Spreading of COVID-19 in Brazil: Impacts and uncertainties in social distancing strategies

Volpatto, Diego; Resende, Anna Claudia M.; Anjos, Lucas dos; Silva, João Vitor Oliveira; Dias, Claudia Mazza; Almeida, Regina C.; Malta, Sandra M. C.

doi:10.1101/2020.05.30.20117283

Cited by 15 publications

(21 citation statements)

References 55 publications

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“…In order to understand the model response to noisy data, we adopt an extension of the compartmental SEIR model, termed SEIRPD-Q model, which encompasses concepts of the models proposed by Jia et al [26] and Vol-patto et al [27]. Initially, consider a population susceptible to a viral outbreak, whose rate of transmission per contact is given by β .…”

Section: Methodsmentioning

confidence: 99%

“… The model adopted presents some fundamental differences in relation to those on which we are based: first, Jia et al [26] consider that only susceptible individuals are subject to quarantine measures, which is modeled using an explicit compartment and also considering an additional parameter that controls the social distancing relaxation; second, we disregard the asymptomatic compartment due to the uncertainties regarding the reported data, and in-corporate the dynamics related to positively diagnosed individuals, of which data are more reliable (as proposed by Volpatto et al [27]); third, we consider only the mortality rate of positively diagnosed individuals, unlike Vol-patto et al [27]. Additionally, we also compute the cumulative number of infected and dead individuals, which are respectively given by These quantities are used in the estimation of the model parameters and the term cumulative number of infected individuals is often used interchangeably with confirmed cases throughout the text.…”

Section: Methodsmentioning

confidence: 99%

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Framework for enhancing the estimation of model parameters for data with a high level of uncertainty

Libotte

Anjos

Almeida

et al. 2020

Preprint

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Research on predictions related to the spread of the novel coronavirus are crucial in decision-making to mitigate the disease. Computational simulations are often used as a basis for forecasting the dynamics of epidemics and, for this purpose, compartmental models have been widely used to assess the situation resulting from the spread of the disease in the population. Reliable data is essential to obtain adequate simulations. However, several political, economic, and social factors have caused inconsistencies in the reported data, which are reflected in the capacity for realistic simulations and predictions. Such uncertainties are mainly motivated by a large-scale underreporting of cases due to the reduced testing capacity in some locations. In order to mitigate the effects of noise in the data used to estimate parameters of compartmental models, we propose strategies capable of improving the ability to predict the spread of the disease. We show that the regularization of data by means of Gaussian Process Regression can reduce the variability of successive forecasts, thus improving predictive ability. We also present the advantages of adopting parameters of compartmental models that vary over time, in detriment to the usual approach with constant values.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Framework for enhancing the estimation of model parameters for data with a high level of uncertainty

Libotte

Anjos

Almeida

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

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“…Finally, in case 4, the model was redefined for the second stage of the epidemy evolution in Brazil, through estimation of five parameters associated with new time-variable functions for the transmission rate and partition coefficient along this second phase. The statistical inversion approach here implemented falls within the Bayesian statistical framework [8][9][10][11][12], in which (probability distribution) models for the measurements and the unknowns are constructed separately and explicitly, as shall be briefly reviewed in what follows.…”

Section: The Backward Siru-type Modelmentioning

confidence: 99%

“…If the proposed jump is rejected, the current value is tally again. For more details on theoretical aspects of the Metropolis-Hastings algorithm and MCMC methods and its application, the reader should refer to References [8][9][10][11][12].…”

Section: The Backward Siru-type Modelmentioning

confidence: 99%

“…However, a Bayesian inference approach is here adopted for parametric estimations, complementing these analytical estimates obtained through the hypothesis of exponential growth in the early stage of the epidemy, before any public health intervention. Other recent contributions have successfully combined phenomenological deterministic compartmental models with Bayesian inference approaches for state estimation and parameter estimation [12][13][14][15][16]. For the present purposes, the Markov Chain Monte Carlo method with the Metropolis-Hastings sampling algorithm has been employed [17][18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

