Optima TB: A Tool to Help Optimally Allocate Tuberculosis Spending

Overview

Journal PLoS Comput Biol

Specialty Biology

Date 2021 Sep 27

PMID 34570767

Citations 6

Authors

Lara Gosce

Gerard J Abou Jaoude

David J Kedziora

Clemens Benedikt

Azfar Hussain

Sarah Jarvis

Alena Skrahina

Dzmitry Klimuk

Henadz Hurevich

Feng Zhao

Nicole Fraser-Hurt

Nejma Cheikh

Marelize Gorgens

David J Wilson

Romesh Abeysuriya

Rowan Martin-Hughes

Sherrie L Kelly

Anna Roberts

Robyn M Stuart

Tom Palmer

Jasmina Panovska-Griffiths

Cliff C Kerr

David P Wilson

Hassan Haghparast-Bidgoli

Jolene Skordis

Ibrahim Abubakar

Affiliations

Soon will be listed here.

Abstract

Approximately 85% of tuberculosis (TB) related deaths occur in low- and middle-income countries where health resources are scarce. Effective priority setting is required to maximise the impact of limited budgets. The Optima TB tool has been developed to support analytical capacity and inform evidence-based priority setting processes for TB health benefits package design. This paper outlines the Optima TB framework and how it was applied in Belarus, an upper-middle income country in Eastern Europe with a relatively high burden of TB. Optima TB is a population-based disease transmission model, with programmatic cost functions and an optimisation algorithm. Modelled populations include age-differentiated general populations and higher-risk populations such as people living with HIV. Populations and prospective interventions are defined in consultation with local stakeholders. In partnership with the latter, demographic, epidemiological, programmatic, as well as cost and spending data for these populations and interventions are then collated. An optimisation analysis of TB spending was conducted in Belarus, using program objectives and constraints defined in collaboration with local stakeholders, which included experts, decision makers, funders and organisations involved in service delivery, support and technical assistance. These analyses show that it is possible to improve health impact by redistributing current TB spending in Belarus. Specifically, shifting funding from inpatient- to outpatient-focused care models, and from mass screening to active case finding strategies, could reduce TB prevalence and mortality by up to 45% and 50%, respectively, by 2035. In addition, an optimised allocation of TB spending could lead to a reduction in drug-resistant TB infections by 40% over this period. This would support progress towards national TB targets without additional financial resources. The case study in Belarus demonstrates how reallocations of spending across existing and new interventions could have a substantial impact on TB outcomes. This highlights the potential for Optima TB and similar modelling tools to support evidence-based priority setting.

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