Efficacy of the spatial repellent product Mosquito Shield™ against wild pyrethroid-resistant Anopheles arabiensis in south-eastern Tanzania

Background Spatial repellents that create airborne concentrations of an active ingredient (AI) within a space offer a scalable solution to further reduce transmission of malaria, by disrupting mosquito behaviours in ways that ultimately lead to reduced human-vector contact. Passive emanator spatial...

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Bibliographic Details
Published in:Malaria journal 2023-08, Vol.22 (1), p.1-249, Article 249
Main Authors: Swai, Johnson Kyeba, Soto, Alina Celest, Ntabaliba, Watson Samuel, Kibondo, Ummi Abdul, Ngonyani, Hassan Ahamad, Mseka, Antony Pius, Ortiz, Anthony, Chura, Madeleine Rose, Mascari, Thomas Michael, Moore, Sarah Jane
Format: Article
Language:English
Subjects:
Anopheles
Anopheles arabiensis
Aquatic insects
Blood
Collections
Control
Culicidae
Disease transmission
Distribution
Emanator
Experimental hut
Experiments
Feeding
Human diseases
Insect baits and repellents
Intervention
Landing behavior
Landing statistics
Malaria
Mosquitoes
Pest control
Pyrethroid
Pyrethroids
Repellents
Spatial repellent
Testing
Transfluthrin
Vector-borne diseases
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Summary:Background Spatial repellents that create airborne concentrations of an active ingredient (AI) within a space offer a scalable solution to further reduce transmission of malaria, by disrupting mosquito behaviours in ways that ultimately lead to reduced human-vector contact. Passive emanator spatial repellents can protect multiple people within the treated space and can last for multiple weeks without the need for daily user touchpoints, making them less intrusive interventions. They may be particularly advantageous in certain use cases where implementation of core tools may be constrained, such as in humanitarian emergencies and among mobile at-risk populations. The purpose of this study was to assess the efficacy of Mosquito Shield[TM] deployed in experimental huts against wild, free-flying, pyrethroid-resistant Anopheles arabiensis mosquitoes in Tanzania over 1 month. Methods The efficacy of Mosquito Shield[TM] transfluthrin spatial repellent in reducing mosquito lands and blood-feeding was evaluated using 24 huts: sixteen huts were allocated to Human Landing Catch (HLC) collections and eight huts to estimating blood-feeding. In both experiments, half of the huts received no intervention (control) while the remaining received the intervention randomly allocated to huts and remained fixed for the study duration. Outcomes measured were mosquito landings, blood-fed, resting and dead mosquitoes. Data were analysed by multilevel mixed effects regression with appropriate dispersion and link function accounting for volunteer, hut and day. Results Landing inhibition was estimated to be 70% (57-78%) [IRR 0.30 (95% CI 0.22-0.43); p < 0.0001] and blood-feeding inhibition was estimated to be 69% (56-79%) [IRR 0.31 (95% CI 0.21-0.44; p < 0.0001] There was no difference in the protective efficacy estimates of landing and blood-feeding inhibition [IRR 0.98 (95% CI 0.53-1.82; p = 0.958]. Conclusions This study demonstrated that Mosquito Shield[TM] was efficacious against a wild pyrethroid-resistant strain of An. arabiensis mosquitoes in Tanzania for up to 1 month and could be used as a complementary or stand-alone tool where gaps in protection offered by core malaria vector control tools exist. HLC is a suitable technique for estimating bite reductions conferred by spatial repellents especially where direct blood-feeding measurements are not practical or are ethically limited. Keywords: Spatial repellent, Emanator, Anopheles, Pyrethroid, Transfluthrin, Experimental hut
ISSN:1475-2875
1475-2875
DOI:10.1186/s12936-023-04674-4