A Novel Sampling Method to Measure Socioeconomic Drivers of Aedes Albopictus Distribution in Mecklenburg County, North Carolina

Overview

Journal Int J Environ Res Public Health

Publisher MDPI

Specialties Environmental Health
Public Health

Date 2018 Oct 11

PMID 30301172

Citations 8

Authors

Ari Whiteman

Eric Delmelle

Tyler Rapp

Shi Chen

Gang Chen

Michael Dulin

Affiliations

Soon will be listed here.

Abstract

Climate change, urbanization, and globalization have facilitated the spread of mosquitoes into regions that were previously unsuitable, causing an increased threat of arbovirus transmission on a global scale. While numerous studies have addressed the urban ecology of , few have accounted for socioeconomic factors that affect their range in urban regions. Here we introduce an original sampling design for , that uses a spatial optimization process to identify urban collection sites based on both geographic parameters as well as the gradient of socioeconomic variables present in Mecklenburg County, North Carolina, encompassing the city of Charlotte, a rapidly growing urban environment. We collected 3,645 specimens of (87% of total samples) across 12 weeks at the 90 optimized site locations and modelled the relationships between the abundance of gravid and a variety of neighborhood socioeconomic attributes as well as land cover characteristics. Our results demonstrate that the abundance of gravid is inversely related to the socioeconomic status of the neighborhood and directly related to both landscape heterogeneity as well as proportions of particular resident races/ethnicities. We present our results alongside a description of our novel sampling scheme and its usefulness as an approach to urban vector epidemiology. Additionally, we supply recommendations for future investigations into the socioeconomic determinants of vector-borne disease risk.

Citing Articles

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Examining Wing Length-Abundance Relationships and Pyrethroid Resistance Mutations among in a Rapidly Growing Urban Area with Implications for Mosquito Surveillance and Control.

Mundis S, Hamerlinck G, Stone E, Whiteman A, Delmelle E, Rapp T Int J Environ Res Public Health. 2021; 18(18).

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Semi-field assessment of the Gravid Aedes Trap (GAT) with the aim of controlling Aedes (Stegomyia) aegypti populations.

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Short-Term, Large-Area Survey of Container (Diptera: Culicidae): Presence and Abundance is Associated with Fine-scale Landscape Factors in North Carolina, USA.

Reiskind M, Styers D, Hayes I, Richards S, Doyle M, Reed E Environ Health Insights. 2020; 14:1178630220952806.

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Integrating environmental and neighborhood factors in MaxEnt modeling to predict species distributions: A case study of Aedes albopictus in southeastern Pennsylvania.

Wiese D, Escalante A, Murphy H, Henry K, Gutierrez-Velez V PLoS One. 2019; 14(10):e0223821.

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