Climate-responsive vector control strategies for Aedes albopictus.

IF 3 2区医学 Q1 PARASITOLOGY

Parasites & Vectors Pub Date : 2025-05-11 DOI:10.1186/s13071-025-06791-2

Jesús Bellver-Arnau, Laura Blanco-Sierra, Santi Escartin, Simone Mariani, Frederic Bartumeus

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引用次数: 0

Abstract

Background: The rise in mosquito-borne diseases such as dengue, Zika, and chikungunya, exacerbated by the ever-expanding habitats of Aedes albopictus, poses a significant public health risk. Even marginal improvements in vector control efficacy can be crucial in mitigating these risks.

Methods: In this study, we employed a metapopulation model to simulate Ae. albopictus population dynamics and dispersal, optimizing the timing and spatial allocation of larvicidal treatments.

Results: Simulations revealed that larvicide treatments are most effective when applied preventively, early in the mosquito season, particularly under conditions of lower-than-average cumulative rainfall and, to a minor extent, colder-than-average temperatures, as these conditions limit larvae proliferation. We found that breeding site characteristics, particularly surface area and maximum water holding capacity, are critical in determining optimal treatment allocation in scarce-resource scenarios. However, a cost-effectiveness trade-off exists, as larger breeding sites offer more substantial reductions in mosquito populations but also demand higher larvicide dosages. Spatial factors such as breeding site distribution had minimal impact on treatment efficacy, possibly due to the high mobility range of adult mosquitoes compared with the size of the study area.

Conclusions: Our results highlight the superior efficiency of the optimized approach in comparison with routine vector control strategies, especially when resources are limited, offering a more effective use of larvicide in controlling mosquito populations. This study demonstrates that vector control strategies for Ae. albopictus can be significantly enhanced by considering climatic variables and breeding site characteristics in treatment planning. This research provides a framework for developing cost-effective and flexible mosquito control programs that can adapt to environmental conditions, potentially improving public health outcomes by reducing the transmission risk of mosquito-borne diseases.

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应对气候变化的白纹伊蚊病媒控制策略。

背景：随着白纹伊蚊栖息地的不断扩大，登革热、寨卡病毒和基孔肯雅热等蚊媒疾病的增加，构成了重大的公共卫生风险。即使是病媒控制效果的微小改善，也可能对减轻这些风险至关重要。方法：在本研究中，我们采用一个元种群模型来模拟伊蚊。白纹伊蚊种群动态和扩散，优化杀幼虫处理的时间和空间配置。结果：模拟显示，在蚊虫季节早期预防性使用杀幼虫剂最有效，特别是在累积降雨量低于平均水平和在较小程度上低于平均温度的条件下，因为这些条件限制了幼虫的繁殖。我们发现，在资源稀缺的情况下，养殖地点的特征，特别是表面积和最大持水量，是决定最佳处理分配的关键。然而，成本效益的权衡是存在的，因为较大的繁殖地点可以更大幅度地减少蚊子的数量，但也需要更高的杀幼虫剂剂量。孳生地分布等空间因素对防治效果的影响较小，这可能是由于成蚊的迁移范围相对于研究区域的大小较大。结论：与常规媒介控制方法相比，优化后的方法效率更高，特别是在资源有限的情况下，可以更有效地利用杀幼虫剂控制蚊虫数量。本研究为伊蚊病媒控制策略提供了依据。在处理计划中考虑气候变量和孳生地特点，可显著增强白纹伊蚊的数量。这项研究为开发具有成本效益和灵活的蚊子控制项目提供了一个框架，这些项目可以适应环境条件，通过降低蚊子传播疾病的传播风险，有可能改善公共卫生结果。

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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来源期刊

Parasites & Vectors 医学-寄生虫学

CiteScore

6.30

自引率

9.40%

发文量

433

审稿时长

1.4 months

期刊介绍： Parasites & Vectors is an open access, peer-reviewed online journal dealing with the biology of parasites, parasitic diseases, intermediate hosts, vectors and vector-borne pathogens. Manuscripts published in this journal will be available to all worldwide, with no barriers to access, immediately following acceptance. However, authors retain the copyright of their material and may use it, or distribute it, as they wish. Manuscripts on all aspects of the basic and applied biology of parasites, intermediate hosts, vectors and vector-borne pathogens will be considered. In addition to the traditional and well-established areas of science in these fields, we also aim to provide a vehicle for publication of the rapidly developing resources and technology in parasite, intermediate host and vector genomics and their impacts on biological research. We are able to publish large datasets and extensive results, frequently associated with genomic and post-genomic technologies, which are not readily accommodated in traditional journals. Manuscripts addressing broader issues, for example economics, social sciences and global climate change in relation to parasites, vectors and disease control, are also welcomed.