Stochastic Modeling in Immunology Based On a Stage-Dependent Framework with Non-Markov Constraints for Individual Cell and Pathogen Dynamics

Q3 Mathematics Mathematical Biology and Bioinformatics Pub Date : 2023-12-13 DOI:10.17537/2023.18.543

N. Pertsev, K. Loginov

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Abstract

We present a systematic approach to modelling the responses of the immune system to virus infections. Two continuous-discrete stochastic models arising in mathematical immunology are developed and computationally implemented. The variables of the models are integer random variables that denote the quantity of individuals (cells and viral particles), and sets of unique types of individuals that take into account the current state and history of stay of individuals in some stages of their development. The distribution laws of the durations of the mentioned stages are different from exponential or geometric. A probabilistic description of a one-stage stochastic model of population dynamics is presented. A stochastic model of the development of HIV-1 infection in the lymph node in the initial period after infection of a healthy person is formulated. A computational algorithm based on the Monte Carlo method is given. Each of the stochastic models is complemented by a deterministic analogue in the form of integral and delay differential equations. The results of numerical simulation are presented.

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基于阶段依赖框架的免疫学随机建模，带有针对单个细胞和病原体动态的非马尔可夫约束条件

我们提出了一种系统的方法来模拟免疫系统对病毒感染的反应。我们建立了数学免疫学中的两个连续-离散随机模型，并对其进行了计算。模型的变量是表示个体（细胞和病毒颗粒）数量的整数随机变量，以及考虑到个体在其发展的某些阶段的当前状态和停留历史的独特个体类型集。上述阶段持续时间的分布规律不同于指数分布或几何分布。本文介绍了种群动态单阶段随机模型的概率描述。建立了健康人感染 HIV-1 后初期淋巴结感染发展的随机模型。给出了一种基于蒙特卡罗方法的计算算法。每个随机模型都有一个积分和延迟微分方程形式的确定性类似模型作为补充。本文介绍了数值模拟的结果。

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Mathematical Biology and Bioinformatics Mathematics-Applied Mathematics

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