Introduction
The initial onset of common mental health conditions, such as depression and/or anxiety, often occurs during adolescence between the ages of 10 and 19 years (Solmi et al., Reference Solmi, Radua, Olivola, Croce, Soardo, Salazar de Pablo, Il Shin, Kirkbride, Jones, Kim, Kim, Carvalho, Seeman, Correll and Fusar-Poli2022). Additionally, the rate of suicide deaths rapidly increases during adolescence and is the fourth leading cause of death among young people, with 88% of adolescent suicides occurring in low- and middle-income countries (WHO, 2021c). Important mental health risk factors at this age include adverse experiences (e.g., family violence, bullying) (Patton et al., Reference Patton, Sawyer, Santelli, Ross, Afifi, Allen, Arora, Azzopardi, Baldwin, Bonell, Kakuma, Kennedy, Mahon, McGovern, Mokdad, Patel, Petroni, Reavley, Taiwo, Waldfogel, Wickremarathne, Barroso, Bhutta, Fatusi, Mattoo, Diers, Fang, Ferguson, Ssewamala and Viner2016); alcohol and substance use (Esmaeelzadeh et al., Reference Esmaeelzadeh, Moraros, Thorpe and Bird2018); and as highlighted during the COVID-19 pandemic, isolation from social networks and activities (Munasinghe et al., Reference Munasinghe, Sperandei, Freebairn, Conroy, Jani, Marjanovic and Page2020). Preventing the occurrence of depression/anxiety and suicidal behaviours during this crucial developmental stage can lead to substantive health gains throughout a person’s life (de Girolamo et al., Reference de Girolamo, Dagani, Purcell, Cocchi and McGorry2012).
School settings are an important platform for delivering mental health prevention/promotion interventions among adolescents (Fazel et al., Reference Fazel, Hoagwood, Stephan and Ford2014a, Reference Fazel, Patel, Thomas and Tol2014b). School-based interventions to prevent mental health conditions and/or suicide typically involve a trained facilitator (e.g., teacher or health professional) delivering several intervention modules that teach young people psychological strategies to improve their mental well-being and reduce the risk of adverse mental health outcomes. Current evidence indicates that school-based socio-emotional learning (SEL) programs are effective in reducing the incidence of depression/anxiety and suicidal behaviours among adolescent students (Hetrick et al., Reference Hetrick, Cox, Witt, Bir and Merry2016; Skeen et al., Reference Skeen, Laurenzi, Gordon, du Toit, Tomlinson, Dua, Fleischmann, Kohl, Ross, Servili, Brand, Dowdall, Lund, van der Westhuizen, Carvajal-Aguirre, Eriksson de Carvalho and Melendez-Torres2019; Wasserman et al., Reference Wasserman, Hoven, Wasserman, Wall, Eisenberg, Hadlaczky, Kelleher, Sarchiapone, Apter, Balazs, Bobes, Brunner, Corcoran, Cosman, Guillemin, Haring, Iosue, Kaess, Kahn, Keeley, Musa, Nemes, Postuvan, Saiz, Reiter-Theil, Varnik, Varnik and Carli2015). These programs have been included in recent guidelines published by the World Health Organization (WHO) on mental health promotion and preventive interventions for adolescents (WHO, 2020) and the prevention of suicide (WHO, 2021a, 2022). Two categories of school-based SEL programs include (1) universal interventions, which target all students regardless of their underlying risk profile, and (2) indicated interventions, which target students with an elevated risk of depression, anxiety and/or suicide completion (Mrazek and Haggerty, Reference Mrazek and Haggerty1994). Students eligible for an indicated intervention are identified (via individual screening that involves scoring a checklist of mental health symptoms or indicators of suicide risk) as having a subthreshold mental health condition – that is, clinically relevant symptoms that fall short of diagnostic criteria for mental illness. Indicated SEL interventions often produce larger intervention effect sizes than universal SEL interventions (Hetrick et al., Reference Hetrick, Cox, Witt, Bir and Merry2016). However, this increased efficacy is offset by the large costs involved in screening for subthreshold cases and the smaller aggregate health impacts, accruing to a narrow subset of the adolescent population (Lee et al., Reference Lee, Barendregt, Stockings, Ferrari, Whiteford, Patton and Mihalopoulos2017).
