RESEARCH

 

Cost-effectiveness analysis of cataract surgery: a global and regional analysis

 

Chirurgie de la cataracte : analyse de coût-efficacité à l'échelle mondiale et régionale

 

Costoeficacia de la cirugía de la catarata: análisis mundial y regional

 

 

Rob BaltussenI, 1; Mariame SyllaII; Silvio P. MariottiIII

IiMTA (Institute for Medical Technology Assessment), Erasmus University Rotterdam, Netherlands; and WHO-CHOICE, Global Programme on Evidence for Health Policy, World Health Organization, 1211 Geneva 27, Switzerland
IIUNICEF, Ouagadougou, Burkina Faso
IIIPrevention of Blindness and Deafness, World Health Organization, Geneva, Switzerland

 

 


ABSTRACT

OBJECTIVE: To estimate the population health effects, costs and cost effectiveness of selected cataract surgery interventions in areas of the world with different epidemiological profiles.
METHODS: Effectiveness estimates are based on a review of the literature taking into account factors such as operative failure, complications and patient non-compliance. A population model was applied to follow the lifelong impact on individuals having cataract surgery. Costing estimates are based on primary data collected in 14 epidemiological subregions by regional costing teams and on a literature review. Costings were estimated for different geographical coverage levels using non-linear cost functions.
FINDINGS: Intra- and extra-capsular cataract surgeries are cost-effective ways to reduce the impact of cataract-blindness. Extra-capsular cataract surgery is more cost-effective than intra-capsular surgery in all regions considered. Providing extra-capsular cataract surgery to 95% of those who need it (95% coverage level) would avert over 3.5 million disability-adjusted life years (DALYs) per year globally. The cost-effectiveness ranges from 57 International dollars (I$) per DALY in the WHO South-East Asia Region where there is high overall child and adult mortality to I$ 2307 per DALY in the WHO Western Pacific Region where there is low overall child and adult mortality.
CONCLUSION: Extra-capsular surgery for cataracts at a high level of coverage is the most cost-effective way of restoring sight in all epidemiological subregions considered. Analysts from countries within a region are encouraged to further contextualize the results based on their own country's specific parameters.

Keywords: Cataract extraction/economics/complications; Lens implantation, Intraocular/complications; Eyeglasses/utilization; Treatment outcome; Patient compliance; Disability evaluation; Cost-benefit analysis; Cost of illness; Comparative study; Review literature; Metaanalysis (source: MeSH, NLM).


RÉSUMÉ

OBJECTIF: Estimer les effets sur la santé de la population, les coûts et le rapport coût-efficacité de diverses interventions de chirurgie de la cataracte dans des régions ayant des profils épidémiologiques différents.
MÉTHODES: Les estimations d'efficacité sont basées sur une revue de la littérature et tiennent compte de facteurs comme l'échec de l'intervention, les complications et la non-observance. Un modèle de population a été appliqué pour suivre l'impact sur toute la vie chez les sujets opérés de la cataracte. Les estimations de coût s'appuient sur les données primaires recueillies dans 14 sous-régions épidémiologiques par des équipes régionales ainsi que sur les données publiées. Les coûts ont été estimés au moyen de fonctions non linéaires pour différents taux de couverture géographique.
RÉSULTATS: Les opérations intra- et extracapsulaires de la cataracte constituent un moyen d'un bon rapport coût-efficacité pour réduire l'impact de la cécité due à la cataracte. Dans toutes les régions considérées, le rapport coût-efficacité est meilleur pour la chirurgie extracapsulaire que pour la chirurgie intracapsulaire. En pratiquant une opération extracapsulaire sur 95 % des personnes qui en ont besoin (taux de couverture de 95 %), on éviterait chaque année, à l'échelle mondiale, plus de 3,5 millions d'années de vie ajustées sur l'incapacité (DALY). Le rapport coût-efficacité va de 57 dollars internationaux par DALY dans la Région OMS de l'Asie du Sud-Est, où la mortalité globale chez l'enfant comme chez l'adulte est élevée, à 2307 dollars internationaux par DALY dans la Région OMS du Pacifique occidental où la mortalité globale est faible.
CONCLUSION: Dans toutes les sous-régions épidémiologiques considérées, l'opération extracapsulaire de la cataracte avec un taux de couverture élevé est à coût égal le moyen le plus efficace pour restaurer la vue. A l'intérieur de chaque région, les analystes des divers pays sont encouragés à replacer ces résultats dans leur contexte compte tenu des particularités locales.

