Core discrete event simulation model for the evaluation of health care technologies in major depressive disorder

Anne-Lise Vataire; Samuel Aballéa; Fernando Antonanzas; Leona Hakkaart-van Roijen; Raymond W Lam; Paul McCrone; Ulf Persson; Mondher Toumi

doi:10.1016/j.jval.2013.11.012

Core discrete event simulation model for the evaluation of health care technologies in major depressive disorder

Value Health. 2014 Mar;17(2):183-95. doi: 10.1016/j.jval.2013.11.012.

Authors

Anne-Lise Vataire¹, Samuel Aballéa², Fernando Antonanzas³, Leona Hakkaart-van Roijen⁴, Raymond W Lam⁵, Paul McCrone⁶, Ulf Persson⁷, Mondher Toumi⁸

Affiliations

¹ Creativ-Ceutical, Paris, France. Electronic address: ava@creativ-ceutical.com.
² Creativ-Ceutical, Paris, France.
³ University of La Rioja, Logrono, Spain.
⁴ Erasmus University Rotterdam, Rotterdam, The Netherlands.
⁵ University of British Columbia, Vancouver, Canada.
⁶ King's College, London, UK.
⁷ The Swedish Institute for Health Economics, Lund, Sweden.
⁸ University of Lyon, Lyon, France.

PMID: 24636376
DOI: 10.1016/j.jval.2013.11.012

Abstract

Objective: A review of existing economic models in major depressive disorder (MDD) highlighted the need for models with longer time horizons that also account for heterogeneity in treatment pathways between patients. A core discrete event simulation model was developed to estimate health and cost outcomes associated with alternative treatment strategies.

Methods: This model simulated short- and long-term clinical events (partial response, remission, relapse, recovery, and recurrence), adverse events, and treatment changes (titration, switch, addition, and discontinuation) over up to 5 years. Several treatment pathways were defined on the basis of fictitious antidepressants with three levels of efficacy, tolerability, and price (low, medium, and high) from first line to third line. The model was populated with input data from the literature for the UK setting. Model outputs include time in different health states, quality-adjusted life-years (QALYs), and costs from National Health Service and societal perspectives. The codes are open source.

Results: Predicted costs and QALYs from this model are within the range of results from previous economic evaluations. The largest cost components from the payer perspective were physician visits and hospitalizations. Key parameters driving the predicted costs and QALYs were utility values, effectiveness, and frequency of physician visits. Differences in QALYs and costs between two strategies with different effectiveness increased approximately twofold when the time horizon increased from 1 to 5 years.

Conclusion: The discrete event simulation model can provide a more comprehensive evaluation of different therapeutic options in MDD, compared with existing Markov models, and can be used to compare a wide range of health care technologies in various groups of patients with MDD.

Keywords: antidepressants; cost-effectiveness; depression; discrete event simulation.

MeSH terms

Antidepressive Agents / adverse effects
Antidepressive Agents / economics
Antidepressive Agents / therapeutic use*
Biomedical Technology / economics*
Computer Simulation
Depressive Disorder, Major / drug therapy*
Depressive Disorder, Major / economics
Hospitalization / economics
Humans
Markov Chains
Models, Economic*
Physicians / economics
Quality-Adjusted Life Years
Technology Assessment, Biomedical / methods
Time Factors
United Kingdom

Substances

Antidepressive Agents