In May 2019, the 72nd World Health Assembly passed a resolution requesting the WHO Director-General to prepare and update a menu of policy options and cost-effective interventions for improving mental health (WHO, 2021d). This menu of policy options has informed an update of the WHO comprehensive mental health action plan 2013–2020 (WHO, 2013). This study presents the results of an economic evaluation undertaken as part of the aforementioned update to examine the cost-effectiveness of delivering universal and indicated school-based SEL programs to prevent depression/anxiety and suicidal behaviours, among adolescent students across different country contexts. This study contributes to the ongoing generation of comparative economic evidence for population-wide, as well as clinical-level, mental health interventions (WHO, 2021d). In the context of recent COVID-19 pandemic response and recovery efforts, it also addresses urgent policy questions around how, where and ‘at what cost’ countries can roll out enhanced levels of mental health awareness and support to affected adolescent populations.
Methods
Analytic approach
This study adopted a health systems perspective in accordance with the World Health Organization CHOosing Interventions that are Cost-Effective (WHO-CHOICE) methods (Bertram et al., Reference Bertram, Lauer, Stenberg and Edejer2021a). WHO-CHOICE is a program of work that helps countries to identify healthcare priorities based on health impacts and cost-effectiveness (Bertram and Edejer, Reference Bertram and Edejer2021). All healthcare options are compared to a common comparator, a null scenario in which the impacts of currently implemented interventions are removed, thereby enabling comparison of interventions across geographical areas and domains of health. Analytic choices arising from the implementation of WHO-CHOICE methods are briefly presented here, with detailed methods provided in Appendix S1. A Markov model was developed in Microsoft Excel 2019 to examine the costs and health impacts of scaling up the delivery of universal and indicated school-based SEL programs. Universal and indicated SEL programs comprised the delivery of several SEL program components (or intervention modules) that are effective in preventing the onset of depression/anxiety and suicidal behaviour (Skeen et al., Reference Skeen, Laurenzi, Gordon, du Toit, Tomlinson, Dua, Fleischmann, Kohl, Ross, Servili, Brand, Dowdall, Lund, van der Westhuizen, Carvajal-Aguirre, Eriksson de Carvalho and Melendez-Torres2019; Wasserman et al., Reference Wasserman, Hoven, Wasserman, Wall, Eisenberg, Hadlaczky, Kelleher, Sarchiapone, Apter, Balazs, Bobes, Brunner, Corcoran, Cosman, Guillemin, Haring, Iosue, Kaess, Kahn, Keeley, Musa, Nemes, Postuvan, Saiz, Reiter-Theil, Varnik, Varnik and Carli2015). Delivery of the universal SEL program encompassed all secondary school students aged 12–17 years, while delivery of the indicated SEL program targeted at-risk school students identified as having subthreshold depression/anxiety following screening. Analyses were conducted on a group of 20 countries from different regions and income levels (that between them account for >80% of the global population and global burden of mental health conditions) (WHO, 2021d). Aggregated results are presented for two country income groups: low- to lower middle-income countries (LLMICs) and upper middle- to high-income countries (UMHICs). Table 1 lists the 20 countries by country income group, alongside other relevant data.
Country-specific costs were obtained from the WHO-CHOICE database and denominated in 2017 international dollars (2017 I$) (Bertram et al., Reference Bertram, Stenberg, Brindley, Li, Serje, Watts and Edejer2017). In accordance with WHO-CHOICE methods, all costs were discounted at a 3% annual rate, with no discounting applied to health impacts while healthcare cost savings and changes in workforce productivity were out of scope (Bertram et al., Reference Bertram, Lauer, Stenberg and Edejer2021a). The model did not evaluate impacts on future employment outcomes that result from enhanced educational outcomes due to improved adolescent mental health. Intervention health impacts were measured in healthy life years gained (HLYGs). Costs and health impacts were analysed for each of the 20 countries at the country-specific level, with the final results aggregated and presented by country income group (i.e., LLMICs and UMHICs). The main study outcome was the average cost-effectiveness ratio, expressed as the total intervention cost (2017 I$) divided by the incremental HLYGs produced by the intervention when compared to no intervention.
