Efficacy of<i>Wolbachia</i>-mediated sterility for control of dengue: emulation of a cluster randomized target trial

Lim, Jue Tao; Mailepessov, Diyar; Chong, Chee Seng; Dickens, Borame; Lai, Yee Ling; Ng, Youming; Deng, Lu; Lee, Caleb; Tan, Li Yun; Chain, Grace; Ho, Soon Hoe; Chang, Chia-Chen; Ma, Pei; Bansal, Somya; Lee, Vernon; Sim, Shuzhen; Tan, Cheong Huat; Ng, Lee Ching

doi:10.1101/2023.11.29.23299172

Cited by 2 publications

(1 citation statement)

References 22 publications

(44 reference statements)

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“…When male insects infected with Wolbachia mate with females that either lack Wolbachia or have different Wolbachia strains, cytoplasmic incompatibility can cause the offspring to die during the early stages of embryonic development (Engelstädter & Telschow, 2009). Wolbachia- mediated cytoplasmic incompatibility has been tested in field trials in China, the USA, and Singapore through the incompatible insect technique (IIT), where only male mosquitoes with the Wolbachia infection are released, and has been found to effectively suppress the mosquito population (Zeng et al, 2022; Crawford et al, 2020; The Project Wolbachia - Singapore Consortium & Ng, 2021; Bansal et al, 2023) and consequently reduce dengue incidence (Lim et al, 2023; Lim et al, 2024). A cluster-randomized controlled trial is also underway in Singapore to provide gold-standard evidence of the technology’s epidemiological efficacy (Ong et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Wolbachiaincompatible insect technique program optimization over large spatial scales using a process-based model of mosquito metapopulation dynamics

Lim,

Cook,

Bansal

et al. 2024

Preprint

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BackgroundWolbachiaincompatible insect technique (IIT) programs have been shown in field trials to be highly effective in suppressing populations of mosquitoes that carry diseases such as dengue, chikungunya and Zika. However, the frequent and repeated release ofWolbachia-infected male mosquitoes makes such programs resource-intensive. While the need for optimization is recognized, potential strategies to optimize releases and reduce resource utilization have not been fully explored.MethodsWe developed a process-based model to study the spatial-temporal metapopulation dynamics of mosquitoes in aWolbachiaIIT program, which explicitly incorporates climatic influence in mosquito life-history traits. We then used the model to simulate various scale-down and redistribution strategies to optimize the existing program in Singapore. Specifically, the model was used to study the trade-offs between the intervention efficacy outcomes and resource requirements of various release program strategies, such as the total number of release events and the number of mosquitoes released.ResultsWe found that scaling down releases in existing sites from twice a week to only once a week yielded minimal changes in suppression efficacy (from 91% to 85%), while requiring 45% fewer mosquitoes and release events. Additionally, redistributing mosquitoes from already suppressed areas and releasing them in new areas once a week led to a greater total suppressive efficacy (88% compared to 65%) while also yielding a 16% and 14% reduction in the number of mosquitoes and release events required respectively.ConclusionsBoth scale-down and redistribution strategies can be implemented to significantly reduce program resource requirements without compromising the suppressive efficacy of IIT. These findings will inform planners on ways to optimize existing and future IIT programs, potentially allowing for the wider adoption of this method for mosquito-borne disease control.

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Section: Introductionmentioning

confidence: 99%

Wolbachiaincompatible insect technique program optimization over large spatial scales using a process-based model of mosquito metapopulation dynamics

Lim,

Cook,

Bansal

et al. 2024

Preprint

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Update to: Assessing the efficacy of male Wolbachia-infected mosquito deployments to reduce dengue incidence in Singapore

Lim,

Mailepessov,

Chong

et al. 2024

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Background This trial is a parallel, two-arm, non-blinded cluster randomised controlled trial that is under way in Singapore, with the aim of measuring the efficacy of male Wolbachia-infected Aedes aegypti deployments in reducing dengue incidence in an endemic setting with all four dengue serotypes in circulation. The trial commenced in July 2022 and is expected to conclude in September 2024. The original study protocol was published in December 2022. Here, we describe amendments that have been made to the study protocol since commencement of the trial. Methods The key protocol amendments are (1) addition of an explicit definition of Wolbachia exposure for residents residing in intervention sites based on the duration of Wolbachia exposure at point of testing, (2) incorporation of a high-dimensional set of anthropogenic and environmental characteristics in the analysis plan to adjust for baseline risk factors of dengue transmission, and (3) addition of alternative statistical analyses for endpoints to control for post hoc imbalance in cluster-based environmental and anthropogenic characteristics. Discussion The findings from this study will provide the first experimental evidence for the efficacy of releasing male-Wolbachia infected mosquitoes to reduce dengue incidence in a cluster-randomised controlled trial. The trial will conclude in 2024 and results will be reported shortly thereafter. Trial registration ClinicalTrials.gov, identifier: NCT05505682. Registered on 16 August 2022. Retrospectively registered. Last updated 11 November 2023.

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Efficacy ofWolbachia-mediated sterility for control of dengue: emulation of a cluster randomized target trial

Cited by 2 publications

References 22 publications

Wolbachiaincompatible insect technique program optimization over large spatial scales using a process-based model of mosquito metapopulation dynamics

Wolbachiaincompatible insect technique program optimization over large spatial scales using a process-based model of mosquito metapopulation dynamics

Update to: Assessing the efficacy of male Wolbachia-infected mosquito deployments to reduce dengue incidence in Singapore

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