Forecasting Hospitalizations Due to COVID-19 in South Dakota, USA.

IF 5.9 Q1 Computer Science

Journal of Healthcare Informatics Research Pub Date : 2021-01-01 Epub Date: 2021-05-01 DOI:10.1007/s41666-021-00094-8

Jeff S Wesner, Dan Van Peursem, José D Flores, Yuhlong Lio, Chelsea A Wesner

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引用次数: 0

Abstract

Anticipating the number of hospital beds needed for patients with COVID-19 remains a challenge. Early efforts to predict hospital bed needs focused on deriving predictions from SIR models, largely at the level of countries, provinces, or states. In the USA, these models rely on data reported by state health agencies. However, predicting disease and hospitalization dynamics at the state level is complicated by geographic variation in disease parameters. In addition, it is difficult to make forecasts early in a pandemic due to minimal data. Bayesian approaches that allow models to be specified with informed prior information from areas that have already completed a disease curve can serve as prior estimates for areas that are beginning their curve. Here, a Bayesian non-linear regression (Weibull function) was used to forecast cumulative and active COVID-19 hospitalizations for SD, USA, based on data available up to 2020-07-22. As expected, early forecasts were dominated by prior information, which was derived from New York City. Importantly, hospitalization trends differed within South Dakota due to early peaks in an urban area, followed by later peaks in rural areas of the state. Combining these trends led to altered forecasts with relevant policy implications.

Supplementary information: The online version contains supplementary material available at 10.1007/s41666-021-00094-8.

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预测美国南达科他州因 COVID-19 而住院的人数。

预测 COVID-19 患者所需的病床数量仍然是一项挑战。早期预测医院床位需求的工作主要集中在从 SIR 模型中得出预测结果，主要是在国家、省或州层面。在美国，这些模型依赖于州卫生机构报告的数据。然而，在州一级预测疾病和住院动态会因疾病参数的地域差异而变得复杂。此外，由于数据极少，很难在大流行早期做出预测。贝叶斯方法允许利用已完成疾病曲线的地区的知情先验信息来指定模型，可作为正在开始其曲线的地区的先验估计。在此，我们使用贝叶斯非线性回归（Weibull 函数），根据截至 2020-07-22 的可用数据，预测美国 SD 省 COVID-19 的累积和活动住院人数。不出所料，早期预测受到先验信息的影响，而先验信息来自纽约市。重要的是，南达科他州内的住院趋势各不相同，早期高峰出现在城市地区，后期高峰则出现在该州的农村地区。综合这些趋势，我们得出了具有相关政策影响的预测结果：在线版本包含补充材料，可查阅 10.1007/s41666-021-00094-8。

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

Journal of Healthcare Informatics Research Computer Science-Computer Science Applications

CiteScore

13.60

自引率

1.70%

发文量

期刊介绍： Journal of Healthcare Informatics Research serves as a publication venue for the innovative technical contributions highlighting analytics, systems, and human factors research in healthcare informatics.Journal of Healthcare Informatics Research is concerned with the application of computer science principles, information science principles, information technology, and communication technology to address problems in healthcare, and everyday wellness. Journal of Healthcare Informatics Research highlights the most cutting-edge technical contributions in computing-oriented healthcare informatics. The journal covers three major tracks: (1) analytics—focuses on data analytics, knowledge discovery, predictive modeling; (2) systems—focuses on building healthcare informatics systems (e.g., architecture, framework, design, engineering, and application); (3) human factors—focuses on understanding users or context, interface design, health behavior, and user studies of healthcare informatics applications. Topics include but are not limited to: · healthcare software architecture, framework, design, and engineering;· electronic health records· medical data mining· predictive modeling· medical information retrieval· medical natural language processing· healthcare information systems· smart health and connected health· social media analytics· mobile healthcare· medical signal processing· human factors in healthcare· usability studies in healthcare· user-interface design for medical devices and healthcare software· health service delivery· health games· security and privacy in healthcare· medical recommender system· healthcare workflow management· disease profiling and personalized treatment· visualization of medical data· intelligent medical devices and sensors· RFID solutions for healthcare· healthcare decision analytics and support systems· epidemiological surveillance systems and intervention modeling· consumer and clinician health information needs, seeking, sharing, and use· semantic Web, linked data, and ontology· collaboration technologies for healthcare· assistive and adaptive ubiquitous computing technologies· statistics and quality of medical data· healthcare delivery in developing countries· health systems modeling and simulation· computer-aided diagnosis