The modelling approach was refined following consultations with an international expert panel who provided in-person feedback at a meeting held at WHO headquarters office in Geneva on August 21, 2019, and through out-of-session email communications (see Acknowledgements). This study adhered to Consolidated Health Economic Evaluation Reporting Standards (CHEERS) (see Appendix S2) (Husereau et al., Reference Husereau, Drummond, Petrou, Carswell, Moher, Greenberg, Augustovski, Briggs, Mauskopf, Loder and Force2013).
Demographic projections
The demographic projection model (Fig. 1) begins with the country population in the 2017 baseline year, split by 1-year age group and sex. Flows in and out of each age–sex cohort were simulated for each subsequent year over 100 years. These flows included outflows due to death (suicide or other causes), inflows in the 0- to 1-year age cohort due to new births, and net migration. Data on the 2017 country population between ages 0 and 80+ years and corresponding age-specific mortality rates over the 100-year time horizon were obtained from OneHealth Tool (Avenir Health, 2022). Data on new births and net migration were obtained from the UN World Population Prospects 2017 (WPP 2017) report (UN DESA, 2017). All demographic projections were validated against WPP 2017 estimates. See Appendix S3 for further details.
Intervention coverage
Universal and indicated school-based SEL programs were modelled with a population coverage of 95% among adolescents aged 12–17 years. Country-specific adjustments were then made to exclude adolescents who do not attend secondary school (UIS, 2022). Under the indicated SEL program, intervention coverage was further restricted to students with subthreshold depression/anxiety – around 5% of adolescents (Bertha and Balazs, Reference Bertha and Balazs2013; Carrellas et al., Reference Carrellas, Biederman and Uchida2017; Haller et al., Reference Haller, Cramer, Lauche, Gass and Dobos2014). See Appendix S3 for further details.
Intervention effect sizes
The model quantified the impact of universal and indicated school-based SEL programs in reducing the incidence of depression/anxiety and suicide mortality among adolescents. It was assumed that universal and indicated SEL programs encompassed a modular design, such that both programs incorporated evidence-based program components that are efficacious in reducing the risk of depression/anxiety and suicide deaths. The intervention effect size for depression/anxiety incidence was based on a meta-analysis of studies examining the efficacy of universal and indicated SEL programs to reduce depression and/or anxiety symptoms among adolescents. The meta-analysis comprised 29 universal and 31 indicated studies gathered from a previous systematic review (Skeen et al., Reference Skeen, Laurenzi, Gordon, du Toit, Tomlinson, Dua, Fleischmann, Kohl, Ross, Servili, Brand, Dowdall, Lund, van der Westhuizen, Carvajal-Aguirre, Eriksson de Carvalho and Melendez-Torres2019). The universal SEL program produced a standardized mean difference (SMD) of −0.10 (95% CI: −0.17 to −0.04) in reducing depression/anxiety symptoms at 1-year follow-up, while the indicated SEL program produced an SMD of −0.19 (95% CI: −0.33 to −0.05). Effect sizes attenuated completely after 1-year follow-up, a finding consistent with other studies (Hetrick et al., Reference Hetrick, Cox, Witt, Bir and Merry2016; Stockings et al., Reference Stockings, Degenhardt, Dobbins, Lee, Erskine, Whiteford and Patton2016). The Cochrane conversion method (see Appendix S4) was used to transform SMD effect sizes into corresponding relative risk (RR) effect sizes (Lee et al., Reference Lee, Le, Stockings, Hay, Whiteford, Barendregt and Mihalopoulos2018). The universal SEL program led to an RR of 0.84 (95% CI: 0.75 to 0.94), while the indicated SEL program produced an RR of 0.73 (95% CI: 0.57 to 0.93).
