Abstract
Mathematical models can assist in the design and understanding of vaccination strategies when resources are limited. Here we propose and analyse an SIR epidemic model with a nonlinear pulse vaccination to examine how a limited vaccine resource affects the transmission and control of infectious diseases, in particular emerging infectious diseases. The threshold condition for the stability of the disease free steady state is given. Latin Hypercube Sampling/Partial Rank Correlation Coefficient uncertainty and sensitivity analysis techniques were employed to determine the key factors which are most significantly related to the threshold value. Comparing this threshold value with that without resource limitation, our results indicate that if resources become limited pulse vaccination should be carried out more frequently than when sufficient resources are available to eradicate an infectious disease. Once the threshold value exceeds a critical level, both susceptible and infected populations can oscillate periodically. Furthermore, when the pulse vaccination period is chosen as a bifurcation parameter, the SIR model with nonlinear pulse vaccination reveals complex dynamics including period doubling, chaotic solutions, and coexistence of multiple attractors. The implications of our findings with respect to disease control are discussed.
Highlights
Epidemiology is the study of the spread of diseases with the objective of tracing factors that are responsible for or contribute to their occurrence and serves as the foundation and logic of interventions made in the interest of public health and preventive medicine
Traditional epidemic models with PVS of population dynamics have assumed that the pulse vaccination proportion p is constant, which implies that medical resources such as drugs, vaccines, hospital beds, and isolation units are sufficient for the infectious disease in question
Chow et al [18] explored the dynamics of an SIR epidemic model to understand how limited medical resources and their supply efficiency affect the transmission of infectious diseases
Summary
Epidemiology is the study of the spread of diseases with the objective of tracing factors that are responsible for or contribute to their occurrence and serves as the foundation and logic of interventions made in the interest of public health and preventive medicine. Traditional epidemic models with PVS of population dynamics have assumed that the pulse vaccination proportion p is constant, which implies that medical resources such as drugs, vaccines, hospital beds, and isolation units are sufficient for the infectious disease in question. Chow et al [18] explored the dynamics of an SIR epidemic model to understand how limited medical resources and their supply efficiency affect the transmission of infectious diseases. Zhou and Fan [19] studied a multigroup SIR epidemiological model to explore the effects of limited medical resources and group-targeted vaccination strategies on disease control and prevention. We will study the dynamic behavior of an SIR epidemic model with nonlinear pulse vaccination Such mathematical models are suitable for simulating processes with short duration perturbations during their development (see [20]). The paper ends with some interesting biological conclusions and numerical bifurcation analyses, which complement the theoretical findings
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