Mots clés: Extraction cataracte/économie/complication; Implantation intraoculaire lentille/complication; Verres correcteurs/utilisation; Evaluation résultats traitement; Observance prescription; Evaluation incapacité; Analyse coût-bénéfice; Coût maladie; Etude comparative; Revue de la littérature; Méta-analyse (source: MeSH, INSERM).


RESUMEN

OBJETIVO: Estimar los efectos en la salud de la población, los costos y la costoeficacia de determinadas intervenciones de cirugía de la catarata en zonas del mundo que presentan distintos perfiles epidemiológicos.
MÉTODOS: Las estimaciones de la eficacia se basan en una revisión de la literatura que tiene en cuenta factores como el fracaso operatorio, las complicaciones y el incumplimiento por parte de los pacientes. Se aplicó un modelo de población para seguir el impacto de la operacion de catarata a todo lo largo de la vida en los individuos que se habían sometido a tal intervención. Las estimaciones de costos están basadas en datos primarios reunidos en 14 subregiones epidemiológicas por los equipos regionales de cálculo de costos y en una revisión de la literatura. Se usaron funciones de costos no lineales para estimar los costos asociados a distintos niveles de cobertura geográfica.
RESULTADOS: Las operaciones de cirugía intracapsular y extracapsular de la catarata son un instrumento costoeficaz para reducir el impacto de la ceguera por catarata. La cirugía extracapsular es más costoeficaz que la intracapsular en todas las regiones consideradas. Proporcionando cirugía extracapsular a un 95% de quienes la necesitan (cobertura del 95%) se evitarían más de 3,5 millones de años de vida ajustados en función de la discapacidad (AVAD) cada año a nivel mundial. La costoeficacia varía entre 57 dólares internacionales (I$) por AVAD en la Región de Asia Sudoriental de la OMS, donde hay una alta mortalidad general de niños y adultos, y I$ 2307 por AVAD en la Región del Pacífico Occidental de la OMS, donde hay una baja mortalidad general de niños y adultos.
CONCLUSIÓN: La cirugía extracapsular de la catarata, asegurando un alto nivel de cobertura, es la alternativa más costoeficaz para restablecer la vista en todas las subregiones epidemiológicas consideradas. Se alienta a los analistas de los países de cada región a que sigan contextualizando los resultados incorporando los parámetros específicos de su país.

Palabras clave: Extracción de catarata/economía/complicaciones; Implantación de lentes intraoculares/complicaciones; Anteojos/utilización; Resultado del tratamiento; Cooperación del paciente; Evaluación de la incapacidad; Análisis de costo-beneficio; Costo de la enfermedad; Estudio comparativo; Literatura de revisión; Meta-análisis (fuente: DeCS, BIREME).



 

 

Introduction

Cataracts are a major cause of blindness and of severe visual impairment leading to bilateral blindness in an estimated 20 million people worldwide. In developing countries 50–90% of all blindness is caused by cataracts (1).

A cataract is a clouding of the lens of the eye that causes loss of vision. Although cataracts result from many conditions, the most frequent cause is the natural ageing process. Other causes include injury, chronic eye disease and other systemic diseases, such as diabetes (2). Cataracts can take from a few months to several years to develop and can affect both eyes at the same time, but they often develop at different rates. Sometimes the cataract stops developing in its early stages and vision is only slightly impaired. But if it continues to develop, vision is impaired, and treatment is necessary. Surgery to remove the opacified lens is the only effective treatment for cataracts. Neither diet nor medications have been shown to stop cataract formation. There are several possible approaches for the surgical extraction of cataracts. In this paper we evaluate the cost effectiveness of two different surgical procedures delivered to 50%, 80% or 95% of those who need surgery.