The intervention effect size for suicide mortality was based on a meta-analysis of three studies identified by a WHO review (WHO, 2015) that contributed to an update of mhGAP evidence-based guidelines (WHO, 2022). School-based SEL programs produced an RR of 0.65 (95% CI: 0.51 to 0.83) in reducing suicide attempts after 1-year follow-up. Appendix S5 presents a mathematical proof demonstrating how post-intervention reductions in suicide mortality can be estimated using an effect size involving suicide attempts. To summarize, if the case fatality proportion of suicide attempts is assumed to be constant before and after an intervention, then it is possible to directly apply the effect size for suicide attempts to suicide mortality. Following feedback from the international expert panel, a lower intervention effect size was adopted by using the upper confidence interval bound as the point estimate – a conservative modelling choice. Both universal and indicated school-based SEL programs were subsequently estimated to produce an RR of 0.83 (95% CI: 0.70 to 0.99) in reducing suicide mortality after 1-year follow-up. The derivation of intervention effect sizes is further described in Appendix S3.
Health impact modelling
The state transition diagram in Fig. 2 outlines how each age–sex cohort in the model transitions between health states over time. Country-specific data on suicide mortality and the epidemiology of depression and anxiety (i.e., prevalence, incidence and remission) were obtained by age and sex from Global Burden of Disease Study 2017 (GBD 2017) (IHME, 2022). The dependent comorbidity method (Mathers et al., Reference Mathers, Iburg and Begg2006) was used to combine separate estimates on the epidemiology of ‘depression’ and ‘anxiety’ into a single estimate on the epidemiology of ‘depression and/or anxiety’ (see Appendix S6). The prevalence of depression/anxiety determined the number of people in the ‘depression/anxiety’ health state at baseline, while the ‘at-risk’ health state included those without a diagnosis of depression/anxiety. The Markov model estimated the annual numbers of people who had an incident case of depression/anxiety, remitted, died from suicide, or died from other causes over time.
Post-intervention outcomes of interest included a reduction in the total number of incident depression/anxiety cases and suicide deaths. Intervention effect sizes were applied to the incidence of depression/anxiety and suicide mortality linked to the ‘at-risk’ and ‘depression/anxiety’ health states. The ‘at-risk’ health state comprised all school students aged 12–17 years in the universal program and all students aged 12–17 years with subthreshold depression/anxiety in the indicated program. Intervention effect sizes were applied for a total post-intervention duration of 1 year. Age–sex cohorts that remained in school (up to age 17 years) would receive the full intervention effect for another year, following repeated exposure to the universal/indicated SEL program. The impact of variations in participant engagement and/or adherence were not explicitly accounted for in the model. Nevertheless, the influence of engagement/adherence was implicitly incorporated as part of the intervention effect sizes, which reflect the levels of engagement/adherence that are observed across the different studies included in each respective meta-analysis.
Intervention health impacts were summarized using the HLYGs measure, which is equivalent to averted disability-adjusted life years and is made up of years of life lost (YLL) and years lived with disability (YLDs). YLLs were estimated for each age–sex cohort by taking the number of deaths in a particular year and multiplying this by potential YLL. Potential YLLs were calculated as the lowest value of either the difference between the current age of the cohort and the average life expectancy in the country or the difference between the current age of the cohort and the remaining time before the end of the 100-year model time horizon. YLDs were estimated for each age–sex cohort by calculating the total number of depression/anxiety cases occurring in a year and multiplying this by the disability weight for depression/anxiety – which was estimated by combining the GBD 2017 disability weights for depression and anxiety (IHME, 2022), while accounting for dependent comorbidity (Mathers et al., Reference Mathers, Iburg and Begg2006). Further details on health impact modelling are provided in Appendix S3.
Costing analysis
The costing framework and methods developed by WHO-CHOICE were used to estimate the country-specific costs of scaling up universal/indicated school-based SEL programs (Bertram et al., Reference Bertram, Lauer, Stenberg and Edejer2021a). Country-specific intervention costs were estimated using previous costing templates developed by WHO to evaluate noncommunicable disease (NCD) prevention and control policies and interventions (WHO, 2011, 2017). These NCD costing templates were modified to account for program-related costs involved in implementing universal/indicated SEL programs (e.g., program management, advocacy, training, program delivery, supplies and equipment). Templates also accounted for four stages of policy development: the planning stage (year 1), policy development (year 2), partial implementation (years 3–5) and full implementation (year 6 onwards). Universal and indicated SEL programs were both delivered by program facilitators via group sessions occurring in the classroom. Face-to-face intervention delivery was deemed the most appropriate modality for scaling up these programs in resource-constrained settings. Data from studies included in the prior meta-analysis of intervention effect sizes were used to estimate resource use associated with program delivery (e.g., time required to train program facilitators and total contact time with students). The indicated SEL program further encompassed time spent by facilitators to screen students for subthreshold depression/anxiety using locally validated mental health questionnaires. See Appendix S7 for further details.