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Mathematical Parameters of the COVID-19 Epidemic in Brazil and Evaluation of the Impact of Different Public Health Measures

Cotta

Naveira-Cotta

Magal

2020

Biology

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A SIRU-type epidemic model is employed for the prediction of the COVID-19 epidemy evolution in Brazil, and analyze the influence of public health measures on simulating the control of this infectious disease. The proposed model allows for a time variable functional form of both the transmission rate and the fraction of asymptomatic infectious individuals that become reported symptomatic individuals, to reflect public health interventions, towards the epidemy control. An exponential analytical behavior for the accumulated reported cases evolution is assumed at the onset of the epidemy, for explicitly estimating initial conditions, while a Bayesian inference approach is adopted for the estimation of parameters by employing the direct problem model with the data from the first phase of the epidemy evolution, represented by the time series for the reported cases of infected individuals. The evolution of the COVID-19 epidemy in China is considered for validation purposes, by taking the first part of the dataset of accumulated reported infectious individuals to estimate the related parameters, and retaining the rest of the evolution data for direct comparison with the predicted results. Then, the available data on reported cases in Brazil from February 15th until March 29th, is used for estimating parameters and then predicting the first phase of the epidemy evolution from these initial conditions. The data for the reported cases in Brazil from March 30th until April 23rd are reserved for validation of the model. Then, public health interventions are simulated, aimed at evaluating the effects on the disease spreading, by acting on both the transmission rate and the fraction of the total number of the symptomatic infectious individuals, considering time variable exponential behaviors for these two parameters. This first constructed model provides fairly accurate predictions up to day 65 below 5% relative deviation, when the data starts detaching from the theoretical curve. From the simulated public health intervention measures through five different scenarios, it was observed that a combination of careful control of the social distancing relaxation and improved sanitary habits, together with more intensive testing for isolation of symptomatic cases, is essential to achieve the overall control of the disease and avoid a second more strict social distancing intervention. Finally, the full dataset available by the completion of the present work is employed in redefining the model to yield updated epidemy evolution estimates.

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Adaptive mesh refinement and coarsening for diffusion–reaction epidemiological models

Grave

Coutinho

2021

Comput Mech

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The outbreak of COVID-19 in 2020 has led to a surge in the interest in the mathematical modeling of infectious diseases. Disease transmission may be modeled as compartmental models, in which the population under study is divided into compartments and has assumptions about the nature and time rate of transfer from one compartment to another. Usually, they are composed of a system of ordinary differential equations in time. A class of such models considers the Susceptible, Exposed, Infected, Recovered, and Deceased populations, the SEIRD model. However, these models do not always account for the movement of individuals from one region to another. In this work, we extend the formulation of SEIRD compartmental models to diffusion–reaction systems of partial differential equations to capture the continuous spatio-temporal dynamics of COVID-19. Since the virus spread is not only through diffusion, we introduce a source term to the equation system, representing exposed people who return from travel. We also add the possibility of anisotropic non-homogeneous diffusion. We implement the whole model in libMesh, an open finite element library that provides a framework for multiphysics, considering adaptive mesh refinement and coarsening. Therefore, the model can represent several spatial scales, adapting the resolution to the disease dynamics. We verify our model with standard SEIRD models and show several examples highlighting the present model’s new capabilities.

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Spreading of COVID-19 in Brazil: Impacts and uncertainties in social distancing strategies

Cited by 15 publications

References 55 publications

Framework for enhancing the estimation of model parameters for data with a high level of uncertainty

Framework for enhancing the estimation of model parameters for data with a high level of uncertainty

Mathematical Parameters of the COVID-19 Epidemic in Brazil and Evaluation of the Impact of Different Public Health Measures

Adaptive mesh refinement and coarsening for diffusion–reaction epidemiological models

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