Model analysis and data validation of structured prevention and control interruptions of emerging infectious diseases

IF 2.2 4区 数学 Q2 BIOLOGY Journal of Mathematical Biology Pub Date : 2024-04-14 DOI:10.1007/s00285-024-02083-y
Hao Zhou, He Sha, Robert A. Cheke, Sanyi Tang
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Abstract

The design of optimized non-pharmaceutical interventions (NPIs) is critical to the effective control of emergent outbreaks of infectious diseases such as SARS, A/H1N1 and COVID-19 and to ensure that numbers of hospitalized cases do not exceed the carrying capacity of medical resources. To address this issue, we formulated a classic SIR model to include a close contact tracing strategy and structured prevention and control interruptions (SPCIs). The impact of the timing of SPCIs on the maximum number of non-isolated infected individuals and on the duration of an infectious disease outside quarantined areas (i.e. implementing a dynamic zero-case policy) were analyzed numerically and theoretically. These analyses revealed that to minimize the maximum number of non-isolated infected individuals, the optimal time to initiate SPCIs is when they can control the peak value of a second rebound of the epidemic to be equal to the first peak value. More individuals may be infected at the peak of the second wave with a stronger intervention during SPCIs. The longer the duration of the intervention and the stronger the contact tracing intensity during SPCIs, the more effective they are in shortening the duration of an infectious disease outside quarantined areas. The dynamic evolution of the number of isolated and non-isolated individuals, including two peaks and long tail patterns, have been confirmed by various real data sets of multiple-wave COVID-19 epidemics in China. Our results provide important theoretical support for the adjustment of NPI strategies in relation to a given carrying capacity of medical resources.

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新发传染病结构化预防和控制中断的模型分析和数据验证
设计优化的非药物干预措施(NPIs)对于有效控制 SARS、A/H1N1 和 COVID-19 等突发传染病以及确保住院病例数不超过医疗资源的承载能力至关重要。为解决这一问题,我们制定了一个经典的 SIR 模型,其中包括密切接触者追踪策略和结构化防控中断(SPCIs)。我们从数值和理论上分析了 SPCI 的时机对非隔离感染者最大数量和隔离区外传染病持续时间(即实施动态零病例政策)的影响。这些分析表明,为了最大限度地减少非隔离感染个体的数量,启动 SPCI 的最佳时机是能够控制疫情第二次反弹的峰值与第一次峰值相等时。在 SPCI 期间加强干预,可能会有更多的人在第二波高峰期受到感染。SPCI 期间的干预持续时间越长,接触追踪力度越大,就越能有效缩短隔离区外的传染病持续时间。隔离和非隔离个体数量的动态演变,包括两个高峰和长尾模式,已被中国多波 COVID-19 流行的各种真实数据集所证实。我们的研究结果为根据特定医疗资源承载能力调整 NPI 策略提供了重要的理论支持。
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来源期刊
CiteScore
3.30
自引率
5.30%
发文量
120
审稿时长
6 months
期刊介绍: The Journal of Mathematical Biology focuses on mathematical biology - work that uses mathematical approaches to gain biological understanding or explain biological phenomena. Areas of biology covered include, but are not restricted to, cell biology, physiology, development, neurobiology, genetics and population genetics, population biology, ecology, behavioural biology, evolution, epidemiology, immunology, molecular biology, biofluids, DNA and protein structure and function. All mathematical approaches including computational and visualization approaches are appropriate.
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