Outline of epidemiological models used to produce $ R $ values

Generating an $ R $ estimate requires a model of some kind with subjective assumptions and information from other sources. Our modelling ensemble comprised mathematical models that were developed, adapted, and used throughout 2020–2022, to model the COVID-19 epidemic in England; to generate epidemic metrics such as $ R $ , $ r $ , incidence, and prevalence; and to produce medium-term projections (MTPs) of hospital admissions, hospital bed occupancy, and deaths. The MTPs will be explored separately in a future publication. These models fall into three broad groups, as described in [Reference Georgakakos31] and [Reference Abbott2]: population-based models (PBMs), data-driven models (DDMs), and agent-based models (ABMs). The models in the ensemble can be split further into three broad categories based on the data they primarily used to inform their estimates: case-based models, admission-based models, and models that were fitted to both case data and hospital data. For the purposes of this study, models that were fitted to survey data are categorized as case-based models as they were focused on detecting the incidence of the disease, though there were differing delays associated with models that were fitted to cases and models that were fitted to survey data. There are drawbacks and advantages associated with fitting to either cases or admissions. Case data are highly sensitive to ascertainment biases. For example, an under-ascertainment of cases may be related to weekend/weekday periods, with people with milder symptoms over the weekend less likely to get confirmed than during the weekdays. The scale of these biases has varied greatly over time. Therefore, models that were fitted to case counts or positivity must be interpreted in the context of testing behaviours and policies at the time. However, admission data are not free from bias either, as they depend on input from physicians and other hospital staff, which means that weekend/weekday effects are likely. In addition, the likelihood of being admitted to the hospital varies greatly by age. Hence, without age stratification in the model, it is likely that community transmission is underestimated among younger age groups. Furthermore, the delay between being infected with COVID-19 and being admitted to the hospital is on average far greater than that between infection and receiving a positive test. This presented difficulties when trying to produce timely estimates of community transmission. Table 1 lists these models along with the type of data they were fitted to and whether or not they were run internally by either the UKHSA Epi-Ensemble or a Devolved Administration (DA) Department.

Table 1. The UKHSA/SPI-M-O models split by model type and the data to which they fit to

While these models can be broadly stratified into the PBM, DDM, and ABM groups, each model within the group has distinctive characteristics. For example, EpiEstim followed the methodology described in [Reference Gostic32] and therefore assumed a consistent relationship between infections and cases. The estimated $ R $ was therefore only robust when the ascertainment rate was roughly constant. While GenSur shared this same limitation, Epidemia and OxfordCSML did not make this assumption [33]. Furthermore, renewal equation-based models tend to be semi-mechanistic, that is assuming that the effects of interventions are absorbed into the data to which they fit. In contrast, fully mechanistic models, such as the susceptible–exposed–infected–recovered (SEIR) population-based models and ABMs, explicitly modelled the effects of interventions such as test–trace–isolate strategies and imposing and removing of social distancing measures.

In epidemiological models, the structure of the model determines the method to calculate $ R $ and depends on the assumptions and data sets used to parameterize and validate the model [Reference Green, Ferguson and Cori34].

In the classic compartmental SEIR model, $ {R}_0=\beta \ast c/\gamma $ _, where $ \beta $ is the transmission probability per contact, $ c $ is the number of contacts $ c $ _, and $ 1/\gamma $ is the infectiousness period (average time that an individual is infectious for). $ R $ is typically calculated from more complex (e.g. multi-group) SEIR models as the largest eigenvalue of the next-generation matrix (NGM), which can be expressed as $ {FV}^{-1} $ , where $ F $ represents infection rates and $ V $ represents recovery rates [Reference Hinch35, Reference James36]. $ R $ can also be estimated using the renewal equation [Reference Keeling37, Reference Kendall38]:

(2) $$ R(t)=\frac{E[I(t)]}{\int_0^{\mathrm{\infty}}f(\tau )I(t-\tau )d\tau}\hskip1em , $$

where $ I(t) $ is number of new infections (i.e. the incidence) at time $ t $ and $ E\left[\right] $ denotes the expected value.

