Mutations make pandemics worse or better: modeling SARS-CoV-2 variants and imperfect vaccination.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Sarita Bugalia, Jai Prakash Tripathi, Hao Wang
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Abstract

COVID-19 is a respiratory disease triggered by an RNA virus inclined to mutations. Since December 2020, variants of COVID-19 (especially Delta and Omicron) continuously appeared with different characteristics that influenced death and transmissibility emerged around the world. To address the novel dynamics of the disease, we propose and analyze a dynamical model of two strains, namely native and mutant, transmission dynamics with mutation and imperfect vaccination. It is also assumed that the recuperated individuals from the native strain can be infected with mutant strain through the direct contact with individual or contaminated surfaces or aerosols. We compute the basic reproduction number, R 0 , which is the maximum of the basic reproduction numbers of native and mutant strains. We prove the nonexistence of backward bifurcation using the center manifold theory, and global stability of disease-free equilibrium when R 0 < 1 , that is, vaccine is effective enough to eliminate the native and mutant strains even if it cannot provide full protection. Hopf bifurcation appears when the endemic equilibrium loses its stability. An intermediate mutation rate ν 1 leads to oscillations. When ν 1 increases over a threshold, the system regains its stability and exhibits an interesting dynamics called endemic bubble. An analytical expression for vaccine-induced herd immunity is derived. The epidemiological implication of the herd immunity threshold is that the disease may effectively be eradicated if the minimum herd immunity threshold is attained in the community. Furthermore, the model is parameterized using the Indian data of the cumulative number of confirmed cases and deaths of COVID-19 from March 1 to September 27 in 2021, using MCMC method. The cumulative cases and deaths can be reduced by increasing the vaccine efficacies to both native and mutant strains. We observe that by considering the vaccine efficacy against native strain as 90%, both cumulative cases and deaths would be reduced by 0.40%. It is concluded that increasing immunity against mutant strain is more influential than the vaccine efficacy against it in controlling the total cases. Our study demonstrates that the COVID-19 pandemic may be worse due to the occurrence of oscillations for certain mutation rates (i.e., outbreaks will occur repeatedly) but better due to stability at a lower infection level with a larger mutation rate. We perform sensitivity analysis using the Latin Hypercube Sampling methodology and partial rank correlation coefficients to illustrate the impact of parameters on the basic reproduction number, the number of cumulative cases and deaths, which ultimately sheds light on disease mitigation.

Abstract Image

变异使流行病恶化或好转:模拟 SARS-CoV-2 变异和不完善的疫苗接种。
COVID-19 是一种由易发生变异的 RNA 病毒引发的呼吸道疾病。自 2020 年 12 月以来,COVID-19 的变种(尤其是 Delta 和 Omicron)不断出现,它们具有不同的特征,影响着世界各地的死亡和传播。针对该疾病的新动态,我们提出并分析了两种病毒株(即原生株和变异株)的动态模型、变异和不完善疫苗接种的传播动态。我们还假定,从原生菌株中恢复的个体可以通过直接接触个体或受污染的表面或气溶胶感染变异菌株。我们计算了基本繁殖数 R 0,它是原生菌株和变异菌株基本繁殖数的最大值。我们利用中心流形理论证明了后向分岔的不存在性,并证明了当 R 0 1 时无疾病平衡的全局稳定性,即疫苗即使不能提供全面保护,也足以有效消灭原生菌株和变异菌株。当地方病平衡失去稳定性时,就会出现霍普夫分岔。中间突变率 ν 1 会导致振荡。当 ν 1 增大到一个临界值时,系统会恢复稳定,并表现出一种有趣的动态,即地方性气泡。推导出了疫苗诱导的群体免疫的分析表达式。群体免疫力阈值的流行病学含义是,如果社区达到最低群体免疫力阈值,疾病就可能被有效根除。此外,利用印度 2021 年 3 月 1 日至 9 月 27 日 COVID-19 确诊病例和死亡人数的累积数据,采用 MCMC 方法对模型进行了参数化。通过提高原生株和变异株的疫苗效力,可以减少累计病例数和死亡数。我们发现,如果将针对本地毒株的疫苗效力视为 90%,则累计病例和死亡人数都将减少 0.40%。由此得出结论,在控制病例总数方面,提高对变异株的免疫力比提高对变异株的疫苗效力更有影响力。我们的研究表明,COVID-19 大流行可能会因某些突变率的振荡而恶化(即反复爆发),但也可能会因突变率较大时较低感染水平的稳定性而好转。我们使用拉丁超立方采样法和偏等级相关系数进行了敏感性分析,以说明参数对基本繁殖数、累计病例数和死亡数的影响,最终揭示了疾病缓解的方法。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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