Uncertainty analysis and sensitivity analysis
Uncertainty analyses were conducted to quantify the impact of input parameter uncertainty on the final cost-effectiveness results. Ersatz software (version 1.31, Brisbane, Australia; available at: http://www.epigear.com/) was used to perform Monte Carlo simulation with 1,000 iterations and produce results with 95% uncertainty intervals (95% UI). Univariate deterministic sensitivity analyses were conducted to test how cost-effectiveness ratios in the base case analysis would change following a 10% increase/decrease in the mean value of each input parameter (up to 425 in total) when varied one-by-one. Multivariate probabilistic sensitivity analyses were done to analyse the strength of association (measured using Spearman’s rank correlation coefficient, r s) between each input parameter on the resulting cost-effectiveness ratio, while simultaneously accounting for interactions between other input parameters. Univariate and multivariate sensitivity analyses make known which input parameters have the greatest impact on the cost-effectiveness ratio. They highlight which input parameters need to be estimated with greater precision to reduce uncertainty around the final result. Additional sensitivity analyses were performed to examine how cost-effectiveness ratios would change after (1) excluding the intervention effect size for suicide mortality and (2) applying different annual discount rates to health impacts (i.e., 3% and 6%, instead of 0%) and intervention costs (i.e., 0% and 6%, instead of 3%). A threshold analysis was also done to examine the effect of incrementally reducing both of the intervention effect sizes applied to depression/anxiety cases and suicide deaths from 0% to 100% (with a reduction of 100% equating to an RR of 1.00).
Results
The model estimated that the total intervention cost of scaling up the universal school-based SEL program would be I$0.096 per capita among LLMICs and I$0.162 per capita among UMHICs. Across the 20 countries, the universal SEL program could potentially avert an additional 742 depression/anxiety cases and 0.581 suicides per 1 million population. By comparison, the total intervention cost for the indicated school-based SEL program would be I$0.060 per capita among LLMICs and I$0.084 per capita among UMHICs. Across the 20 countries, the indicated SEL program could avert an additional 45 depression/anxiety cases and 0.017 suicides per 1 million population. The total cost of scaling up universal and indicated SEL programs was comparable to other low-cost, clinical interventions for the treatment of common mental disorders. For example, a previous WHO-CHOICE analysis estimated that the total cost of scaling up basic psychosocial support for depression and anxiety ranged between I$0.115 and I$0.159 per capita (WHO, 2013).
A summary of population-standardized results for the base case analysis is shown in Table 2. When analysing the universal SEL program, the cost-effectiveness ratio was estimated to be I$958 per HLYG among LLMICs and I$2,006 per HLYG among UMHICs. When analysing the indicated SEL program, the cost-effectiveness ratio was much larger at I$11,123 per HLYG among LLMICs and I$18,473 per HLYG among UMHICs. Absolute results that were not population-standardized are shown in Appendix S8. These results are presented alongside detailed breakdowns of YLDs, YLLs and the total number of depression/anxiety cases and suicide deaths averted (expressed in absolute and population-standardized units).
Abbreviations: 95% UI, 95% uncertainty interval; CE, cost-effectiveness; HLYG, healthy life year gained; I$, international dollars; LLMICs, low- to lower middle-income countries; UMHICs, upper middle- to high-income countries.
a Per 1 million population per year.
The majority of aggregate health impacts (measured in terms of HLYGs) were attributable to YLDs averted due to the prevention of depression/anxiety cases, rather than YLLs averted due to the prevention of suicides. For example, across the 20 countries, YLDs averted represented 83.9% of total HLYGs for the universal SEL program and 91.3% of total HLYGs for the indicated SEL program. The small proportion of health gains attributable to averted suicides is explained by the comparatively smaller (absolute) number of suicide deaths that occur among adolescents, when compared to incident cases of depression/anxiety. The indicated SEL program was much less cost-effective when compared to the universal SEL program. This was due to the large costs involved with screening students, alongside health impacts accruing to a narrow subset of students.
