Real-time mechanistic Bayesian forecasts of COVID-19 mortality

The Annals of Applied Statistics Pub Date : 2023-09-01 DOI:10.1214/22-aoas1671

Graham C. Gibson, Nicholas G. Reich, Daniel Sheldon

{"title":"Real-time mechanistic Bayesian forecasts of COVID-19 mortality","authors":"Graham C. Gibson, Nicholas G. Reich, Daniel Sheldon","doi":"10.1214/22-aoas1671","DOIUrl":null,"url":null,"abstract":"The COVID-19 pandemic emerged in late December 2019. In the first six months of the global outbreak, the U.S. reported more cases and deaths than any other country in the world. Effective modeling of the course of the pandemic can help assist with public health resource planning, intervention efforts, and vaccine clinical trials. However, building applied forecasting models presents unique challenges during a pandemic. First, case data available to models in real time represent a nonstationary fraction of the true case incidence due to changes in available diagnostic tests and test-seeking behavior. Second, interventions varied across time and geography leading to large changes in transmissibility over the course of the pandemic. We propose a mechanistic Bayesian model that builds upon the classic compartmental susceptible–exposed–infected–recovered (SEIR) model to operationalize COVID-19 forecasting in real time. This framework includes nonparametric modeling of varying transmission rates, nonparametric modeling of case and death discrepancies due to testing and reporting issues, and a joint observation likelihood on new case counts and new deaths; it is implemented in a probabilistic programming language to automate the use of Bayesian reasoning for quantifying uncertainty in probabilistic forecasts. The model has been used to submit forecasts to the U.S. Centers for Disease Control through the COVID-19 Forecast Hub under the name MechBayes. We examine the performance relative to a baseline model as well as alternate models submitted to the forecast hub. Additionally, we include an ablation test of our extensions to the classic SEIR model. We demonstrate a significant gain in both point and probabilistic forecast scoring measures using MechBayes, when compared to a baseline model, and show that MechBayes ranks as one of the top two models out of nine which regularly submitted to the COVID-19 Forecast Hub for the duration of the pandemic, trailing only the COVID-19 Forecast Hub ensemble model of which which MechBayes is a part.","PeriodicalId":188068,"journal":{"name":"The Annals of Applied Statistics","volume":"24 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2023-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"The Annals of Applied Statistics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1214/22-aoas1671","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

The COVID-19 pandemic emerged in late December 2019. In the first six months of the global outbreak, the U.S. reported more cases and deaths than any other country in the world. Effective modeling of the course of the pandemic can help assist with public health resource planning, intervention efforts, and vaccine clinical trials. However, building applied forecasting models presents unique challenges during a pandemic. First, case data available to models in real time represent a nonstationary fraction of the true case incidence due to changes in available diagnostic tests and test-seeking behavior. Second, interventions varied across time and geography leading to large changes in transmissibility over the course of the pandemic. We propose a mechanistic Bayesian model that builds upon the classic compartmental susceptible–exposed–infected–recovered (SEIR) model to operationalize COVID-19 forecasting in real time. This framework includes nonparametric modeling of varying transmission rates, nonparametric modeling of case and death discrepancies due to testing and reporting issues, and a joint observation likelihood on new case counts and new deaths; it is implemented in a probabilistic programming language to automate the use of Bayesian reasoning for quantifying uncertainty in probabilistic forecasts. The model has been used to submit forecasts to the U.S. Centers for Disease Control through the COVID-19 Forecast Hub under the name MechBayes. We examine the performance relative to a baseline model as well as alternate models submitted to the forecast hub. Additionally, we include an ablation test of our extensions to the classic SEIR model. We demonstrate a significant gain in both point and probabilistic forecast scoring measures using MechBayes, when compared to a baseline model, and show that MechBayes ranks as one of the top two models out of nine which regularly submitted to the COVID-19 Forecast Hub for the duration of the pandemic, trailing only the COVID-19 Forecast Hub ensemble model of which which MechBayes is a part.

查看原文本刊更多论文

COVID-19死亡率的实时机制贝叶斯预测

COVID-19大流行于2019年12月下旬出现。在全球疫情爆发的前六个月，美国报告的病例和死亡人数比世界上任何其他国家都多。对大流行过程进行有效的建模有助于公共卫生资源规划、干预工作和疫苗临床试验。然而，在大流行期间，建立适用的预测模型提出了独特的挑战。首先，由于可用诊断测试和寻求测试行为的变化，模型实时获得的病例数据代表了真实病例发病率的非平稳部分。第二，干预措施因时间和地域而异，导致大流行期间传播能力发生巨大变化。我们提出了一种机制贝叶斯模型，该模型建立在经典的区隔易感-暴露-感染-恢复(SEIR)模型的基础上，以实现COVID-19的实时预测。该框架包括对不同传播率的非参数建模，对由于检测和报告问题造成的病例和死亡差异的非参数建模，以及对新病例数和新死亡的联合观察可能性;它是用概率编程语言实现的，以自动使用贝叶斯推理来量化概率预测中的不确定性。该模型已被用于通过名为MechBayes的COVID-19预测中心向美国疾病控制中心提交预测。我们检查了相对于基线模型以及提交给预测中心的备用模型的性能。此外，我们还对经典SEIR模型的扩展进行了消融测试。我们证明，与基线模型相比，使用MechBayes的点和概率预测评分指标都有显著提高，并表明在大流行期间定期向COVID-19预测中心提交的9个模型中，MechBayes是排名前两位的模型之一，仅次于MechBayes所在的COVID-19预测中心集成模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

The Annals of Applied Statistics

自引率

0.00%

发文量