Cost-effectiveness analysis can be undertaken in many ways, and there have been several attempts to develop methodological guidelines to make results more comparable. WHO has developed a standardized set of methods and tools that can be used to analyse the societal costs and impact on the health of the population of current and new interventions at the same time (3, 4). The WHO-CHOICE (CHOosing Interventions that are Cost-Effective) project is intended to provide regularly updated databases on the costs and effects of a full range of interventions to promote health and prevent disease, and to cure and rehabilitate. Additional information on the project is shown in Box 1 (web version only, available at: http://www.who.int/bulletin). Adopting this standardized approach to generalized cost-effectiveness analysis allows comparisons to be made among a range of interventions relating to cataracts as well as with interventions for other major health problems.

 

Methods

Regions

It would be desirable to evaluate all possible combinations of interventions for every country in the world. In the case of some of the larger countries, it would be desirable to evaluate these combinations at a subnational level. No country has yet been able to do this, and many countries do not have the technical capacity to evaluate even a few interventions. At the other extreme, global estimates of an intervention's cost effectiveness are of little use to any specific country.

This study provides information on the costs and health effects of cataract surgery at the subregional level in different parts of the world. Regions are grouped by geographical proximity and epidemiological similarity (Box 2). These can then be further contextualized to the country level.

Interventions

The aim of cataract surgery is to rehabilitate blind or visually impaired people by restoring their sight to normal or as near to normal as possible. This analysis distinguishes between two types of surgical intervention. Intra-capsular cataract extraction, using aphakic glasses (ICCE-AG), is a technique where the whole lens is removed from the eye. After surgery special eyeglasses are provided to patients to restore sight. In extra-capsular cataract extraction with implantation of a posterior chamber intraocular lens (ECCE-PC-IOL), the lens and the front portion of the capsule are removed and then replaced with an artificial lens.

We evaluated both procedures for 14 epidemiological subregions, except for the four areas where ICCE-AG is not used (Box 2).

Modelling health effects on the population

To assess the impact of cataracts on population health, a population model was developed to simulate the life span of individuals in a population. Population health is expressed as the number of healthy years lived (HYL) and the difference in HYL as disability-adjusted life years (DALYs) that are averted as a result of the intervention. The model allows individuals to be categorized into one of three mutually exclusive health states: healthy, cataract-blind and dead.

Population health depends not only on the proportion of individuals who are blind but also on the disability weight that is associated with blindness. The flow of individuals from one state to another is similarly modelled for both the null scenario and the situation in which interventions are applied. Population models of the prevalence of cataracts were based on the regional global burden of disease data which include consistent prevalence and incidence data for 14 epidemiological subregions (1). The null scenario was derived from each model by setting the cataract remission rate in the model to 0 starting in the year 2000 to reflect the absence of cataract surgery. Analyses attach a disability weight of 0.6 to people who are blind (1).

Intervention effectiveness was modelled using the remission rate — that is, the number of people who are blind bilaterally because of cataracts and whose sight is restored in one eye (Table 1). WHO's definition of blindness was used.

Clinical studies report small variations in the effectiveness of ICCE-AG and ECCE-PC-IOL (5, 6). WHO internal expert advisers assessed the real world effectiveness of these results, taking into account the occurrence of complications and non-compliance by patients. All estimates are explicitly presented as distributions around best estimates to reflect uncertainty, since most clinical studies typically involve only a limited follow-up period and do not capture these factors (Table 2).

After discussion with WHO's internal panel, the effectiveness of ICCE-AG and ECCE-PC-IOL were both estimated at 95%. Complications for both interventions were estimated to reduce effectiveness by 5%. Furthermore, non-compliance in terms of not wearing glasses (for whatever reason) may further reduce the effectiveness of ICCE-AG. In a survey in Nepal, it was found that for all bilaterally blind patients undergoing cataract surgery in a single eye, 27% were not wearing glasses at all after surgery because they did not own any, and at the time of the survey 82% were not wearing glasses, had broken glasses, or had dirty or scratched glasses (7). These data are confirmed by various WHO country reports showing that at 1–10 years after surgery, 18–69% of patients who have had surgery for cataracts do not wear glasses. For example, in Turkmenistan 35% of patients did not wear their glasses. The comparable percentages for other regions are: North Viet Nam, 69%; Punjab, 20%; Myanmar, 20–42%; and India, 18%. On the basis of this evidence, we assumed a reduction in effectiveness of 27–82% that was uniformly distributed.

