Bayesian inference across multiple models suggests a strong increase in lethality of COVID-19 in late 2020 in the UK

Pietzonka, Patrick; Brorson, Erik; Bankes, William; Cates, Michael E.; Jack, Robert L.; Adhikari, R.

doi:10.1101/2021.03.10.21253311

Cited by 4 publications

(7 citation statements)

References 14 publications

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“…Our estimates are based on data from 2020, some of which were obtained more than a year ago (see dates listed in Table 1). It is likely that, with continual viral mutation of SARS-CoV-2 and advances in treatment, the current IFR in many places is now markedly different than it was earlier, and our estimates are therefore likely to be outdated (Pei et al, 2021, Pietzonka et al, 2021, Walensky et al, 2021). In particular, at the present time, India is experiencing a rapid increase in COVID-19 fatalities which suggests that the current IFR in India may be much higher now than during earlier phases of the pandemic (Padma, 2021, Thiagarajan, 2021).…”

Section: Discussionmentioning

confidence: 89%

Inferring the COVID-19 infection fatality rate in the community-dwelling population: a simple Bayesian evidence synthesis of seroprevalence study data and imprecise mortality data

Campbell

Gustafson

2021

Preprint

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Estimating the COVID-19 infection fatality rate (IFR) has proven to be particularly challenging --and rather controversial-- due to the fact that both the data on deaths and the data on the number of individuals infected are subject to many different biases. We consider a Bayesian evidence synthesis approach which, while simple enough for researchers to understand and use, accounts for many important sources of uncertainty inherent in both the seroprevalence and mortality data. We estimate the COVID-19 IFR to be 0.38% (95% prediction interval of (0.03%, 1.19%)) for a typical population where the proportion of those aged over 65 years old is 9% (the approximate worldwide value). Our results suggest that, despite immense efforts made to better understand the COVID-19 IFR, there remains a large amount of uncertainty and unexplained heterogeneity surrounding this important statistic.

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Section: Discussionmentioning

confidence: 89%

Inferring the COVID-19 infection fatality rate in the community-dwelling population: a simple Bayesian evidence synthesis of seroprevalence study data and imprecise mortality data

Campbell

Gustafson

2021

Preprint

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“…Given the modelling assumptions ( particularly the well-mixed assumption, without over-dispersion), this result shows that the method has promise. Further work on more detailed and accurate models [40] will provide new and stringent tests of its applicability. Data accessibility.…”

Section: Methodology: Strengths and Weaknessesmentioning

confidence: 99%

“…Other classes may be either infectious or non-infectious: the canonical example is an SIR model which corresponds to L = 3, in which case the recovered (R) class is non-infectious. The analysis presented here is straightforwardly generalized to more complex compartment models, as might be used (for example) to model different pathogen strains, or vaccinated individuals with reduced susceptibility, or testing and quarantining [ 40 ].…”

Section: Compartment Modelsmentioning

confidence: 99%

“…It is likely that fits of similar quality could be achieved by a model with significantly fewer parameters; the dependence of parameters on age is also not very strong, so the number of age cohorts might also be reduced without much loss of accuracy. However, one purpose of this example is to test the capacity of the approach to handle models of this complexity, with a view to future work with (for example) compartments for quarantined/vaccinated individuals [ 40 ] and/or multiple variants of the virus. In this example, the inference computations are within the capability of desktop workstations, although long runs were required for MCMC and evidence computations, see below for details.…”

Section: Covid-19 In England and Wales: Modelmentioning

confidence: 99%

“…The intended future applications of these methods are to similar (population-level) models with higher complexity, e.g. [ 40 ].…”

Section: Introductionmentioning

confidence: 99%

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Efficient Bayesian inference of fully stochastic epidemiological models with applications to COVID-19

Turk

Rohrbach

et al. 2021

R. Soc. open sci.

Self Cite

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Epidemiological forecasts are beset by uncertainties about the underlying epidemiological processes, and the surveillance process through which data are acquired. We present a Bayesian inference methodology that quantifies these uncertainties, for epidemics that are modelled by (possibly) non-stationary, continuous-time, Markov population processes. The efficiency of the method derives from a functional central limit theorem approximation of the likelihood, valid for large populations. We demonstrate the methodology by analysing the early stages of the COVID-19 pandemic in the UK, based on age-structured data for the number of deaths. This includes maximum a posteriori estimates, Markov chain Monte Carlo sampling of the posterior, computation of the model evidence, and the determination of parameter sensitivities via the Fisher information matrix. Our methodology is implemented in PyRoss, an open-source platform for analysis of epidemiological compartment models.

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Inferring the COVID-19 infection fatality rate in the community-dwelling population: a simple Bayesian evidence synthesis of seroprevalence study data and imprecise mortality data

Campbell

Gustafson

2021

Epidemiol. Infect.

View full text Add to dashboard Cite

Estimating the coronavirus disease-2019 (COVID-19) infection fatality rate (IFR) has proven to be particularly challenging –and rather controversial– due to the fact that both the data on deaths and the data on the number of individuals infected are subject to many different biases. We consider a Bayesian evidence synthesis approach which, while simple enough for researchers to understand and use, accounts for many important sources of uncertainty inherent in both the seroprevalence and mortality data. With the understanding that the results of one's evidence synthesis analysis may be largely driven by which studies are included and which are excluded, we conduct two separate parallel analyses based on two lists of eligible studies obtained from two different research teams. The results from both analyses are rather similar. With the first analysis, we estimate the COVID-19 IFR to be 0.31% [95% credible interval (CrI) of (0.16%, 0.53%)] for a typical community-dwelling population where 9% of the population is aged over 65 years and where the gross-domestic-product at purchasing-power-parity (GDP at PPP) per capita is $17.8k (the approximate worldwide average). With the second analysis, we obtain 0.32% [95% CrI of (0.19%, 0.47%)]. Our results suggest that, as one might expect, lower IFRs are associated with younger populations (and may also be associated with wealthier populations). For a typical community-dwelling population with the age and wealth of the United States we obtain IFR estimates of 0.43% and 0.41%; and with the age and wealth of the European Union, we obtain IFR estimates of 0.67% and 0.51%.

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Bayesian inference across multiple models suggests a strong increase in lethality of COVID-19 in late 2020 in the UK

Cited by 4 publications

References 14 publications

Inferring the COVID-19 infection fatality rate in the community-dwelling population: a simple Bayesian evidence synthesis of seroprevalence study data and imprecise mortality data

Inferring the COVID-19 infection fatality rate in the community-dwelling population: a simple Bayesian evidence synthesis of seroprevalence study data and imprecise mortality data

Efficient Bayesian inference of fully stochastic epidemiological models with applications to COVID-19

Inferring the COVID-19 infection fatality rate in the community-dwelling population: a simple Bayesian evidence synthesis of seroprevalence study data and imprecise mortality data

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