具有免疫反应的登革热病毒宿主内传播模型

Q2 Mathematics
P. Muthu, Bikash Modak
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引用次数: 0

摘要

摘要登革热是一种传染性病毒性发热。病毒在体内的复杂行为可以通过数学模型来解释,以了解病毒的动力学。我们提出了两种不同的具有体液免疫反应的登革热病毒宿主内传播模型。所提出的模型彼此不同,因为其中一个模型假设新形成的病毒会再次感染健康细胞。为了了解所提出模型的动力学,我们对稳定性分析、数值模拟和灵敏度分析进行了比较研究。使用下一代矩阵方法计算两个模型的基本再现数(BRN)。用线性化方法讨论了局部稳定性分析。李雅普诺夫直接法用于检验模型的全局稳定性。已经发现,基于BRN的值,两个模型的平衡状态,即无病毒平衡状态和地方病平衡状态,都是全局稳定的。结果显示免疫反应对细胞动力学和病毒颗粒的影响。抗体的病毒中和率和影响抗体生长的速率对这两个模型高度敏感。应用最优控制来探索防止病毒在宿主系统中传播的可能控制策略。从结果中可以明显看出,使用抗生素和家庭疗法的策略可以减缓病毒在宿主中的传播。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Within-host models of dengue virus transmission with immune response
Abstract Dengue fever is an infectious viral fever. The complex behavior of the virus within the body can be explained through mathematical models to understand the virus’s dynamics. We propose two different with-in host models of dengue virus transmission with humoral immune response. The proposed models differ from one another because one of the models assumes that newly formed viruses infect healthy cells again. To understand the dynamics of the proposed models, we perform a comparative study of stability analysis, numerical simulation, and sensitivity analysis. The basic reproduction number (BRN) of the two models is computed using next-generation matrix method. The local stability (l.s) analysis is discussed using the linearization method. The Lyapunov’s direct method is used to check the global stability (g.s) of the models. It has been found that both the equilibrium states for both the models, namely, virus-free equilibrium state and endemic equilibrium state, are globally stable, based on the value of BRN. Results show the influence of immune response on the cell dynamics and virus particles. The virus neutralization rate by antibodies and rate that affects the antibody growth are highly sensitive for the two models. Optimal control is applied to explore the possible control strategies to prevent virus spread in the host system. It is evident from the results that the strategy to administrate antibiotic drugs and home remedies slow down the virus spread in the host.
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来源期刊
Computational and Mathematical Biophysics
Computational and Mathematical Biophysics Mathematics-Mathematical Physics
CiteScore
2.50
自引率
0.00%
发文量
8
审稿时长
30 weeks
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