The remission rate of cataracts is then estimated as: the natural log of (1 – [population effectiveness x the coverage of the intervention]) (see Table 1). Coverage rates for the interventions refer to the percentage of the cataract-blind population in each country that has the surgery over 10 years. These rates are arbitrarily defined at 50%, 80% and 95%.

Interventions were overlaid on the null scenario for the years 2000–10. The HYLs gained in each surgery scenario were then compared to the null scenario to estimate the DALYs averted.

Estimating costs

Costs covered in this analysis include programme-level costs associated with the intervention, such as administration and training, and patient-level costs, such as primary care visits. These costs were based on a standard ingredients approach developed by WHO-CHOICE to aid in costing interventions. The following components were included:

• Programme-level resource inputs used to produce an intervention at a level above that of the patient or facility providing the service, such as central planning, policy, training and administration functions. Estimated quantities of resources required to start and then maintain each intervention for 10 years at national, provincial and district levels were based on a series of evaluations made by experts in the different subregions. These were validated against the literature (categories of resource input included personnel, training, materials and supplies, media, transport, maintenance, utilities and capital);

• Patient-level resource inputs used to provide a given health care intervention (for example, hospital inpatient days, outpatient visits, medications, laboratory tests, etc.). Patient costs for cataracts include the costs of supplies and equipment related to the surgical procedures. Countries were clustered in three broad categories representing their utilization pattern for outpatient and inpatient visits, tests and compliance (Table 2). The number of outpatient and inpatient visits are based on a literature review. Resources used for ECCE-PC-IOL include an operation equipment kit, intraocular lenses and microscope. Resources used for ICCE-AG include a cataract equipment kit, a loupe and eyeglasses. Cataract surgery is assumed to be performed by a surgeon assisted by a nurse; and

• Unit costs of programme-level and patient-level resource inputs, such as the salaries of central administrators, the capital costs of offices and furniture, or the cost per inpatient and outpatient visit. Data were obtained from a review of the literature and supplemented by primary data from several countries or they were based on international catalogue prices for operation supplies and equipment. (For a full overview of all unit costs, see http://www.who.int/evidence/cea.).

Costs are reported in International dollars ($I) to facilitate more meaningful comparisons across regions. (For additional information about International dollars, see Box 3 web version only, available at: http://www.who.int/bulletin.) The base year is 2000. More details on health facility unit cost estimates are reported in Adam et al (9). A description of the estimates of the programmes' costs, including costing of various coverage levels as well as the scaling-up of costs to the level of WHO subregions, can be found in Johns et al (10).

This analysis reports the cost-effectiveness estimates of interventions that are done technically efficiently, using 80% capacity utilization as the norm. This ensures that the observed differences are due to the intrinsic characteristics of the intervention rather than the extent to which capital and labour have been utilized in the environment in which the interventions were evaluated. In comparison to studies describing the costs of interventions on the basis of the actual capacity utilization, this approach often results in much lower estimates of cost.

Full details of the methods used to generate these cost estimates, including the costing of various coverage levels as well as the scaling-up of costs to the level of the epidemiological subregions, are given in the WHO-CHOICE guidelines (11).

Cost-effectiveness ratios

The average cost-effectiveness ratios are calculated for each intervention by combining information on total costs with information on total health effects in terms of DALYs averted. All costs and effects are discounted at 3%.

Using a standardized approach, we have identified the set of interventions a region should purchase to maximize its health gain for different budgets. The order in which interventions would be purchased is called an expansion path and is based on the incremental costs and benefits of each intervention compared with the last intervention purchased.

The WHO Commission on Macroeconomics and Health defined interventions that have a cost-effectiveness ratio of less than three times the gross domestic product (GDP) per capita as cost effective (12). Based on this, three broad categories are defined here. Interventions that gain each year of healthy life (that is, a DALY averted) at a cost that is less than GDP per capita are defined as very cost effective. Those averting each DALY at a cost of between one and three times GDP per capita are cost effective. The remainder are not cost effective.

