Development of the reproduction number from coronavirus SARS-CoV-2 case data in Germany and implications for political measures

Khailaie, Sahamoddin; Mitra, Tanmay; Bandyopadhyay, Arnab; Schips, Marta; Mascheroni, Pietro; Vanella, Patrizio; Lange, Berit; Binder, Sebastian C.; Meyer‐Hermann, Michael

doi:10.1186/s12916-020-01884-4

Cited by 66 publications

(47 citation statements)

References 52 publications

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“…The estimated reproduction number R(t) oscillates around a value of 1 and illustrates the effect of describing the politics' countermeasures and the population's (e) 7-day incidence compliance to them (Figure 2, Panel (d)). This is in line with several publications [9], [19], [20] reporting similar behavior of the reproduction number. In general, oscillations in dynamical systems often are attributed to a feedback with delay, which is also the case here for the reproduction number R(t).…”

Section: Covid-19 Spread In Germanysupporting

confidence: 93%

Data-Driven Prediction of COVID-19 Cases in Germany for Decision Making

Lorenz

Riedlinger

Taubenböck

et al. 2021

Preprint

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BackgroundThe COVID-19 pandemic has led to a high interest in mathematical models describing and predicting the diverse aspects and implications of the virus outbreak. Model results represent an important part of the information base for the decision process on different administrative levels. The Robert-Koch-Institute (RKI) initiated a project whose main goal is to predict COVID-19-specific occupation of beds in intensive care units: Steuerungs-Prognose von Intensivmedizinischen COVID-19 Kapazitäten (SPoCK). The incidence of COVID-19 cases is a crucial predictor for this occupation.MethodsWe developed a model based on ordinary differential equations for the COVID-19 spread with a time-dependent infection rate described by a spline. Furthermore, the model explicitly accounts for weekday-specific reporting and adjusts for reporting delay. The model is calibrated in a purely data-driven manner by a maximum likelihood approach. Uncertainties are evaluated using the profile likelihood method. The uncertainty about the appropriate modeling assumptions can be accounted for by including and merging results of different modelling approaches.ResultsThe model is calibrated based on incident cases on a daily basis and provides daily predictions of incident COVID-19 cases for the upcoming three weeks including uncertainty estimates for Germany and its subregions. Derived quantities such as cumulative counts and 7-day incidences with corresponding uncertainties can be computed. The estimation of the time-dependent infection rate leads to an estimated reproduction factor that is oscillating around one. Data-driven estimation of the dark figure purely from incident cases is not feasible.ConclusionsWe successfully implemented a procedure to forecast near future COVID-19 incidences for diverse subregions in Germany which are made available to various decision makers via an interactive web application. Results of the incidence modeling are also used as a predictor for forecasting the need of intensive care units.

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Section: Covid-19 Spread In Germanysupporting

confidence: 93%

Data-Driven Prediction of COVID-19 Cases in Germany for Decision Making

Lorenz

Riedlinger

Taubenböck

et al. 2021

Preprint

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“…For each county, we use an age-resolved SIR-type model based on [8,11], with particular new focus on commuter testing. The model uses the compartments Susceptible (S i ); Exposed (E i ), who carry the virus but are not yet infectious to others; Carriers (C i ), who carry the virus and are infectious to others but do not yet show symptoms (they may be preor asymptomatic); Infected (I i ), who carry the virus, are infectious and show symptoms; Hospitalized (H i ), who experience a severe development of the disease; In Intensive Care Unit (U i ); Dead (D i ); and Recovered (R i ), who cannot be infected again.…”

Section: Mathematical Modelmentioning

confidence: 99%

“…The prediction of SARS-CoV-2 infections by mathematical models is an active area of research of many groups from all over the world. In particular for Germany, e.g., the authors of [5,6,7,8,9,10,11,12] have studied the effects of political interventions and provided predictions for the development of new cases. Spatial resolutions with a particular focus on networks and mobility was, among others, presented by the authors of [5,9,12,11].…”

Section: Introductionmentioning

confidence: 99%

Regional opening strategies with commuter testing and containment of new SARS-CoV-2 variants in Germany

Kuehn

Abele

Binder

et al. 2021

Preprint

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Background: Despite the accelerating vaccination process, a large majority of the population is still susceptible to SARS-CoV-2. In addition, we face the spread of novel variants. Until we overcome the pandemic, reasonable mitigation and opening strategies are crucial to balance public health and economic interests. Methods: We model the spread of SARS-CoV-2 over the German counties by a graph-SIR-type model with particular focus on commuter testing. We account for political interventions by varying contact reduction values in private and public locations such as homes, schools, workplaces, and other. We consider different levels of lockdown strictness, commuter testing strategies, or the delay of intervention implementation. We conduct numerical simulations to assess the effectiveness of the different intervention strategies after one month. The virus dynamics in the counties are initialized randomly with incidences between 75-150 weekly new cases per 100,000 inhabitants (red zones) or below 10 (green zones) and consider 25 different initial scenarios of randomly distributed red zones (between 2 and 20 % of all counties). To account for uncertainty, we consider an ensemble set of 500 Monte Carlo runs for each scenario. Results: We find that the strength of the lockdown in regions with out of control virus dynamics is most important to avoid the spread into neighboring regions. With very strict lockdowns in red zones, commuter testing rates of twice a week can substantially contribute to the safety of adjacent regions. In contrast, less strict lockdowns with the same commuter testing rate quickly and substantially lead to overall higher infection dynamics. A further key contributor is the potential delay of the intervention implementation. In order to keep the spread of the virus under control, strict regional lockdowns with minimum delay and commuter testing of at least twice a week are advisable.

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“…José Lourenço et al infer epidemiological parameters [40]. Khailaie et al analyze how changes in the reproduction number affect the epidemic dynamics [41]. Stutt et al evaluate the effectiveness of NPIs [42].…”

Section: Plos Onementioning

confidence: 99%

Heterogeneity matters: Contact structure and individual variation shape epidemic dynamics

2021

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In the recent COVID-19 pandemic, mathematical modeling constitutes an important tool to evaluate the prospective effectiveness of non-pharmaceutical interventions (NPIs) and to guide policy-making. Most research is, however, centered around characterizing the epidemic based on point estimates like the average infectiousness or the average number of contacts. In this work, we use stochastic simulations to investigate the consequences of a population’s heterogeneity regarding connectivity and individual viral load levels. Therefore, we translate a COVID-19 ODE model to a stochastic multi-agent system. We use contact networks to model complex interaction structures and a probabilistic infection rate to model individual viral load variation. We observe a large dependency of the dispersion and dynamical evolution on the population’s heterogeneity that is not adequately captured by point estimates, for instance, used in ODE models. In particular, models that assume the same clinical and transmission parameters may lead to different conclusions, depending on different types of heterogeneity in the population. For instance, the existence of hubs in the contact network leads to an initial increase of dispersion and the effective reproduction number, but to a lower herd immunity threshold (HIT) compared to homogeneous populations or a population where the heterogeneity stems solely from individual infectivity variations.

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Development of the reproduction number from coronavirus SARS-CoV-2 case data in Germany and implications for political measures

Cited by 66 publications

References 52 publications

Data-Driven Prediction of COVID-19 Cases in Germany for Decision Making

Data-Driven Prediction of COVID-19 Cases in Germany for Decision Making

Regional opening strategies with commuter testing and containment of new SARS-CoV-2 variants in Germany

Heterogeneity matters: Contact structure and individual variation shape epidemic dynamics

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