Identifying the relationship between imported cases and case rates

Since 15 February 2021, the UK has implemented a policy of testing all inbound travellers for COVID-19 within 48 h of arrival to the UK, and then again 8 days after arrival. Data regarding the travellers' origin country, and destination postcode are also recorded. The analysis presented in this paper aims to explore the relationship between importation rates and COVID-19 case rates for LTLA in England.

We are primarily concerned with COVID-19 importations from India; however, we also compare these with the aggregated importations from all countries. Importations are limited to those occurring over the 6-week period between 1 March and 12 May 2021. We account for population effects by considering each LTLA's importation rate – calculated as the number of importations per 10 000 population.

COVID-19 case rates in each LTLA are calculated from confirmed cases [Reference Clare9], and are again given as a rate per 10 000 population. We only consider cases which were initially identified through polymerase chain reaction (PCR) testing; rather than either lateral flow device (LFD) testing, or LFD testing with confirmatory PCR. This somewhat mitigates the effects of surge testing, as well as testing within schools and businesses.

We also provide the analysis on a finer geographic scale by investigating the importation rate and case rate per 1000 population of each Middle Super Output Area (MSOA) in nine LTLAs. These LTLAs have been selected due to having either >30 cases per 10 000 population and non-zero imported positive cases, or with >2 imported positive cases per 10 000 population.

Validating importation rates

A reasonable concern one might have with this analysis is that it offers no way of knowing whether the observed importation rates to Bolton were accurate. To address this, we must show that Bolton had as many importations as we might expect, given its economic, demographic and geographic characteristics.

To do this, we use an artificial neural network trained on demographic data at MSOA level. The model uses 161 explanatory variables, covering age distributions, countries of birth, economic activity, ethnicity, household structures, living arrangements, socio-economic classification and religion; all taken from 2011 census data. This was supplemented with more recent data at LTLA level covering 2019 estimates for religion and ethnicity. Geographic location was also included in the model, encoded as the latitude and longitude of each MSOA's population weighted centroid. All variables were scaled such that they have mean of zero and standard deviation of one before being passed into the model. We use Principle Component Analysis to reduce the dimensionality of the model from 161 to 35 explanatory variables, while retaining 95% of the data's variance.

The data were split into training and testing sets, with 79.5% of LTLAs (252/317) being used for training data. Bolton was placed in the testing set to ensure reliable validation, otherwise LTLAs were randomly allocated as testing or training data. The 252 LTLAs making up the training set comprised of 5517 individual MSOAs, with the testing set consisting of a further 1274 MSOAs, giving a true training split of 81.2%. A further 20% of the training data (1104 MSOAs) were used to validate the model during training, helping to avoid model overfitting.

The model architecture is described in Section S1 in the Supplementary Material. The model was built in Python (v3.9) using the Keras (v2.3.1) machine learning package. The results of the Neural Network model were checked against a second analysis using a Gradient Boosting Regression model trained on identical input data. The Gradient Boosting Regression model was built using the Sci-Kit Learn package (v0.23.1) for Python. Details of this model are also given in the Supplementary Materials.

Transmission modelling

The method described in section ‘Identifying the relationship between imported cases and case rates’ provides a quick and effective way of identifying the relationship between imported cases and COVID-19 case rates. However, it does not provide any indication of whether importations were sufficient in explaining the ongoing transmission seen in a number of LTLAs. In order to better understand this we must demonstrate a causative link between importations and case rates.

We employ an SEIR transmission model, fitted to LTLA case data, to identify this causative link. The model, described in equations 1–8, uses multiple compartments for the exposed population (E ₀, E ₁, E ₂), simulating the Erlang distributed incubation periods observed in the literature [Reference Pellis10, Reference Stage11]. Further, we separate the infectious (I ₀) compartments into those cases that are detected by COVID-19 surveillance streams (I _d) and those that remain undetected (I _u) [Reference Stage11]. We assume that detected infectious individuals undergo self-quarantine, reducing their transmission rate by a factor ν [12]. The Removed compartment (R) comprises of recovered individuals and fatalities.

