Impact of vaccination on the entire population and dose-response relation of COVID-19

Q3 Medicine

Vacunas Pub Date : 2023-10-01 DOI:10.1016/j.vacun.2023.04.004

Abdul Malek, Ashabul Hoque

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引用次数: 0

Abstract

Objective

The objective of this study is to develop a mathematical model for the COVID-19 pandemic including vaccination, the transmissibility of the virus-pathogen dose-response relationship, vaccine efficiency, and vaccination rate.

Methods

The Runge-Kutta (RK-45) method was applied to solve the proposed model with MATLAB code and the calculated results show the dynamics of the individuals in each compartment. The data of total death due to the COVID-19 pandemic in the case of the USA were collected from GitHub and the re-use of this data needs no ethical clearance. The control reproduction number was used to assess the dose-response relationship and critical vaccination coverage.

Results

We have calculated the probability of infection and the infection risk against the different exposure doses and the virus copies, respectively. The results show that the probability of infection increases with the increasing exposure dose for certain virus copies and the risk of infection decreases with the increasing of virus copies for a certain exposure dose. The results also show that the critical vaccination coverage demands increase with an increase in transmission rate and decrease with increasing vaccine efficacy.

Conclusions

It was seen that the critical vaccination coverage corresponding to an increased transmission rate rise sharply in the beginning and then reached a threshold. Moreover, the real data of the total death cases in the USA were compared with the fitted curved of the model which validated the proposed model. Vaccination against COVID-19 is essential to control the pandemic, and achieving high vaccine uptake in the population can reduce the pandemic as fast as possible.

Abstract Image

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疫苗接种对全人群的影响及COVID-19的量效关系

目的建立包括疫苗接种、病毒-病原体传播量效关系、疫苗效率和疫苗接种率在内的2019冠状病毒病大流行的数学模型。方法采用龙格-库塔(RK-45)法对模型进行MATLAB代码求解，计算结果显示了各隔间个体的动力学特性。以美国为例，COVID-19大流行导致的总死亡人数数据来自GitHub，该数据的重复使用无需伦理许可。对照繁殖数用于评估剂量-反应关系和临界疫苗接种覆盖率。结果分别计算了不同暴露剂量和不同病毒拷贝的感染概率和感染风险。结果表明:在一定的暴露剂量下，感染的概率随病毒拷贝数的增加而增加;在一定的暴露剂量下，感染的风险随病毒拷贝数的增加而降低。结果还表明，关键疫苗接种覆盖率需求随传播率的增加而增加，随疫苗效力的提高而降低。结论与传播率升高相对应的临界疫苗接种率在开始时急剧上升，然后达到阈值。并将美国实际死亡总人数数据与模型拟合曲线进行了比较，验证了模型的有效性。针对COVID-19的疫苗接种对于控制大流行至关重要，在人群中实现高疫苗接种率可以尽快减少大流行。

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

Vacunas Medicine-Infectious Diseases

CiteScore

3.90

自引率

0.00%

发文量

138

审稿时长

62 days

期刊介绍： Sin duda una de las mejores publicaciones para conocer los avances en el campo de las vacunaciones preventivas, tanto en el ámbito de la investigación básica como aplicada y en la evaluación de programas de vacunaciones. Su alta calidad y utilidad la ha llevado a estar indexada en los prestigiosos índices IME y SCOPUS.