使用综合建模方法衡量 COVID-19 的全球传播。

Measuring the worldwide spread of COVID-19 using a comprehensive modeling method.

机构信息

Department of Critical Care Medicine, State Key Laboratory for Complex Severe and Rare Diseases, Peking Union Medical College Hospital, Peking Union Medical College and Chinese Academy of Medical Sciences, Beijing, 100730, China.

Department of Medical Administration, National Health Commission of the People's Republic of China, Beijing, 100044, China.

出版信息

BMC Med Inform Decis Mak. 2023 Sep 15;21(Suppl 9):384. doi: 10.1186/s12911-023-02213-4.

DOI:10.1186/s12911-023-02213-4

PMID:37715170

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10504693/

Abstract

BACKGROUND

With the global spread of COVID-19, detecting high-risk countries/regions timely and dynamically is essential; therefore, we sought to develop automatic, quantitative and scalable analysis methods to observe and estimate COVID-19 spread worldwide and further generate reliable and timely decision-making support for public health management using a comprehensive modeling method based on multiple mathematical models.

METHODS

We collected global COVID-19 epidemic data reported from January 23 to September 30, 2020, to observe and estimate its possible spread trends. Countries were divided into three outbreak levels: high, middle, and low. Trends analysis was performed by calculating the growth rate, and then country grouping was implemented using group-based trajectory modeling on the three levels. Individual countries from each group were also chosen to further disclose the outbreak situations using two predicting models: the logistic growth model and the SEIR model.

RESULTS

All 187 observed countries' trajectory subgroups were identified using two grouping strategies: with and without population consideration. By measuring epidemic trends and predicting the epidemic size and peak of individual countries, our study found that the logistic growth model generally estimated a smaller epidemic size than the SEIR model. According to SEIR modeling, confirmed cases in each country would take an average of 9-12 months to reach the outbreak peak from the day the first case occurred. Additionally, the average number of cases at the peak time will reach approximately 10-20% of the countries' populations, and the countries with high trends and a high predicted size must pay special attention and implement public health interventions in a timely manner.

CONCLUSIONS

We demonstrated comprehensive observations and predictions of the COVID-19 outbreak in 187 countries using a comprehensive modeling method. The methods proposed in this study can measure COVID-19 development from multiple perspectives and are generalizable to other epidemic diseases. Furthermore, the methods also provide reliable and timely decision-making support for public health management.

摘要

背景

随着 COVID-19 在全球的传播，及时、动态地检测高危国家/地区至关重要；因此，我们寻求开发自动、定量和可扩展的分析方法，以便使用基于多种数学模型的综合建模方法，观察和估计全球 COVID-19 的传播，并进一步为公共卫生管理生成可靠且及时的决策支持。

方法

我们收集了 2020 年 1 月 23 日至 9 月 30 日全球 COVID-19 疫情报告的流行数据，以观察和估计其可能的传播趋势。国家分为高、中、低三个暴发水平。通过计算增长率对趋势进行分析，然后在三个水平上使用基于群组的轨迹建模对国家进行分组。使用两种预测模型：逻辑增长模型和 SEIR 模型，进一步选择每个组中的个别国家来揭示暴发情况。

结果

使用两种分组策略：有和没有人口考虑，确定了所有 187 个观察国家的轨迹子组。通过衡量流行趋势并预测个别国家的流行规模和高峰，我们的研究发现逻辑增长模型通常估计的流行规模小于 SEIR 模型。根据 SEIR 建模，从首例病例发生之日起，每个国家的确诊病例平均需要 9-12 个月达到暴发高峰。此外，高峰时间的病例平均数将达到各国人口的 10-20%左右，趋势高且预测规模大的国家必须特别注意并及时采取公共卫生干预措施。

结论

我们使用综合建模方法对 187 个国家的 COVID-19 暴发进行了全面观察和预测。本研究提出的方法可以从多个角度衡量 COVID-19 的发展，并且可推广到其他传染病。此外，这些方法还为公共卫生管理提供可靠且及时的决策支持。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/70af/10504693/b6e39caaf1f9/12911_2023_2213_Fig1_HTML.jpg

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使用综合建模方法衡量 COVID-19 的全球传播。

Measuring the worldwide spread of COVID-19 using a comprehensive modeling method.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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