The vaccination programme is modelled as taking individuals from the susceptible (S) to the removed (R) compartments at a constant rate, calculated as the mean daily vaccinations over the period. This assumption agrees with observations which suggest that the vaccination rate in the UK was broadly constant between January and May 2021 [1]. We have made no attempt to account for differences between first and second doses of the vaccine, and assume all vaccines are 80% effective [Reference Voysey13–15].

The model is described by the following system of Ordinary Differential Equations:

(1)$$\displaystyle{{dS} \over {dt}} = {-}\beta S\left({\displaystyle{{I_0 + I_u + \nu I_d} \over {N_0}}} \right)-\phi \displaystyle{S \over {N_0}}$$

(2)$$\displaystyle{{dE_0} \over {dt}} = \beta S\left({\displaystyle{{I_0 + I_u + \nu I_d} \over {N_0}}} \right)\;-\;3\alpha E_0$$

(3)$$\displaystyle{{dE_1} \over {dt}} = 3\alpha ( {E_0-E_1} ) $$

(4)$$\displaystyle{{dE_2} \over {dt}} = 3\alpha ( {E_1-E_2} ) $$

(5)$$\displaystyle{{dI_0} \over {dt}} = 3\alpha E_2-\gamma I_0$$

(6)$$\displaystyle{{dI_d} \over {dt}} = k\gamma I_0-\delta _dI_{d\;} + {\rm \Delta }( t ) $$

(7)$$\displaystyle{{dI_u} \over {dt}} = ( {1-k} ) \gamma I_0-\delta _uI_0 + \displaystyle{1 \over {10}}{\rm \Delta }( t ) $$

(8)$$\displaystyle{{dR} \over {dt}} = \delta _dId + \delta _uIu + \phi \displaystyle{S \over {N_0}}$$

We use Approximate Bayesian Computation (ABC) to parameterise the model, based on observations of case numbers in each LTLA between 10 January and 1 April 2021. The fitting process uses a negative binomial loss function – a common choice when dealing with over-dispersed epidemiological data [Reference Frasso and Lambert16, Reference Angelov and Slavtchova-Bojkova17]. A list of the model parameters and initial values is provided in Tables S1 and S2 in the Supplementary Materials. The ABC fitting process provides 1000 posterior parameterisations for each LTLA. Model development and ABC fitting was completed using the PyGOM package for Python.

All model parameters are fitted using ABC, with the exception of vaccine efficacy ϕ = 0.8 [Reference Voysey13–15], self-isolation rate ν = 0.1 [12] and latency rate α = 0.196 days-1 [Reference Pellis10, Reference Stage11]. The initial values of each state are also identified via ABC, except for I _d(0) = T _cy(0); where T _c is the mean generation time for COVID-19, taken to be T _c = 9 days [Reference Byrne18], and y(0) is the first value in the case data. Sensitivity of the results across ϕ ∈ {0.4, 0.6, 0.9}, ν ∈ {0.05, 0.2, 0.5} and T _c ∈ {3, 6, 12, 15} is shown in Tables S1–S3 in the Supplementary Materials.

The model is run twice for each LTLA. The first run uses the training data to estimate the continued trajectory of cases in the absence of any imported cases. In the second run, we introduce imported positive cases to the model after the fitting period. In order to model cases which are not captured by border screening, estimated to be around 10% of cases [Reference Bays, Bennett and Finnie19], we introduce imported cases to both the I _d and I _ucompartments. On day t, we introduce Δ(t) cases to I _d, and a further 0.1Δ(t) to I _u.

We use two metrics to assess the accuracy of the projections. First, we assess the broad accuracy by considering the root mean squared error (RMSE) between the log-transformed observed and predicted cases. Secondly, we also consider how well the model captures the observed growth rate in cases after the fit period. Growth rates are obtained by fitting a generalised linear model with a negative binomial link function to the log-transformed case data and projections – the coefficient of this model gives us an estimate for growth rate.