50 Barber, JA, Thompson, SG. Analysis of cost data in randomized trials: an application of the non-parametric bootstrap. Stat Med 2000; 19: 219–36.3.0.CO;2-P>CrossRefGoogle ScholarPubMed
51 Briggs, A, Claxton, K, Sculpher, M. Decision Modelling for Health Economic Evaluation. Oxford University Press, 2006.CrossRefGoogle Scholar
52 Johnson, S, Fawke, J, Hennessy, E, Rowell, V, Thomas, S, Wolke, D, et al. Neurodevelopmental disability through 11 years of age in children born before 26 weeks of gestation. Pediatrics 2009; 124: e24957.CrossRefGoogle ScholarPubMed
53 Greene, WH. Econometric Analysis, 5th edn. Prentice Hall, 2003.Google Scholar
54 Ungar, W. Economic Evaluation in Child Health. Oxford University Press, 2009.CrossRefGoogle Scholar
55 To, T, Dell, S, Dick, P, Cicutto, L. The burden of illness experienced by young children associated with asthma: a population-based cohort study. J Asthma 2008; 45: 45–9.CrossRefGoogle ScholarPubMed
56 Thornton, J, Lunt, M, Ashcroft, DM, Baildam, E, Foster, H, Davidson, J, et al. Costing juvenile idiopathic arthritis: examining patient-based costs during the first year after diagnosis. Rheumatology 2008; 47: 985–90.CrossRefGoogle ScholarPubMed
57 Drummond, M. Introducing economic and quality of life measurements into clinical studies. Ann Med 2001; 33: 344–9.CrossRefGoogle ScholarPubMed
58 Feeny, D, Furlong, W, Saigal, S, Sun, J. Comparing directly measured standard gamble scores to HUI2 and HUI3 utility scores: group- and individual-level comparisons. Soc Sci Med 2004; 58: 799809.CrossRefGoogle ScholarPubMed
59 Green, H, McGinnity, A, Meltzer, H, Ford, T, Goodman, R. Mental Health of Children and Young People in Great Britain, 2004. Office for National Statistics, 2004.Google Scholar
60 McClellan, J, Bresnahan, MA, Echeverria, D, Knox, SS, Susser, E. Approaches to psychiatric assessment in epidemiological studies of children. J Epidemiol Community Health 2009; 63: i4i14.CrossRefGoogle ScholarPubMed
61 Petrou, S, Murray, L, Cooper, P, Davidson, LL. The accuracy of self-reported health care resource utilization in health economic studies. Int J Technol Assess Health Care 2002; 18: 705–10.CrossRefGoogle ScholarPubMed
62 Petrou, S. Methodological issues raised by preference-based approaches to measuring the health status of children. Health Econ 2003; 12: 697702.CrossRefGoogle ScholarPubMed
63 Verrips, GHW, Stuifbergen, MC, den Ouden, LA, Bonsel, GJ, Gemke, RJ, Paneth, N, et al. Measuring health status using the Health Utility Index: agreement between raters and between modalities of administration. J Clin Epidemiol 2001; 54: 475–81.CrossRefGoogle ScholarPubMed
64 Eiser, C, Morse, R. Quality-of-life measures in chronic diseases of childhood. Health Technol Assess 2001; 5: 1156.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Mean public sector costs over the previous year of life and mean cost differences between children with and without psychiatric disorders (UK £ sterling, 2006–7 prices)

Figure 1

Table 2 Relationship between psychiatric disorders and public sector costs (UK £ sterling, 2006–7 prices) over the previous year of life, generalised linear models with gamma distribution and linear (identity) link function

Figure 2

Table 3 Health Utilities Index Mark 3 multi-attribute utility scores for children with and without psychiatric disorders

Figure 3

Table 4 Health Utilities Index UK Mark 2 multi-attribute utility scores for children with and without psychiatric disorders

Figure 4

Table 5 Relationship between psychiatric disorders and Health Utilities Index Mark 3 multi-attribute utility scores, Tobit regressions

Figure 5

Table 6 Relationship between psychiatric disorders and UK Health Utilities Index Mark 2 multi-attribute utility scores, Tobit regressions

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