היצוא הצליח — 

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

 

שמור ב:
מידע ביבליוגרפי
Autores: Calvo Monge, Jimmy José, Arroyo Esquivel, Jorge, Gehman, Alyssa, Sánchez Peña, Fabio Ariel
פורמט: artículo original
Fecha de Publicación:2024
תיאור: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.
País:Kérwá
מוסד:Universidad de Costa Rica
Repositorio:Kérwá
שפה:Inglés
OAI Identifier:oai:kerwa.ucr.ac.cr:10669/104614
גישה מקוונת:https://hdl.handle.net/10669/104614
https://doi.org/10.1007/s11538-024-01328-7
מילת מפתח:Mathematical modeling
Ecology
Sea stars
Population dynamics
Patch epidemic model
Dispersal
Non-recovery models
Stability analysis
Infectious diseases
Host population
Ecological crisis
Environmental conservation