Uncertainty analysis

Probabilistic uncertainty analyses have been undertaken to consider how uncertainty about epidemiological, effectiveness and cost parameters translates into uncertainty about the cost-effectiveness ratio. The application of probabilistic uncertainty analysis with Monte Carlo simulations is described in full detail elsewhere (13). It requires that analysts assume some distributional form for costs and effects from which repeated samples are drawn to determine a distribution for the cost-effectiveness ratio.

Distributional forms for the parameters used in this analysis are defined in Table 1 and Table 2. The simple percentile method was used to estimate uncertainty intervals for cost-effectiveness ratios. In this approach, the 5th percentile and 95th percentile results were taken from Monte Carlo simulations in which all random variables were chosen simultaneously.

 

Results

Table 3 provides the total annualized costs, total annual health effects in terms of DALYs averted, and the average cost-effectiveness ratios for each intervention. ECCE-PC-IOL is more cost effective than ICCE-AG in all regions considered. This is also illustrated in the expansion path for the region of Africa at mortality stratum D (Africa-D) (Fig. 1): ECCE-PC-IOL is both more effective and more cost effective than ICCE-AG and therefore dominates ICCE-AG.

 

 

Moreover, the results also show that interventions that reach more people are always more cost effective than those that reach fewer people. This shows that economies of scale play a part in cost effectiveness (since the costs of administration and planning are relatively independent of the number of surgeries performed). ECCE-PC-IOL used with 95% coverage of the population would avert more than 3.5 million DALYs per year globally, with cost effectiveness ranging from I$ 57 per DALY in the South-East Asia Region at mortality stratum B to I$ 2307 per DALY in the Western Pacific Region at mortality stratum A.

The probabilistic uncertainty analysis included 5 000 random draws from predefined distributions, and it showed that the results were robust even when variations were introduced to the model's parameters. For example, ECCE-PC-IOL at 95% coverage in Africa-D has a mean cost-effectiveness ratio of I$ 89 per DALY, with the 5% to 95% percentile interval ranging from I$ 39 per DALY to I$ 148 per DALY (Table 4, web version only, available at: http://www.who.int/bulletin). Although the average cost-effectiveness ratios for different strategies could, in some cases, vary by a factor of 2 between the high estimates and the low estimates, the overall conclusion is that the range of interventions examined here would have attractive cost-effectiveness ratios. Also the findings regarding the relative cost effectiveness of different strategies remains largely unchanged.

 

 

Discussion

A number of studies have estimated the cost effectiveness of interventions in cataract control. This study is unique in that it evaluates the cost effectiveness of intra-capsular and extra-capsular cataract surgery in a framework of a single generalized cost-effectiveness analysis, and it does so for several regions. Extra-capsular surgery dominates intra–capsular surgery, and it can therefore be considered the best choice for cataract control. In all regions, extracapsular surgery is very cost effective according to the criterion of the Commission on Macroeconomics and Health (12).

This analysis provides only broad indications of the cost effectiveness of cataract surgery. The results are presented for the regional level, using regional patterns of resource utilization and epidemiology. Although epidemiological patterns can be assumed to be relatively homogeneous between countries in a certain region, resource utilization patterns can be expected to vary. Decision-makers who wish to extrapolate the results to their own context should assess whether the quantities and costs of the various inputs are applicable to their setting. If so, they can estimate the cost effectiveness for their context. The models used to calculate costs and effects, including the raw input data, are available on the Internet at http://www.who.int/evidence/cea. This will allow the study's findings to be used to make decisions about resource allocation in a range of countries. Moreover, the assumption of technical efficiency (which is necessary to allow a fair comparison of the cost effectiveness of interventions across disease areas) may not be relevant to a specific decision-making context. To increase this study's relevance for policy-making, analysts are encouraged to put the results of this study into a context that represents the situation of their country.

The availability of surgeons to perform cataract surgery is another issue that must be addressed when interpreting results at the country level. The number of cataract surgeons is insufficient in many countries, especially if policy-makers wish to aim for a population coverage level of 95%. Cataract surgery rates fall short of this figure. For example, Lewallen & Courtright reported that coverage rates for cataract surgery in nine studies varied from 17% to 69% (14). We have shown that high coverage rates make cataract surgery more economically attractive. We believe more cataract surgeons should be trained.