Across the dynamical models that comprise sets of differential equations in our ensemble, such as the Manchester or University of Liverpool models, $ R $ was estimated by inferring the rate of transmission within the model, which was fitted to observed data on cases, hospitalizations, deaths, or their combination. Some more complex dynamical models, such as the one developed by Public Health England (PHE) and Cambridge or the Imperial one (sircovid), explicitly calculated R as the largest eigenvalue of the NGM.

There is also a difference in how R was estimated between compartmental and ABMs or individual-based models. In ABMs, such as Covasim, it is possible simply to count exactly how many secondary infections are caused by each primary infection at any stage of the epidemic and hence explicitly calculate $ R $ .

A third approach, and a characteristic of the data-driven models in our ensemble, used statistical models to estimate R empirically from the notification data. These methods made minimal structural assumptions about epidemic dynamics and only required users to specify the generation time distribution. A selection of models in this category in the ensemble was formulated based on Equation (1). For example, where the generation time distribution is described by a gamma distribution with shape $ a $ and rate $ b $ , $ R $ can be expressed in terms of the growth rate $ r $ as follows:

(3) $$ R=\frac{{\left(r+b\right)}^a}{b^a}, $$

A high-level description of the methods used to calculate $ R $ , along with an outline of the main characteristics of each model, is given in Table A1 in the Appendix.

Combining model estimates to generate a consensus $ R $

To generate combined $ R $ estimates from the ensemble of models, we used the statistical model developed as a collaboration between DSTL, the University of Southampton, and the University of Liverpool with the underlying methodology described in [Reference Brooks-Pollock10]. We present a high-level outline of the method below. Each of the epidemiological models described in Table A1 and calibrated to the data as outlined in Table 1 generated 5th, 25th, 50th, 75th, and 95th percentile estimates for $ R $ . Using these, a mean and a standard deviation for each model’s $ R $ estimate were generated. The mean of the $ {i}^{th} $ model, $ {y}_i $ , was initially estimated as the median (or $ {50}^{th} $ quantile), and the standard deviation was calculated as follows:

(4) $$ {s}_i=\frac{\max \left(|{q}_i(95)-{q}_i(50)|,|{q}_i(50)-{q}_i(5)|\right)}{z_{95}}, $$

where $ {q}_i(x) $ represented the $ {x}^{th} $ quantile of the $ {i}^{th} $ model and $ {z}_{95} $ is the z-score for the 90% confidence interval (CI) of the standard normal distribution. Where model estimates were highly skewed, a skewness correction calculation was applied to provide alternative estimates for the mean and the standard error (see [Reference Brooks-Pollock10] for further details). Otherwise, the distribution of the model estimates for $ R $ was assumed to be symmetric.

These estimates were then combined using a random-effects model, which allowed for differences in model structure and did not assume that models shared a common effect size. The random-effects statistical model was described as follows:

(5) $$ {y}_i=\mu +{\mu}_i+{\unicode{x025B}}_i,\hskip1em {\mu}_i\sim \mathcal{N}\left(0,{\tau}^2\right),\hskip1em {\unicode{x025B}}_i\sim \mathcal{N}\left(0,{v}_i\right), $$

where the estimated mean for model $ i $ is denoted by $ {y}_i $ and the standard error is denoted by $ {s}_i=\sqrt{v_i} $ . The model was fitted to provide estimates for $ \mu $ and $ \tau $ _, which are the mean and standard deviation of the true effect size, respectively. The between-model variance, $ {\tau}^2 $ , was estimated using the restricted maximum-likelihood method, and the CI of the mean true overall effect size is estimated using the standard Wald-type method. The models were equally weighted (see next section for more details) and the range of $ R $ was rounded out to one decimal place, by using the lower and upper bounds, respectively. Further details of other methods used for calculating the between group errors and CIs are provided in [Reference Kendall39].

