Crowded and warmer: Unequal dengue risk at high spatial resolution across a megacity of India

PLOS climate Pub Date : 2024-03-25 DOI:10.1371/journal.pclm.0000240

V. Romeo-Aznar, O. Telle, M. Santos-Vega, R. Paul, Mercedes Pascual

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Abstract

The role of climate factors on transmission of mosquito-borne infections within urban landscapes must be considered in the context of the pronounced spatial heterogeneity of such environments. Socio-demographic and environmental variation challenge control efforts for emergent arboviruses transmitted via the urban mosquito Aedes aegypti. We address at high resolution, the spatial heterogeneity of dengue transmission risk in the megacity of Delhi, India, as a function of both temperature and the carrying-capacity of the human environment for the mosquito. Based on previous results predicting maximum mosquitoes per human for different socio-economic typologies, and on remote sensing temperature data, we produce a map of the reproductive number of dengue at a resolution of 250m by 250m. We focus on dengue risk hotspots during inter-epidemic periods, places where chains of transmission can persist for longer. We assess the resulting high-resolution risk map of dengue with reported cases for three consecutive boreal winters. We find that both temperature and vector carrying-capacity per human co-vary in space because of their respective dependence on population density. The synergistic action of these two factors results in larger variation of dengue’s reproductive number than when considered separately, with poor and dense locations experiencing the warmest conditions and becoming the most likely reservoirs off-season. The location of observed winter cases is accurately predicted for different risk threshold criteria. Results underscore the inequity of risk across a complex urban landscape, whereby individuals in dense poor neighborhoods face the compounded effect of higher temperatures and mosquito carrying capacity. Targeting chains of transmission in inter-epidemic periods at these locations should be a priority of control efforts. A better mapping is needed of the interplay between climate factors that are dominant determinants of the seasonality of vector-borne infections and the socio-economic conditions behind unequal exposure.

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拥挤而温暖：印度特大城市高空间分辨率下的登革热风险不平等

气候因素对蚊媒传染病在城市景观中传播的作用必须结合这种环境的明显空间异质性来考虑。社会人口和环境的变化对通过城市埃及伊蚊传播的新发虫媒病毒的控制工作提出了挑战。我们以高分辨率研究了印度德里特大城市登革热传播风险的空间异质性，它是温度和人类环境对蚊子的承载能力的函数。根据以往对不同社会经济类型的人均蚊子数量的预测结果以及遥感温度数据，我们绘制了一幅分辨率为 250 米乘 250 米的登革热繁殖数量图。我们重点关注登革热流行间歇期的风险热点，即传播链可能持续较长时间的地方。我们利用连续三个北方冬季的报告病例评估了由此绘制的高分辨率登革热风险地图。我们发现，温度和病媒的人均携带能力在空间上是共同变化的，因为它们各自都依赖于人口密度。这两个因素的协同作用导致登革热繁殖数量的变化比单独考虑时更大，贫困和人口稠密的地区经历了最温暖的条件，最有可能成为淡季的疫源地。根据不同的风险阈值标准，可以准确预测观察到的冬季病例的地点。研究结果表明，在复杂的城市环境中，风险是不公平的，居住在密集贫困社区的人面临着较高气温和蚊子携带能力的双重影响。在疫情间歇期，针对这些地区的传播链应是控制工作的重点。气候因素是病媒传染病季节性的主要决定因素，而社会经济条件则是不平等接触的背后因素，需要更好地了解这两者之间的相互作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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PLOS climate

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