Modelling COVID-19 transmission using IDSIM, an epidemiological-modelling desktop app with multi-level immunization capabilities.

Eleodor Nichita, Mary-Anne Pietrusiak, Fangli Xie, Peter Schwanke, Anjali Pandya
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Abstract

Background: : The coronavirus disease 2019 (COVID-19) pandemic has placed unprecedented demands on local public health units in Ontario, Canada, one of which was the need for in-house epidemiological modelling capabilities. The objective of this study is to develop a native Windows desktop app for epidemiological modelling, to be used by public health unit epidemiologists to predict COVID-19 transmission in Durham Region.

Methods: : The developed app is an implementation of a multi-stratified compartmental epidemiological model that can accommodate multiple virus variants and levels of vaccination, as well as public health measures such as physical distancing, contact tracing followed by quarantine and testing followed by isolation. It was used to investigate the effects of different factors on COVID-19 transmission, including vaccination coverage, vaccine effectiveness, waning of vaccine-induced immunity and the advent of the Omicron variant. The simulation start date was November 22, 2021.

Results: : For the Delta variant, at least 90% of the population would need to be vaccinated to achieve herd immunity. A Delta-variant-only epidemiological curve would be flattened from the start in the absence of immunity waning and within six months in the presence of immunity waning. The percentage of infections caused by the Omicron variant was forecast to increase from 1% to 97% in the first month of the simulation. Total Omicron infections were forecasted to be reduced, respectively, by 26% or 41% if 3,000 or 5,000 booster doses were administered per day.

Conclusion: : For the Delta variant, both natural and vaccination-induced immunity are necessary to achieve herd immunity, and waning of vaccine-induced immunity lengthens the time necessary to reach herd immunity. In the absence of additional public health measures, a wave driven by the Omicron variant was predicted to pose significant public health challenges with infections predicted to peak in 2-3 months from the start of the simulation, depending on the rate of administration of booster doses.

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使用 IDSIM(一款具有多级免疫功能的流行病学建模桌面应用程序)模拟 COVID-19 的传播。
背景: :2019 年冠状病毒病(COVID-19)大流行对加拿大安大略省的地方公共卫生单位提出了前所未有的要求,其中之一就是需要具备内部流行病学建模能力。本研究的目的是开发一个用于流行病学建模的本地 Windows 桌面应用程序,供公共卫生单位的流行病学家用于预测 COVID-19 在达勒姆地区的传播情况:所开发的应用程序是一个多分层分区流行病学模型的实现,可容纳多种病毒变种和疫苗接种水平,以及物理距离、接触追踪后隔离和检测后隔离等公共卫生措施。该模型用于研究不同因素对 COVID-19 传播的影响,包括疫苗接种覆盖率、疫苗有效性、疫苗引起的免疫力减弱以及 Omicron 变种的出现。模拟开始日期为 2021 年 11 月 22 日:对于德尔塔变体,至少需要 90% 的人口接种疫苗才能实现群体免疫。如果没有免疫力减弱,仅德尔塔变体的流行病学曲线将从一开始就趋于平缓;如果有免疫力减弱,则在 6 个月内趋于平缓。预测在模拟的第一个月,由 Omicron 变体引起的感染比例将从 1%增至 97%。如果每天注射 3,000 或 5,000 强化剂量,预计奥米克隆感染总数将分别减少 26% 或 41%:对于德尔塔变体,自然免疫和疫苗诱导免疫都是实现群体免疫的必要条件,而疫苗诱导免疫的减弱会延长实现群体免疫所需的时间。在没有额外公共卫生措施的情况下,预计由奥米克龙变异体驱动的波将对公共卫生构成重大挑战,根据强化剂的接种率,预计感染高峰将在模拟开始后的 2-3 个月内达到。
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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An innovative tool to prioritize the assessment of investigational COVID-19 therapeutics: A pilot project. Evidence brief on facilitators, barriers and hesitancy of COVID-19 booster doses in Canada. Large scale analysis of the SARS-CoV-2 main protease reveals marginal presence of nirmatrelvir-resistant SARS-CoV-2 Omicron mutants in Ontario, Canada, December 2021-September 2023. Lessons learned from COVID-19: Harnessing community insights for better vaccination outcomes. Mathematical modelling for pandemic preparedness in Canada: Learning from COVID-19.
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