年龄异质性和疫苗接种对 SARS-CoV-2 的动态和控制作用的数学评估

IF 8.8 3区 医学 Q1 Medicine Infectious Disease Modelling Pub Date : 2024-04-26 DOI:10.1016/j.idm.2024.04.007
Binod Pant , Abba B. Gumel
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引用次数: 0

摘要

在由 SARS-CoV-2 引起的 COVID-19 大流行中,社会中的某些群体受到了不成比例的影响,尤其是老年人群(他们在疾病的严重程度、住院和死亡方面首当其冲)。本研究提出了一个具有多个异质性子人群的广义多群体模型,以评估年龄异质性和疫苗接种对美国 SARS-CoV-2 大流行的传播动态和控制的影响。对该模型的同质情况(即 m = 1 的模型)进行的严格分析表明,只要相关的繁殖数量小于 1,在两种特殊情况下(疫苗完全有效或疾病引起的死亡率可忽略不计),该模型的无病平衡是全局渐近稳定的。当相关的繁殖临界值超过 1 时,该模型在特殊情况下具有唯一的、全球渐近稳定的地方病平衡。利用美国三个不同波段(A 波段(2020 年 10 月 17 日至 2021 年 4 月 5 日)、B 波段(2021 年 7 月 9 日至 2021 年 11 月 7 日)和 C 波段(2022 年 1 月 1 日至 2022 年 5 月 7 日))的累积死亡率观测数据对均质模型进行了拟合,这些波段分别与阿尔法、德尔塔和奥密克龙变种在美国占主导地位的时间段相吻合。校准模型用于推导实现疫苗衍生群体免疫力(在美国消灭该疾病所需的免疫力)的理论表达式。结果表明,使用单组同质模型,在美国大流行的 C 波期间,无论完全接种者的覆盖水平如何,都无法实现疫苗衍生的群体免疫力。为确定对疾病动态和负担影响最大的模型参数,我们进行了全局敏感性分析。这些分析表明,在一个波次中可能非常有效的控制和缓解策略,在另一个或多个波次中可能并不那么有效。然而,针对无症状和症状前感染者的策略在所有波次中都显示出持续的有效性。为了研究 COVID-19 对老年人群的过度影响,我们考虑了将总人口细分为 65 岁以下和 65 岁及以上两个子人群的异质模型。我们还利用 C 波的累积死亡率数据对由此得出的两组异质模型进行了严格分析。与单组模型不同的是,双组模型显示,如果至少有 61% 的人口完全接种了疫苗,那么在大流行的 C 波期间确实可以实现疫苗衍生的群体免疫。因此,本研究表明,在同质混合的 SARS-CoV-2 疫苗接种模型中加入年龄异质性,可显著降低实现疫苗衍生群体免疫所需的疫苗接种覆盖水平(具体而言,对于异质性模型,如果适度比例的易感个体完全接种疫苗,则可在 C 波期间实现群体免疫)。这一结果的后果是,未明确考虑年龄异质性的 SARS-CoV-2 疫苗接种模型可能高估了消除 SARS-CoV-2 大流行所需的疫苗衍生群体免疫力阈值水平。
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Mathematical assessment of the roles of age heterogeneity and vaccination on the dynamics and control of SARS-CoV-2

The COVID-19 pandemic, caused by SARS-CoV-2, disproportionately affected certain segments of society, particularly the elderly population (which suffered the brunt of the burden of the pandemic in terms of severity of the disease, hospitalization, and death). This study presents a generalized multigroup model, with m heterogeneous sub-populations, to assess the population-level impact of age heterogeneity and vaccination on the transmission dynamics and control of the SARS-CoV-2 pandemic in the United States. Rigorous analysis of the model for the homogeneous case (i.e., the model with m = 1) reveal that its disease-free equilibrium is globally-asymptotically stable for two special cases (with perfect vaccine efficacy or negligible disease-induced mortality) whenever the associated reproduction number is less than one. The model has a unique and globally-asymptotically stable endemic equilibrium, for special a case, when the associated reproduction threshold exceeds one. The homogeneous model was fitted using the observed cumulative mortality data for the United States during three distinct waves (Waves A (October 17, 2020 to April 5, 2021), B (July 9, 2021 to November 7, 2021) and C (January 1, 2022 to May 7, 2022)) chosen to align with time periods when the Alpha, Delta and Omicron were, respectively, the predominant variants in the United States. The calibrated model was used to derive a theoretical expression for achieving vaccine-derived herd immunity (needed to eliminate the disease in the United States). It was shown that, using the one-group homogeneous model, vaccine-derived herd immunity is not attainable during Wave C of the pandemic in the United States, regardless of the coverage level of the fully-vaccinated individuals. Global sensitivity analysis was carried out to determine the parameters of the model that have the most influence on the disease dynamics and burden. These analyses reveal that control and mitigation strategies that may be very effective during one wave may not be so very effective during the other wave or waves. However, strategies that target asymptomatic and pre-symptomatic infectious individuals are shown to be consistently effective across all waves. To study the impact of the disproportionate effect of COVID-19 on the elderly population, we considered the heterogeneous model for the case where the total population is subdivided into the sub-populations of individuals under 65 years of age and those that are 65 and older. The resulting two-group heterogeneous model, which was also fitted using the cumulative mortality data for wave C, was also rigorously analysed. Unlike for the case of the one-group model, it was shown, for the two-group model, that vaccine-derived herd immunity can indeed be achieved during Wave C of the pandemic if at least 61% of the populace is fully vaccinated. Thus, this study shows that adding age heterogeneity into a SARS-CoV-2 vaccination model with homogeneous mixing significantly reduces the level of vaccination coverage needed to achieve vaccine-derived herd immunity (specifically, for the heterogeneous model, herd-immunity can be attained during Wave C if a moderate proportion of susceptible individuals are fully vaccinated). The consequence of this result is that vaccination models for SARS-CoV-2 that do not explicitly account for age heterogeneity may be overestimating the level of vaccine-derived herd immunity threshold needed to eliminate the SARS-CoV-2 pandemic.

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来源期刊
Infectious Disease Modelling
Infectious Disease Modelling Mathematics-Applied Mathematics
CiteScore
17.00
自引率
3.40%
发文量
73
审稿时长
17 weeks
期刊介绍: Infectious Disease Modelling is an open access journal that undergoes peer-review. Its main objective is to facilitate research that combines mathematical modelling, retrieval and analysis of infection disease data, and public health decision support. The journal actively encourages original research that improves this interface, as well as review articles that highlight innovative methodologies relevant to data collection, informatics, and policy making in the field of public health.
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