The results of the univariate and multivariate sensitivity analyses are presented, respectively, in Appendix S9 and S10. The cost-effectiveness ratio for the universal SEL program was highly sensitive to changes in the intervention effect size applied to depression/anxiety cases, the intervention effect size applied to suicide deaths, and the disability weight for depression/anxiety. In addition to these same parameters, the cost-effectiveness ratio for the indicated SEL program was highly sensitive to changes in the increased risk of developing depression/anxiety among individuals with subthreshold depression/anxiety and the prevalence of subthreshold depression/anxiety. Additional sensitivity analyses (see Table 3) found that cost-effectiveness ratios for the universal and indicated SEL programs marginally increased (i.e., were slightly less cost-effective) when excluding the intervention effect size for suicide mortality and greatly increased (i.e., were much less cost-effective) when using a 6% discount rate for health impacts. The results of the threshold analysis are presented in Appendix S11. Cost-effectiveness ratios for the universal SEL program remained below I$5,000 per HLYG after intervention effect sizes decreased by 80% among LLMICs and 59% among UMHICs. By contrast, cost-effectiveness ratios for the indicated SEL program remained below I$50,000 per HLYG following a 77% and 63% reduction in intervention effect sizes among LLMICs and UMHICs, respectively.
Abbreviations: 95% UI, 95% uncertainty interval; CE, cost-effectiveness; HLYG, healthy life year gained; I$, international dollars; LLMICs, low- to lower middle-income countries; UMHICs, upper middle- to high-income countries.
a The base case scenario applied a discount rate of 0% to health impacts and 3% to intervention costs.
Discussion
Summary of findings
This study aimed to identify the expected population-level costs and health impacts of implementing universal and indicated school-based SEL programs at scale in secondary schools. The results suggest that implementation costs for both are similarly modest, ranging from an annual per capita investment of I$0.10 in LLMICs to I$0.16 in UMHICs for the universal SEL program and I$0.06 in LLMICs to I$0.09 in UMHICs for the indicated SEL program. However, the universal SEL program generated 20 times as much population health gain (e.g., 100 HLYGs per 1 million population were generated by universal SEL in LLMICs compared to 5 for indicated SEL). Considering costs and effects together, the cost per HLYG for the universal SEL program was just below I$1,000 in LLMICS (I$958) and one order of magnitude higher in UMHICs (I$2,006), whereas the average cost-effectiveness ratio for the indicated SEL program was substantially higher than that of the universal SEL program (I$11,123 and I$18,473 in LLMICs and UMHICs, respectively).
These cost-effectiveness results can be contextualized by referencing other health interventions for which equivalent data are available. For instance, the cost per HLYG associated with increased excise taxes on tobacco or alcoholic beverages is in the range of I$100 in LLMICs, episodic treatment of depression or ischaemic heart disease falls in the range I$100–1,000, and management of diabetes and its complications exceed I$1,000 (Bertram et al., Reference Bertram, Lauer, Stenberg, Ralaidovy and Edejer2021b). This study solely quantified health impacts produced by school-based SEL programs in relation to the prevention of depression, anxiety and self-harm among 12- to 17-year-old adolescents. It did not quantify other known impacts of school-based SEL programs, such as students’ attitudes to self, others and their school; school commitment; academic achievement; impacts on health risk behaviours (e.g., alcohol/substance use) and impacts on parents. Furthermore, the school-based SEL programs were modelled as stand-alone interventions; when in practice, there may be opportunities to integrate them within other existing school-based programs focused on students’ health, well-being and social skills (WHO and UNESCO, 2021a).
