MosqTent: An Individual Portable Protective Double-chamber Mosquito Trap for Anthropophilic Mosquitoes

Overview

Journal PLoS Negl Trop Dis

Specialties Infectious Diseases
Tropical Medicine

Date 2017 Mar 10

PMID 28278171

Citations 12

Authors

Jose Bento Pereira Lima

Allan Kardec Ribeiro Galardo

Leonardo Soares Bastos

Arthur Weiss da Silva Lima

Maria Goreti Rosa-Freitas

Affiliations

Soon will be listed here.

Abstract

Here, we describe the development of the MosqTent, an innovative double-chamber mosquito trap in which a human being attracts mosquitoes while is protected from being bitten within the inner chamber of the trap, while mosquitoes are lured to enter an outer chamber where they are trapped. The MosqTent previously collected an average of 3,000 anophelines/man-hour compared to 240 anophelines/man-hour for the human landing catch (HLC), thereby providing high numbers of human host-seeking mosquitoes while protecting the collector from mosquito bites. The MosqTent performed well by collecting a high number of specimens of Anopheles marajoara, a local vector and anthropophilic mosquito species present in high density, but not so well in collecting An. darlingi, an anthropophilic mosquito species considered the main vector in Brazil but is present in low-density conditions in the area. The HLC showed a higher efficiency in collecting An. darlingi in these low-density conditions. The MosqTent is light (<1 kg), portable (comes as a bag with two handles), flexible (can be used with other attractants), adaptable (can be deployed in a variety of environmental settings and weather conditions), and it can be used in the intra-, peri-, and in the extradomicile. Also, the MosqTent collected similar portions of parous females and anthropophilic mosquito species and collects specimens suitable for downstream analysis. Further developments may include testing for other fabric colors, different mesh sizes and dimensions for other hematophagous insects and conditions, additional chemical mosquito attractants, and even the replacement of the human attractant in favor of other attractants. MosqTent modifications that would allow the trap to be applied as a vector control tool with killing action could also be explored.

Citing Articles

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Furtado N, Saraiva J, Ribeiro K, Fernandes Neto N, Barroso J, Rodovalho C PLoS One. 2025; 20(1):e0315869.

PMID: 39808618 PMC: 11731733. DOI: 10.1371/journal.pone.0315869.

Evaluation of the effectiveness of the human-baited double net traps and BG traps compared with the human landing catches for collecting outdoor Aedes albopictus in China.

Wu Y, Hou J, Liu Q, Wang J, Li T, Luo M BMC Public Health. 2023; 23(1):1973.

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Anopheline diversity in urban and peri-urban malaria foci: comparison between alternative traps and seasonal effects in a city in the Western Brazilian Amazon.

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An annotated image dataset for training mosquito species recognition system on human skin.

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Larval habitats, species composition and distribution of malaria vectors in regions with autochthonous and imported malaria in Roraima state, Brazil.

de Almeida N, Louzada J, Neves M, Carvalho T, Castro-Alves J, Silva-DO-Nascimento T Malar J. 2022; 21(1):13.

PMID: 35027049 PMC: 8759267. DOI: 10.1186/s12936-021-04033-1.

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