An SEIR Infectious Disease Model with Testing and Conditional Quarantine

We propose an additional intervention that would contribute to the control of the COVID-19 pandemic, offer more protection for people working in essential jobs, and help guide an eventual reopening of society. The intervention is based on: (1) testing every individual (2) repeatedly, and (3) isolation of infected individuals. We show here that at a sufficient rate of testing and isolation, the R0 of SARS-CoV-2 would be reduced well below 1.0, and the epidemic would collapse. The approach does not rely on strong and/or unrealistic assumptions about test accuracy, compliance to isolation, population structure or epidemiological parameters, and its success can be monitored in real time by measuring the change of the test positivity rate over time. In addition to the rate of compliance and false negatives, the required rate of testing is dependent on the design of the testing regime, with concurrent testing outperforming random sampling of individuals. Provided that results are reported rapidly, the test frequency required to suppress an epidemic is linear with respect to R0, to the infectious period, and to the fraction of susceptible individuals. Importantly, the testing regime would be effective at any level of prevalence, and additive to other interventions such as contact tracing and social distancing. It would also be robust to failure, as even in the case where the testing rate would be insufficient to collapse the epidemic, it would still reduce the number of infected individuals in the population, improving both public health and economic conditions. A mass-produced, disposable antigen or RNA test that could be used at home would be ideal, due to the optimal performance of concurrent tests that return immediate results.The ongoing pandemic spread of SARS-CoV-2 is the cause of widespread and accelerating outbreaks of the respiratory syndrome COVID-19. As of May 17, 2020, a total of 4 525 497 persons have been confirmed to be infected, and 307 395 have died 1 . Currently, the virus is present on all continents, spreading rapidly in Europe and the USA, and is a major threat to world order. It now seems likely that unemployment in most countries will exceed the levels reached during the depth of the Great Depression of the 1930s. Detailed models of the epidemic dynamics of SARS-CoV-2 are available that take into account population structure, and can provide estimates of the magnitude and duration of the peak of infection 2 . However, very broadly speaking, an outbreak of a novel virus in a naïve population can have only two outcomes. As long as the reproduction number R0 remains greater than 1, the virus spreads rapidly until most people have been infected (Fig. 1A), creating a temporary surge of infected individuals. If, using pharmaceutical or social interventions, R0 can be reduced below 1, then the epidemic collapses (Fig. 1B), and most people remain uninfected (but still susceptible). Because of the exponential nature of epidemics, the outcomes are nearly binary. Even when R0 exceeds one by only a small amo...

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“…26), and the other by a team consisting of David Berger, Kyle Hirkenhoff and Simon Mongey that report similar conclusions (Ref. 27).…”

Section: Acknowledgmentsmentioning

confidence: 69%

Population-scale testing can suppress the spread of COVID-19

Taipale

Romer

Linnarsson

2020

Preprint

100

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“…We assume that the free beds are rationed proportionally across groups. 2 Then, σ k is endogenously determined from the lethality rateσ k of patients with a severe infection who have access to ICU care as follows,…”

Section: The Modelsmentioning

confidence: 99%

“…All individuals from E tr k enter compartments Q when they become infectious while all individuals from E nt k enter compartments I. 2 A different rationing mechanism might be interesting to look at if one is interested in the age structure of the dead or if one wants to analyze the effect of different triage mechanisms that imply preferential treatment, e.g., for young people. Those extensions are easily possible by modifying of Equation (3).…”

Section: The Modelsmentioning

confidence: 99%

Extensions of the SEIR Model for the Analysis of Tailored Social Distancing and Tracing Approaches to Cope with COVID-19

Grimm

Mengel

Schmidt

2020

Preprint

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In the context of the COVID-19 pandemic, governments worldwide face the challenge of designing tailored measures of epidemic control to provide reliable health protection while allowing more societal and economic activity. In this paper, we propose an extension of the epidemiological SEIR model to enable a detailed analysis of commonly discussed tailored measures of epidemic control-among them group-specific protection and the use of tracing apps. We introduce groups into the SEIR model that may differ both, in their underlying parameters as well as in their behavioral response to public health interventions. We allow for different infectiousness parameters within and across groups, different asymptomatic, hospitalization, and lethality rates, as well as different take-up rates of tracing apps. Our results visualize the sharp trade-offs between different goals of epidemic control, namely a low death toll, avoiding overload of the health system, and a short duration of the epidemic. We show that a combination of tailored mechanisms, e.g., the protection of vulnerable groups together with a "trace & isolate" approach, can be effective in preventing a high death toll. Protection of vulnerable groups without further measures requires unrealistically strict isolation. A key insight is that high compliance is critical for the effectiveness of a "trace & isolate" approach. Our model allows to analyze the interplay of group-specific social distancing and tracing also beyond our case study in scenarios with a large number of groups reflecting, e.g., sectoral, regional, or age differentiation and group-specific take-up rates for tracing apps.

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“…Consequently, on the basis of eq. ( 3 ), the parameter of SIR model can be estimated as the number of new registered cases of infection to number of active cases ratio: ( 4 ) where is the rate of new infected cases ( 5 ) which can be estimated by counting new cases of infection, and usually is measured by number of registered new cases per time period ( 6 ) The number of daily new infected cases is defined as ( 7 ) So, expected number of new cases in next day could be predicted by the today number of active infected individuals multiplied by the infectious rate ( 8 ) In general, the infectious rate is time dependent and usually can be described by a complex function with additional parameters that must be daily calibrated according to last epidemiological data. Behaviour of the infectious rate during quarantine may differ in different countries, which reduces possibilities to build correct model of the infectious rate on the basis of epidemiological data from other countries.…”

Section: Simplified Model Of Epidemic Dynamics Under Quarantinementioning

confidence: 99%

“…Most popular epidemic dynamics models of Covid-19 are based on transmission model for a directly transmitted infectious disease, such as standard compartment models of disease SIR [5,6], or more advances derivates, such as SEIR and similar models [7][8][9][10]. Many of the models, which are used to forecast the COVID-19 epidemic, do not accurately capture the transient dynamics of epidemics; therefore, they give poor predictions of both the epidemic's peak and its duration [11], because calibration of parameters are based on dynamics of such non-reliable epidemiological data as number of active infectious cases.…”

Section: Introductionmentioning

confidence: 99%

Simplified model of Covid-19 epidemic prognosis under quarantine and estimation of quarantine effectiveness

Džiugys

Skarbalius

Misiulis

et al. 2020

Preprint

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A simplified model of Covid-19 epidemic dynamics under quarantine conditions and method to estimate quarantine effectiveness are developed. The model is based on the growth rate of new infections when total number of infections is significantly smaller than population size of infected country or region. The model is developed on the basis of collected epidemiological data of Covid19 pandemic, which shows that the growth rate of new infections has tendency to decrease linearly when the quarantine is imposed in a country (or a region) until it reaches constant value, which corresponds to the effectiveness of quarantine measures taken in the country. The growth rate of new infections can be used as criteria to estimate quarantine effectiveness.

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An SEIR Infectious Disease Model with Testing and Conditional Quarantine

Cited by 209 publications

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Population-scale testing can suppress the spread of COVID-19

Population-scale testing can suppress the spread of COVID-19

Extensions of the SEIR Model for the Analysis of Tailored Social Distancing and Tracing Approaches to Cope with COVID-19

Simplified model of Covid-19 epidemic prognosis under quarantine and estimation of quarantine effectiveness

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