The results of this study add to the findings of previous economic evaluations of school-based SEL programs to improve adolescent mental health and well-being (Le et al., Reference Le, Esturas, Mihalopoulos, Chiotelis, Bucholc, Chatterton and Engel2021). Several model-based economic evaluations have found that universal/indicated school-based SEL programs are likely cost-effective in preventing depression and anxiety (Lee et al., Reference Lee, Barendregt, Stockings, Ferrari, Whiteford, Patton and Mihalopoulos2017, Reference Lee, Le, Lal, Engel and Mihalopoulos2021a, Reference Lee, Le, Lal, Engel and Mihalopoulos2021b; Mihalopoulos et al., Reference Mihalopoulos, Vos, Pirkis and Carter2012; Simon et al., Reference Simon, Dirksen and Bogels2013; Ssegonja et al., Reference Ssegonja, Sampaio, Alaie, Philipson, Hagberg, Murray, Sarkadi, Langenskiold, Jonsson and Feldman2020). Conversely, trial-based economic evaluations demonstrate mixed evidence of cost-effectiveness – with two studies finding no evidence of cost-effectiveness (Anderson et al., Reference Anderson, Ukoumunne, Sayal, Phillips, Taylor, Spears, Araya, Lewis, Millings, Montgomery and Stallard2014; Stallard et al., Reference Stallard, Phillips, Montgomery, Spears, Anderson, Taylor, Araya, Lewis, Ukoumunne, Millings, Georgiou, Cook and Sayal2013) and one finding that an indicated SEL program was good value for money (Lynch et al., Reference Lynch, Dickerson, Clarke, Beardslee, Weersing, Gladstone, Porta, Brent, Mark, DeBar, Hollon and Garber2019). Evidence on the cost-effectiveness of school-based SEL programs to prevent suicide outcomes was similarly mixed – with one model-based study observing that a universal SEL program was cost-saving under a societal perspective (but not a health sector perspective) (Kinchin et al., Reference Kinchin, Russell, Petrie, Mifsud, Manning and Doran2020) and another trial-based study finding no evidence of cost-effectiveness (Ahern et al., Reference Ahern, Burke, McElroy, Corcoran, McMahon, Keeley, Carli, Wasserman, Hoven, Sarchiapone, Apter, Balazs, Banzer, Bobes, Brunner, Cosman, Haring, Kaess, Kahn, Kereszteny, Postuvan, Saiz, Varnik and Wasserman2018). A recent return-on-investment analysis found that universal and indicated SEL programs can produce economic benefits that far exceed the costs of implementation – particularly when accounting for future improvements in employment and earnings potential that accrue to individuals experiencing improved mental health outcomes during adolescence (Stelmach et al., Reference Stelmach, Kocher, Kataria, Jackson-Morris, Saxena and Nugent2022).
Application and relevance of study findings
These findings assume new relevance when considering the inclusion of school-based SEL as an integral and key element of Helping Adolescents Thrive (HAT) – an evidence-based programmatic guidance package developed by WHO and UNICEF to enhance mental health promotion and protection and to reduce risk behaviours among adolescents. Early uptake of HAT at a country level has indicated strong interest in establishing or enhancing school-based mental health programs and has informed the development of the HAT Teacher’s Guide and related comic book to facilitate integration of SEL in the school curricula of young adolescents (UNICEF and WHO, 2021). Delivering SEL in schools should be considered a single element within a multipronged strategy for implementing school-based mental health promotive policies that are closely linked to other health services and referral mechanisms currently delivered in schools (NICE, 2022; WHO and UNESCO, 2021a, 2021b). Despite producing fewer population-level health benefits, the implementation of indicated SEL programs may be justified as a means of reducing population inequalities that affect high-risk populations who would benefit from a more tailored intervention approach.
The cost-effectiveness findings in this study are highly sensitive to fluctuations around the intervention effect sizes that were input into the model. It follows that any prospective rollout should proactively address implementation challenges that can reduce the fidelity and/or quality of SEL program delivery (Durlak, Reference Durlak2016; Kaspar and Massey, Reference Kaspar and Massey2023). For example, inadequate participant engagement and/or adherence can adversely impact on the real-world effectiveness of SEL programs. The WHO’s HAT Toolkit provides detailed operational guidance on how to implement SEL programs (WHO and UNICEF, 2021). Nine implementation factors have been identified to improve the likelihood that scaled up programs achieve their intended impacts. These include involving the adolescent target group and key stakeholders (e.g., caregivers and teachers) in the program development and implementation, ensuring the integration of SEL programs within the broader education curricula and adapting program materials to the local cultural context while ensuring intervention fidelity. Moreover, ongoing monitoring and evaluation is vital to bringing about effective program implementation.
