Integrating behavioral dynamics and allee effect in eco-epidemiological model: A comprehensive approach to disease impact

• Published in: PloS one Vol. 20; no. 5; p. e0323928
• Main Author: Kabir, K. M. Ariful
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 22.05.2025; Public Library of Science (PLoS)
• Subjects: Animals; Behavior; Biology and Life Sciences; Communicable diseases; Communicable Diseases - epidemiology; Communicable Diseases - transmission; Computer Simulation; Cooperation; Decision making; Disease control; Disease prevention; Disease spread; Disease transmission; Distribution; Dynamics; Ecology and Environmental Sciences; Ecosystem; Ecosystems; Endangered & extinct species; Epidemic models; Epidemics; Epidemiological Models; Epidemiology; Food; Game Theory; Health aspects; Health risks; Humans; Infections; Infectious diseases; Influence; Mathematical models; Medicine and Health Sciences; Models, Biological; Numerical simulations; Oscillations; Population Dynamics; Population stability; Predation; Predation (Biology); Predator-prey interactions; Predator-prey simulation; Predators; Predatory Behavior; Prey; Salinity; Species extinction; Stability; Stochastic models; Systems stability; Bangladesh
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0323928

Predator-prey models in ecology typically focus on direct predation without considering other interactions, such as hunting behaviors on qualitative impact and numerous diseases, which has led researchers to explore the intersection of ecology and mathematics, resulting in the development of mathematical models. This paper introduces a novel eco-epidemiological model that integrates the dynamics of infectious diseases within predator-prey interactions, factoring in direct predation, the roles of infected prey, and the influence of behavioral dynamics. By utilizing evolutionary game theory, this study explores the effects of cooperation and non-cooperation strategies on disease spread and population stability. Numerical simulations reveal that disease transmission rates and the Allee effect significantly impact population stability. Low transmission rates favor stability, while higher rates provoke periodic oscillations that can destabilize the population. The associated controlling cost reduces the risk of infection in prey populations, affecting the predator population. Moreover, the Allee effect exacerbates prey vulnerability, increasing the risk of predator extinction unless disease transmission is curtailed. Findings underscore the importance of considering behavioral dynamics and epidemic factors in conserving species and managing infectious diseases, offering valuable insights into the complex interactions that govern ecosystem health and stability.