A deterministic transmission model for analytics-driven optimization of COVID-19 post-pandemic vaccination and quarantine strategies.

IF 2.6 4区 工程技术 Q1 Mathematics Mathematical Biosciences and Engineering Pub Date : 2024-03-01 DOI:10.3934/mbe.2024219
C K Mahadhika, Dipo Aldila
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Abstract

This study developed a deterministic transmission model for the coronavirus disease of 2019 (COVID-19), considering various factors such as vaccination, awareness, quarantine, and treatment resource limitations for infected individuals in quarantine facilities. The proposed model comprised five compartments: susceptible, vaccinated, quarantined, infected, and recovery. It also considered awareness and limited resources by using a saturated function. Dynamic analyses, including equilibrium points, control reproduction numbers, and bifurcation analyses, were conducted in this research, employing analytics to derive insights. Our results indicated the possibility of an endemic equilibrium even if the reproduction number for control was less than one. Using incidence data from West Java, Indonesia, we estimated our model parameter values to calibrate them with the real situation in the field. Elasticity analysis highlighted the crucial role of contact restrictions in reducing the spread of COVID-19, especially when combined with community awareness. This emphasized the analytics-driven nature of our approach. We transformed our model into an optimal control framework due to budget constraints. Leveraging Pontriagin's maximum principle, we meticulously formulated and solved our optimal control problem using the forward-backward sweep method. Our experiments underscored the pivotal role of vaccination in infection containment. Vaccination effectively reduces the risk of infection among vaccinated individuals, leading to a lower overall infection rate. However, combining vaccination and quarantine measures yields even more promising results than vaccination alone. A second crucial finding emphasized the need for early intervention during outbreaks rather than delayed responses. Early interventions significantly reduce the number of preventable infections, underscoring their importance.

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用于分析优化 COVID-19 大流行后疫苗接种和检疫策略的确定性传播模型。
本研究建立了 2019 年冠状病毒病(COVID-19)的确定性传播模型,考虑了疫苗接种、认知、隔离和隔离设施中感染者治疗资源限制等各种因素。拟议模型包括五个部分:易感者、接种疫苗者、隔离者、感染者和康复者。该模型还使用饱和函数考虑了意识和有限的资源。本研究进行了动态分析,包括平衡点、控制繁殖数和分叉分析,并利用分析方法得出了见解。我们的研究结果表明,即使控制繁殖数小于 1,也有可能出现地方性平衡。利用印度尼西亚西爪哇的发病率数据,我们对模型参数值进行了估算,使其与实地的实际情况相吻合。弹性分析强调了接触限制在减少 COVID-19 传播中的关键作用,尤其是在与社区意识相结合的情况下。这强调了我们方法的分析驱动性质。由于预算限制,我们将模型转化为优化控制框架。利用庞特里亚金的最大值原理,我们精心制定了最优控制问题,并使用前向后退扫频法进行了求解。我们的实验强调了疫苗接种在遏制感染中的关键作用。接种疫苗可有效降低接种者的感染风险,从而降低总体感染率。然而,与单独接种疫苗相比,将接种疫苗和隔离措施结合起来会产生更有希望的结果。第二个重要发现强调了在疫情爆发时尽早干预而不是延迟应对的必要性。早期干预大大减少了可预防感染的数量,突出了其重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Mathematical Biosciences and Engineering
Mathematical Biosciences and Engineering 工程技术-数学跨学科应用
CiteScore
3.90
自引率
7.70%
发文量
586
审稿时长
>12 weeks
期刊介绍: Mathematical Biosciences and Engineering (MBE) is an interdisciplinary Open Access journal promoting cutting-edge research, technology transfer and knowledge translation about complex data and information processing. MBE publishes Research articles (long and original research); Communications (short and novel research); Expository papers; Technology Transfer and Knowledge Translation reports (description of new technologies and products); Announcements and Industrial Progress and News (announcements and even advertisement, including major conferences).
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