Forecasting Epidemics Through Nonparametric Estimation of Time-Dependent Transmission Rates Using the SEIR Model

Smirnova, Alexandra; DeCamp, Linda; Chowell, Gerardo

doi:10.1007/s11538-017-0284-3

Cited by 62 publications

(49 citation statements)

References 31 publications

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“…We employed an infectious disease dynamics model (SEIR model) for the purpose of modeling and predicting the number of COVID-19 cases in Wuhan, China. The model is a classic epidemic method to analyze the infectious disease, which has a definite latent period, and has proved to be predictive for a variety of acute infectious diseases in the past such as Ebola and SARS 22,[26][27][28][29][30][31] . Application of the mathematical model is of great guiding significance to assess the impact of isolation of symptomatic cases as well as observation of asymptomatic contact cases and to promote evidence-based decisions and policy.…”

Section: Modelmentioning

confidence: 99%

Phase-adjusted estimation of the number of Coronavirus Disease 2019 cases in Wuhan, China

et al. 2020

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An outbreak of clusters of viral pneumonia due to a novel coronavirus (2019-nCoV/SARS-CoV-2) happened in Wuhan, Hubei Province in China in December 2019. Since the outbreak, several groups reported estimated R 0 of Coronavirus Disease 2019 (COVID-19) and generated valuable prediction for the early phase of this outbreak. After implementation of strict prevention and control measures in China, new estimation is needed. An infectious disease dynamics SEIR (Susceptible, Exposed, Infectious, and Removed) model was applied to estimate the epidemic trend in Wuhan, China under two assumptions of R t . In the first assumption, R t was assumed to maintain over 1. The estimated number of infections would continue to increase throughout February without any indication of dropping with R t = 1.9, 2.6, or 3.1. The number of infections would reach 11,044, 70,258, and 227,989, respectively, by 29 February 2020. In the second assumption, R t was assumed to gradually decrease at different phases from high level of transmission (R t = 3.1, 2.6, and 1.9) to below 1 (R t = 0.9 or 0.5) owing to increasingly implemented public health intervention. Several phases were divided by the dates when various levels of prevention and control measures were taken in effect in Wuhan. The estimated number of infections would reach the peak in late February, which is 58,077-84,520 or 55,869-81,393. Whether or not the peak of the number of infections would occur in February 2020 may be an important index for evaluating the sufficiency of the current measures taken in China. Regardless of the occurrence of the peak, the currently strict measures in Wuhan should be continuously implemented and necessary strict public health measures should be applied in other locations in China with high number of COVID-19 cases, in order to reduce R t to an ideal level and control the infection.

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Section: Modelmentioning

confidence: 99%

Phase-adjusted estimation of the number of Coronavirus Disease 2019 cases in Wuhan, China

et al. 2020

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“…The model is a classic epidemic method to analyze the infectious disease which has a definite latent period, and has proved to be predictive for a variety of acute infectious diseases in the past such as Ebola and SARS. 22,[26][27][28][29][30][31] Application of the mathematical model is of great guiding significance to assess the impact of isolation of symptomatic cases as well as observation of asymptomatic contact cases and to promote evidence-based decisions and policy.…”

Section: Modelmentioning

confidence: 99%

Phase-adjusted estimation of the number of Coronavirus Disease 2019 cases in Wuhan, China

Wang

Dong

et al. 2020

Preprint

164

223

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“…The classic SEIR epidemiological model has been employed in a number of prior studies, such as the SARS outbreak Fang et al (2006); Saito et al (2013); Smirnova et al (2019) as well as the Covid outbreak Read et al (2020); Tang et al (2020); Wu & Leung (2020). The entire population is divided into four sub-populations: susceptible S; exposed E; infected I; and recovered R. The sub-populations' evolution is governed by the following system of four coupled nonlinear ordinary differential equations (Smirnova et al 2019;Wang et al 2020)…”

Section: Model 1: Without Quarantine Controlmentioning

confidence: 99%

“…We leverage this model to analyze and compare the role of quarantine control policies employed in Wuhan, Italy, South Korea and USA, in controlling the virus effective reproduction number R t Read et al 2020;Tang et al 2020;Li et al 2020a;Wu & Leung 2020;Kucharski et al 2020;Ferguson et al 2020). In the original model, known as SEIR (Fang et al 2006;Saito et al 2013;Smirnova et al 2019), the population is divided into the susceptible S, exposed E, infected I and recovered R groups, and their relative growths and competition are represented as a set of coupled ordinary differential equations. The simpler SIR model does not account for the exposed population E. These models cannot capture the largescale effects of more granular interactions, such as the population's response to social distancing and quarantine policies.…”

Section: Introductionmentioning

confidence: 99%

Quantifying the effect of quarantine control in Covid-19 infectious spread using machine learning

Dandekar

Barbastathis

2020

Preprint

103

107

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Since the first recording of what we now call Covid-19 infection in Wuhan, Hubei province, China on Dec 31, 2019, the disease has spread worldwide and met with a wide variety of social distancing and quarantine policies. The effectiveness of these responses is notoriously difficult to quantify as individuals travel, violate policies deliberately or inadvertently, and infect others without themselves being detected. Moreover, the publicly available data on infection rates are themselves unreliable due to limited testing and even possibly under-reporting. In this paper, we attempt to interpret and extrapolate from publicly available data using a mixed first-principles epidemiological equations and data-driven neural network model. Leveraging our neural network augmented model, we focus our analysis on four locales: Wuhan, Italy, South Korea and the United States of America, and compare the role played by the quarantine and isolation measures in each of these countries in controlling the effective reproduction number Rt of the virus. Our results unequivocally indicate that the countries in which rapid government interventions and strict public health measures for quarantine and isolation were implemented were successful in halting the spread of infection and prevent it from exploding exponentially. In the case of Wuhan especially, where the available data were earliest available, we have been able to test the predicting ability of our model by training it from data in the January 24 till March 3 window, and then matching the predictions up to April 1. Even for Italy and South Korea, we have a buffer window of one week (25 March - 1 April) to validate the predictions of our model. In the case of the US, our model captures well the current infected curve growth and predicts a halting of infection spread by 20 April 2020. We further demonstrate that relaxing or reversing quarantine measures right now will lead to an exponential explosion in the infected case count, thus nullifying the role played by all measures implemented in the US since mid March 2020.

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Forecasting Epidemics Through Nonparametric Estimation of Time-Dependent Transmission Rates Using the SEIR Model

Cited by 62 publications

References 31 publications

Phase-adjusted estimation of the number of Coronavirus Disease 2019 cases in Wuhan, China

Phase-adjusted estimation of the number of Coronavirus Disease 2019 cases in Wuhan, China

Phase-adjusted estimation of the number of Coronavirus Disease 2019 cases in Wuhan, China

Quantifying the effect of quarantine control in Covid-19 infectious spread using machine learning

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