The cost per surgery performed varies considerably by region. This may be caused by relative differences in resource utilization and price. Another reason is that programme-level resource inputs, such as costs of administration and planning beyond the patient-level, were assumed to be relatively independent of the number of cataract surgeries performed: regions with a relatively low number of cataract surgeries will thus have relatively high programme costs per surgery. (This is also the main reason why costs per surgery in the Western Pacific Region at mortality stratum A are higher than in the Region of the Americas at mortality stratum A.)

In general, the cost estimates in our study compare reasonably well with those reported in other studies (15–23) considering the large variations in methodologies used. For example, studies in India, Nepal and Mali show a range of costs from US$ 20–53 per cataract surgery (costs converted to US$ for the base year 2000), whereas we estimate costs in those regions to be in the range of US$ 24–68 (converted from International dollars using purchasing power parities). Our estimates tend to be relatively high because other studies typically have not included programme costs. As in the other studies, our cost estimates were restricted to health care costs because of the methodological problems involved in measuring the societal costs of a patient's time spent seeking care and undergoing care or societal gains in productivity (11).

At the individual level, ECCE-PC-IOL surgery decreases the disability weighting (for example, for a male aged 50 years old in Africa-D from 0.7 to 0.24). When the number of life-years that patients benefit from surgery is taken into account the effectiveness of surgery varies from 1 DALY to 3 DALYs per surgery. Our reported gains are in the same range as the 2 DALYs to 4 DALYs estimated by Javitt (20) and Marseille et al. (24), respectively. However, ours are on the conservative side. There are two main reasons for this difference. Firstly, we did not assume any case fatality associated with being blinded by cataract. Several studies carried out in Africa suggested mortality of 1.5–3.0, which is higher for people who are visually impaired or blind (25, 26). But strong evidence for this rate is lacking. Secondly, our study applied a population model which allowed for the precise calculation of DALYs averted whereas Javitt et al. (20) used a simpler approach. However, the effectiveness of the intervention was estimated on the basis of the number of cataract-blind people who are cured by surgery. This may overestimate the real health gains because it assumes full recovery of eyesight for all individuals who have a remission from being blind bilaterally, even though not all people may be blind bilaterally and some may benefit only slightly from cataract surgery.

Cost effectiveness is only one of the key inputs that affect the final decision about how to allocate scarce resources. Policy-makers have other concerns as well, such as reducing poverty and other inequalities. Another key concern for policy-makers is how different interventions can be incorporated into the health infrastructure of the country or how the infrastructure could be adapted to accommodate the desired strategies. The information presented here is only one of the critical inputs required to inform decision-making about efficient ways to reduce blindness caused by cataracts.

 

Acknowledgements

The authors thank the members of the WHO-CHOICE team and the WHO-PBD team for their contributions to the development of the methodological framework for the analysis and their comments on, and review of, this paper.

The views expressed are those of the authors and not necessarily those of the organizations they represent.

Conflicts of interest: none declared.

 

References

1. Murray CJL, Lopez AD. A comprehensive assessment of mortality and disability from diseases, injuries, and risk factors in 1990 and projected to 2020. In: Murray CJL, Lopez AD, editors. The global burden of disease. Cambridge (MA): Harvard School of Public Health; 1996.        

2. West SK, Valmadrid CT. Epidemiology of risk factors for age-related cataract. Survey of Ophthalmology 1995;39:323-34.        

3. Hutubessy RCW, Baltussen RMPM, Tan Torres–Edejer T, Evans DB. Generalised cost–effectiveness analysis: an aid to decision making in health. Applied Health Economics and Health Policy 2002;1:89-95.        

4. Murray CJ, Evans DB, Acharya A, Baltussen RM. Development of WHO guidelines on generalized cost-effectiveness analysis. Health Economics 2000;9:235-51.        

5. Singh AJ, Garner P, Floyd K. Cost–effectiveness of public-funded options for cataract surgery in Mysore, India. Lancet 2000;355:180-4.        