While this study was initiated before the onset of the pandemic, its findings offer valuable information to national policymakers confronted with the deep and far-reaching mental health impacts of COVID-19 on young people, particularly the quantification of the expected level of prevented cases of depression, anxiety and suicide if school-based SEL programs are fully implemented. Additionally, the newly developed model can be, and already has been, applied at the country level to inform national mental health investment cases. In the Philippines, for example, an investment of 68 Philippine pesos (US$ 1.10) per capita in universal school-based SEL programs for 12- to 17-year-olds has the potential to avert over 450,000 cases of depression/anxiety and 377 suicides over a period of 10 years (WHO, 2021b).
Limitations
This study has several limitations. Data have been synthesized from various sources, with estimates of intervention effect size largely obtained from high-income country settings where more research and evaluation studies have been completed. Further research on the effectiveness of SEL programs in low- and middle-income countries is required, alongside consideration of cultural adaptations to improve program acceptance and uptake. This analysis has deliberately considered the combined effects of SEL interventions on depression/anxiety and suicide, even though many programs implemented in practice only consider impacts on one of these outcomes. Post hoc analysis of results indicates that over 90% of the estimated HLYG are attributable to the reduced incidence of depression/anxiety, so this might be considered a lower bound estimate of the potential health impact of these interventions. Use of the Cochrane conversion method to impute RR effect sizes from SMD effect sizes may limit the internal validity of study findings. Moreover, the assumption that reductions in suicide attempts lead to commensurate reductions in suicide deaths should be further explored, particularly in settings where prior suicide attempts are weaker predictors of completed suicides. Improving the accurate measurement of intervention effect sizes is vital, given the sensitivity of cost-effectiveness findings to this input parameter.
Conclusion
This study adds to current global evidence on SEL programs as a recommended strategy for child and adolescent mental health promotion and protection by quantifying their expected health impacts and costs when implemented at scale in different country income settings. It suggests that both universal and indicated SEL programs require a low level of investment (in the range of I$0.05 to I$0.20 per person) but that universal SEL programs produce significantly greater health benefits and therefore better value for money (e.g., less than I$1,000 per HLYG in LLMICs). Any prospective implementation of these programs in schools should take proactive steps to ensure the fidelity and quality of SEL program delivery and, in turn, the realization of the potential cost-effectiveness gains identified in this study.
Supplementary material
The supplementary material for this article can be found at https://doi.org/10.1017/S204579602300029X.
Availability of data and materials
In accordance with the WHO open access policy, data collected for this study are being made available to others on the Figshare repository through a CC BY 4.0 license at the date of publication, including country-level demographic and epidemiological data, other model parameters relating to intervention costs and effectiveness and the model structure itself. Application of the CC BY 4.0 license requires interested users of the data to attribute the original source.
Acknowledgements
We would like to thank the following members of the international expert panel who provided in-person feedback on this study at a meeting held at WHO headquarters in Geneva, Switzerland, on August 21, 2019: David Gunnell, David McDaid, Flemming Konradsen, Lai Fong Chan, Lakshmi Vijayakumar, Eva Kohlschmid, Gamini Manuweera, Lamia Bouzgarrou and Hesham Hamoda. We would also like to thank the following experts who provided feedback on this study through out-of-session email communications: Ella Arensman, Joran Lokkerbol, Pim Cuijpers and Tom Frieden. A special thanks goes to Melanie Bertram, who offered technical guidance on the costing analysis and model development, and Piumee Bandara, who reviewed and commented on the draft manuscript.
Financial support
This study was funded through pooled, unearmarked contributions by WHO Member States. The funders of the study had no role in study design, data collection, data analysis, interpretation of findings or manuscript preparation. The authors alone are responsible for the views expressed in this publication; they do not necessarily represent the decisions, policy or views of the World Health Organization and/or the institutions with which the authors are affiliated.
Competing interests
The authors declare no conflicts of interest.
Ethical standards
The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2013.