Abstract
BackgroundDue to spatial heterogeneity in onchocerciasis transmission, the duration of ivermectin mass drug administration (MDA) required for eliminating onchocerciasis will vary within endemic areas and the occurrence of transmission “hotspots” is inevitable. The geographical scale at which stop-MDA decisions are made will be a key driver in how rapidly national programs can scale down active intervention upon achieving the epidemiological targets for elimination.MethodsWe used 2 onchocerciasis models (EPIONCHO-IBM and ONCHOSIM) to predict the likelihood of achieving elimination by 2030 in Africa, accounting for variation in preintervention endemicity levels and histories of ivermectin treatment. We explore how decision making at contrasting geographical scales (community vs larger scale “project”) changes projections on populations still requiring MDA or transitioning to post-treatment surveillance.ResultsThe total population considered grows from 118 million people in 2020 to 136 million in 2030. If stop-MDA decisions are made at project level, the number of people requiring treatment declines from 69–118 million in 2020 to 59–118 million in 2030. If stop-MDA decisions are made at community level, the numbers decline from 23–81 million in 2020 to 15–63 million in 2030. The lower estimates in these prediction intervals are based on ONCHOSIM, the upper limits on EPIONCHO-IBM.ConclusionsThe geographical scale at which stop-MDA decisions are made strongly determines how rapidly national onchocerciasis programs can scale down MDA programs. Stopping in portions of project areas or transmission zones would free up human and economic resources.
Highlights
Due to spatial heterogeneity in onchocerciasis transmission, the duration of ivermectin mass drug administration (MDA) required for eliminating onchocerciasis will vary within endemic areas and the occurrence of transmission “hotspots” is inevitable
Adult O. volvulus worms live in subcutaneous nodules [1], with an average life expectancy of 10 years [2]
We use 2 stochastic individual-based simulation models, EPIONCHO-IBM and ONCHOSIM, to predict how onchocerciasis microfilarial prevalence levels decline during MDA and when MDA can be stopped with minimal risk of resurgence
Summary
We used 2 onchocerciasis models (EPIONCHO-IBM and ONCHOSIM) to predict the likelihood of achieving elimination by 2030 in Africa, accounting for variation in preintervention endemicity levels and histories of ivermectin treatment. We use 2 stochastic individual-based simulation models, EPIONCHO-IBM and ONCHOSIM, to predict how onchocerciasis microfilarial prevalence levels decline during MDA and when MDA can be stopped with minimal risk of resurgence. Detailed descriptions of both models are provided elsewhere [8, 18, 21]. The 2 models are used side-by-side to capture uncertainties in the underlying transmission processes that influence the predictions [22]. Both EPIONCHO-IBM and ONCHOSIM simulate onchocerciasis transmission in a closed, dynamic population, typically representing a village. The dynamics of infection (from ingested mf to infective L3 larvae) in the vector population are modeled deterministically, with both models assuming density-dependent larval establishment within the (savannah) Simulium damnosum vectors
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