6. Snellingen T, Evans JR, Ravilla T, Foster A. Surgical interventions for age-related cataract. Cochrane Database of Systematic Reviews 2002;(2):CD001323        

7. Hogeweg M, Sapkota YD, Foster A. Acceptability of aphakic correction. Results from Karnali eye camps in Nepal. Acta Ophthalmologica 1992;70:407-12.        

8. World Bank Development Data Group. World Development Indicators 2002. Washington (DC): World Bank; 2002.        

9. Adam T, Evans DB, Murray CJL. Econometric estimation of country–specific hospital costs. Cost-effectiveness and resource allocation [electronic resource] 2003;1:3.        

10. Johns B, Baltussen R, Hutubessy RCW. Programme costs in the economic evaluation of health interventions. Cost-effectiveness and Resource Allocation [electronic resource] 2003;1:1.        

11. Tan Torres–Edejer T, Baltussen R, Adam T, Hutubessy R, Acharya A, Evans D, et al. WHO guide to cost-effectiveness analysis. Geneva: World Health Organization; 2003.        

12. WHO Commission on Macroeconomics and Health. Macroeconomics and health: investing in health for economic development. Report of the Commission on Macroeconomics and Health. Geneva: World Health Organization; 2001.        

13. Baltussen RM, Hutubessy RC, Evans DB, Murray CJ. Uncertainty in cost–effectiveness analysis: probabilistic uncertainty analysis and stochastic league tables. International Journal of Technology Assessment in Health Care 2002;18:112-9.        

14. Lewallen S, Courtright P. Gender and use of cataract surgical services in developing countries. Bulletin of the World Health Organization 2002;80:300-3.        

15. Marseille E, Gilbert S. The cost of cataract surgery in a public health eye care program in Nepal. Health Policy 1996;35:145-54.        

16. Murthy GV, Sharma P. Cost analysis of eye camps and camp–based cataract surgery. National Medical Journal of India 1994;7:111-4.        

17. Ruit S, Tabin GC, Nissman SA, Paudyal G. Low-cost high-volume extracapsular cataract extraction with posterior chamber intraocular lens implantation in Nepal. Ophthalmology 1999;106:1887-92.        

18. Schemann JF, Bakayoko S, Coulibaly S. Traditional couching is not an effective alternative procedure for cataract surgery in Mali. Ophthalmic Epidemiology 2000;7:271-83.        

19. Drummond MF. Economic aspects of cataract. Ophthalmology 1988;95:1147-53.        

20. Javitt JC. Cataract. In: Jamison DT, Mosley WH, Measham AR, Bobadilla LJ, editors. Disease control priorities in developing countries. New York: Oxford University Press; 1993. p. 635-45.        

21. Lundstrom M, Brege KG, Floren I, Roos P, Stenevi U, Thorburn W. Cataract surgery and effectiveness. 1. Variation in costs between different providers of cataract surgery. Acta Ophthalmologica Scandinavica 2000;78:335-9.        

22. Minassian DC, Rosen P, Dart JK, Reidy A, Desai P, Sidhu M, et al. Extracapsular cataract extraction compared with small incision surgery by phacoemulsification: a randomised trial. British Journal of Ophthalmology 2001;85:822-9.        

23. Cresswell PA, Allen ED, Tomkinson J, Chapman FM, Pickering S, Donaldson LJ. Cost effectiveness of a single-function treatment center for cataract surgery. Journal of Cataract and Refractive Surgery 1996;22:940-6.        

24. Marseille E. Cost effectiveness of cataract surgery in a public health eye care programme in Nepal. Bulletin of the World Health Organization 1996;74:319-24.        

25. Kirkwood B, Smith P, Marshall T, Prost A. Relationships between mortality, visual acuity and microfilarial load in the area of the Onchocerciasis Control Programme. Transactions of the Royal Society of Tropical Medicine and Hygiene 1983;77:862-8.        

26. Prost A, Vaugelade J. Excess mortality among blind persons in the West African savannah zone. Bulletin of the World Health Organization 1981;59:773-6.        

 

 

(Submitted: 28 February 03 – Final revised version received: 18 September 03 – Accepted: 3 October 03)

 

 

1 Correspondence should be sent to this author (email: baltussen@bmg.eur.nl).

World Health Organization Genebra - Genebra - Switzerland
E-mail: bulletin@who.int