具有生命阶段和感染后无恢复期的双斑 SI 流行病模型中的源-汇动态。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Jimmy Calvo-Monge, Jorge Arroyo-Esquivel, Alyssa Gehman, Fabio Sanchez
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引用次数: 0

摘要

本研究全面分析了一种无感染恢复的双斑块、双生命阶段 SI 模型,重点关注自然种群中疾病传播和宿主种群生存能力的动态变化。该模型的灵感来源于现实世界中的生态危机,如糜烂丝虫病导致的两栖动物种群减少和海星枯萎病导致的海星种群减少,其目的是了解在什么条件下汇宿主种群可以从更健康的源种群中获得生态拯救。数学和数值分析揭示了源种群和汇种群的基本繁殖数量、成熟率和幼体扩散率在决定种群结果方面的关键作用。研究确定了每个斑块的基本繁殖数 R 0,以及基本繁殖数产生接收斑块的条件,在此条件下,接收斑块的种群数量会增加。这些发现为管理受疾病影响的自然种群提供了启示,并对保护策略产生了影响,例如维持具有繁殖能力的避难种群的重要性,以及考虑扩散和成熟率对种群恢复的影响。这项研究强调了空间结构环境中宿主-病原体动态的复杂性,并突出了在面对新出现的疾病时采取多方面方法保护生物多样性的必要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Source-Sink Dynamics in a Two-Patch SI Epidemic Model with Life Stages and No Recovery from Infection.

Source-Sink Dynamics in a Two-Patch SI Epidemic Model with Life Stages and No Recovery from Infection.

This study presents a comprehensive analysis of a two-patch, two-life stage SI model without recovery from infection, focusing on the dynamics of disease spread and host population viability in natural populations. The model, inspired by real-world ecological crises like the decline of amphibian populations due to chytridiomycosis and sea star populations due to Sea Star Wasting Disease, aims to understand the conditions under which a sink host population can present ecological rescue from a healthier, source population. Mathematical and numerical analyses reveal the critical roles of the basic reproductive numbers of the source and sink populations, the maturation rate, and the dispersal rate of juveniles in determining population outcomes. The study identifies basic reproduction numbers R 0 for each of the patches, and conditions for the basic reproduction numbers to produce a receiving patch under which its population. These findings provide insights into managing natural populations affected by disease, with implications for conservation strategies, such as the importance of maintaining reproductively viable refuge populations and considering the effects of dispersal and maturation rates on population recovery. The research underscores the complexity of host-pathogen dynamics in spatially structured environments and highlights the need for multi-faceted approaches to biodiversity conservation in the face of emerging diseases.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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