Collaborating across government and academia to produce a consensus nowcast

The process of cross-academic and government collaboration to generate consensus $ R $ was done in several steps. Firstly, the outputs from the models detailed in Table A1 were submitted by the modellers to the UKHSA Epi-Ensemble team weekly. The team then combined the model estimates using CrystalCast to generate a combined estimate for $ R $ , $ r $ , incidence, and prevalence in England, the English regions and the DAs. The combined estimates, as well as individual model estimates, were discussed at a weekly meeting between the UKHSA Epi-Ensemble and SPI-M modellers, wider SPI-M-O members, and wider representatives from UKHSA and DAs. These meetings gave the modellers the chance to explain their outputs, discuss the model behaviour, and agree on the inclusion or exclusion of any specific models in the ensemble for that week. A model would only be excluded if there was a clear error in its outputs or if it displayed behaviour that could not be justified from an epidemiological perspective. Once a consensus was reached for each of the epidemic metrics, a recommendation was made to the EMRG, who then finally approved and published the consensus outputs.

Sensitivity analysis

Two sensitivity analyses explored the extent to which the combined $ R $ would have been impacted by the variable weighting of the models within the ensemble and the size of the ensemble. For consistency, no individual models were re-run for these analyses; we used only the original model results submitted at the time the consensus $ R $ was published. This was intentional so that the analysis would serve as a historic record of the combined estimates at the time.

$ R $ as an epidemic indicator

The $ R $ time series is a transform of epidemic metrics such as case incidence or hospitalizations. Hence, we expect it would be statistically correlated with the epidemic metrics, but quantifying the degree of correlation with different metrics is interesting.

We explored the correlation between the consensus $ R $ as published on the UK Government COVID-19 Dashboard and the key public data sources relating to the COVID-19 pandemic, namely cases, admissions, and deaths. We expect the $ R $ number to be correlated in some way to the rate of change of these three metrics, and we know this relationship is non-linear. Therefore, we used Spearman’s rank correlation coefficient, $ \rho $ .

In order to adjust for periodic weekly fluctuations (e.g. weekend/weekday differences in under-ascertainment), each source of data was transformed into a centred weekly moving average. For each date that an $ R $ number was calculated, the slope of the data was calculated over a centred weekly window. We used the same length and position of windows over which to perform the analysis in order to ensure consistency; otherwise, additional artificial lag would be introduced into the analysis.

The correlation between $ R $ and the weekly rate of change in cases, admissions, or deaths may have an inherent lag due to the fact that it takes time for more severe symptoms to develop. In order to investigate this, we explored how the correlation changed between the $ R $ number, shifted along its time axis by a varying number of days, and the rate of change of new hospital admissions and deaths. This was done by shifting the calculated values of $ R $ we used by 1–20 days and observing how $ \rho $ changed with an increasing shift size. Mathematically, we are calculating the following, where the variable $ X $ represents the centred weekly rolling average of either the recorded incidence of cases, hospital admissions, or deaths:

$$ {\rho}_{\mathcal{R}\left({R}_{t^{\prime }}\right),\mathcal{R}\left(\dot{X}\right)}=\frac{\mathrm{Cov}\left[\mathcal{R}\left({R}_{t^{\prime }}\right),\mathcal{R}\left(\dot{X}\right)\right]}{\sigma_{\mathcal{R}\left({R}_{t^{\prime }}\right),\mathcal{R}\left(\dot{X}\right)}}\hskip1em . $$

In the above, $ \mathcal{R}\left(\cdot \right) $ denotes the ordinal rank and $ {R}_{t^{\prime }} $ is the time-shifted $ R $ , equal to $ R\left(t-{t}_{\mathrm{shift}}\right) $ _, where $ {t}_{\mathrm{shift}}\in \left(1,20\right) $ . $ \dot{X} $ denotes the rate of change of variable $ X $ with respect to time, and all times considered are measured in days. We performed this calculation on data within specific time windows, which correspond to the Delta and Omicron waves, respectively, and shifted the time window for the published $ R $ value against the static recorded data. These time windows were 7 May 2021 to 30 July 2021 and 26 November 2021 to 25 February 2022 for the Delta and Omicron waves, respectively.