Assessing dengue risk globally using non-Markovian models

IF 2 4区数学 Q2 BIOLOGY Journal of Theoretical Biology Pub Date : 2024-05-31 DOI:10.1016/j.jtbi.2024.111865

Aram Vajdi , Lee W. Cohnstaedt , Caterina M. Scoglio

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Abstract

Dengue is a vector-borne disease transmitted by Aedes mosquitoes. The worldwide spread of these mosquitoes and the increasing disease burden have emphasized the need for a spatio-temporal risk map capable of assessing dengue outbreak conditions and quantifying the outbreak risk. Given that the life cycle of Aedes mosquitoes is strongly influenced by habitat temperature, numerous studies have utilized temperature-dependent development rates of these mosquitoes to construct virus transmission and outbreak risk models. In this study, we contribute to existing research by developing a mechanistic model for the mosquito life cycle that accurately captures its non-Markovian nature. Beginning with integral equations to track the mosquito population across different life cycle stages, we demonstrate how to derive the corresponding differential equations using phase-type distributions. This approach can be further applied to similar non-Markovian processes that are currently described with less accurate Markovian models. By fitting the model to data on human dengue cases, we estimate several model parameters, allowing the development of a global spatiotemporal dengue risk map. This risk model employs temperature and precipitation data to assess the environmental suitability for dengue outbreaks in a given area.

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利用非马尔可夫模型评估全球登革热风险。

登革热是一种由伊蚊传播的病媒传染病。这些蚊子在全球范围内的传播和日益加重的疾病负担凸显了对能够评估登革热爆发条件和量化爆发风险的时空风险地图的需求。鉴于伊蚊的生命周期受栖息地温度的强烈影响，许多研究利用这些蚊子与温度相关的发育率来构建病毒传播和疫情风险模型。在这项研究中，我们为蚊子的生命周期建立了一个机械模型，准确地捕捉到了其非马尔可夫性质，从而为现有研究做出了贡献。我们首先利用积分方程来追踪蚊子在不同生命周期阶段的数量，然后演示了如何利用阶段型分布推导出相应的微分方程。这种方法可进一步应用于目前用不太精确的马尔可夫模型描述的类似非马尔可夫过程。通过将模型与人类登革热病例数据进行拟合，我们估算出了几个模型参数，从而绘制出了全球时空登革热风险地图。该风险模型利用温度和降水数据来评估特定地区登革热爆发的环境适宜性。

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来源期刊

Journal of Theoretical Biology 生物-生物学

CiteScore

4.20

自引率

5.00%

发文量

218

审稿时长

51 days

期刊介绍： The Journal of Theoretical Biology is the leading forum for theoretical perspectives that give insight into biological processes. It covers a very wide range of topics and is of interest to biologists in many areas of research, including: • Brain and Neuroscience • Cancer Growth and Treatment • Cell Biology • Developmental Biology • Ecology • Evolution • Immunology, • Infectious and non-infectious Diseases, • Mathematical, Computational, Biophysical and Statistical Modeling • Microbiology, Molecular Biology, and Biochemistry • Networks and Complex Systems • Physiology • Pharmacodynamics • Animal Behavior and Game Theory Acceptable papers are those that bear significant importance on the biology per se being presented, and not on the mathematical analysis. Papers that include some data or experimental material bearing on theory will be considered, including those that contain comparative study, statistical data analysis, mathematical proof, computer simulations, experiments, field observations, or even philosophical arguments, which are all methods to support or reject theoretical ideas. However, there should be a concerted effort to make papers intelligible to biologists in the chosen field.