Impact of increased ventilation on indoor temperature and malaria mosquito density: an experimental study in The Gambia

Jatta, Ebrima; Carrasco-Tenezaca, Majo; Jawara, Musa; Bradley, John; Ceesay, Sainey; D'Alessandro, Umberto; Jeffries, David; Kandeh, Balla; Lee, Daniel Sang-Hoon; Pinder, Margaret; Wilson, Anne L.; Knudsen, Jakob; Lindsay, Steve W.

doi:10.1098/rsif.2020.1030

Impact of increased ventilation on indoor temperature and malaria mosquito density: an experimental study in The Gambia

Jatta, Ebrima; Carrasco-Tenezaca, Majo; Jawara, Musa; Bradley, John; Ceesay, Sainey; D'Alessandro, Umberto; Jeffries, David; Kandeh, Balla; Lee, Daniel Sang-Hoon; Pinder, Margaret; Wilson, Anne L.; Knudsen, Jakob; Lindsay, Steve W.

Authors

Ebrima Jatta

Majo Carrasco-Tenezaca

Musa Jawara

John Bradley

Sainey Ceesay

Umberto D'Alessandro

David Jeffries

Balla Kandeh

Daniel Sang-Hoon Lee

Margaret Pinder

Anne L. Wilson

Jakob Knudsen

Professor Steve Lindsay s.w.lindsay@durham.ac.uk
Professor

Abstract

In sub-Saharan Africa, cooler houses would increase the coverage of insecticide-treated bednets, the primary malaria control tool. We examined whether improved ventilation, using windows screened with netting, cools houses at night and reduces malaria mosquito house entry in The Gambia. Identical houses were constructed, with badly fitting doors the only mosquito entry points. Two men slept in each house and mosquitoes captured using light traps. First, temperature and mosquito density were compared in four houses with 0, 1, 2 and 3 screened windows. Second, carbon dioxide (CO2), a major mosquito attractant, was measured in houses with (i) no windows, (ii) screened windows and (iii) screened windows and screened doors. Computational fluid dynamic modelling captured the spatial movement of CO2. Increasing ventilation made houses cooler, more comfortable and reduced malaria mosquito house entry; with three windows reducing mosquito densities by 95% (95%CI = 90–98%). Screened windows and doors reduced the indoor temperature by 0.6°C (95%CI = 0.5–0.7°C), indoor CO2 concentrations by 31% between 21.00 and 00.00 h and malaria mosquito entry by 76% (95%CI = 69–82%). Modelling shows screening reduces CO2 plumes from houses. Under our experimental conditions, cross-ventilation not only reduced indoor temperature, but reduced the density of house-entering malaria mosquitoes, by weakening CO2 plumes emanating from houses.

Citation

Jatta, E., Carrasco-Tenezaca, M., Jawara, M., Bradley, J., Ceesay, S., D'Alessandro, U., Jeffries, D., Kandeh, B., Lee, D. S.-H., Pinder, M., Wilson, A. L., Knudsen, J., & Lindsay, S. W. (2021). Impact of increased ventilation on indoor temperature and malaria mosquito density: an experimental study in The Gambia. Journal of the Royal Society. Interface, 18(178), Article 20201030. https://doi.org/10.1098/rsif.2020.1030

Journal Article Type	Article
Acceptance Date	Apr 21, 2021
Online Publication Date	May 12, 2021
Publication Date	2021-05
Deposit Date	May 20, 2021
Publicly Available Date	May 21, 2021
Journal	Journal of the Royal Society, Interface
Print ISSN	1742-5689
Electronic ISSN	1742-5662
Publisher	The Royal Society
Peer Reviewed	Peer Reviewed
Volume	18
Issue	178
Article Number	20201030
DOI	https://doi.org/10.1098/rsif.2020.1030
Public URL	https://durham-repository.worktribe.com/output/1247881

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