The reproduction number R for COVID-19 in England: Why hasn't ''lockdown'' been more effective?

The reproduction number R, the average number of people that a single individual with a contagious disease infects, is central to understanding the dynamics of the COVID-19 epidemic. Values greater than one correspond to increasing rates of infection, and values less than one indicate that control measures are being effective. Here, we summarise how changes in the behaviour of individuals alter the value of R. We also use matrix models that correctly recreate distributions of times that individuals spend incubating the disease and being infective to demonstrate the accuracy of a simple approximation to estimate R directly from time series of case numbers, hospital admissions or deaths. The largest uncertainty is that the generation time of the infection is not precisely known, but this challenge also affects most of the more complex methods of calculating R. We use this approximation to examine changes in R in response to the introduction of lockdown restrictions in England. This suggests that there was a substantial reduction in R before large scale compulsory restrictions on economic and social activity were imposed on 23rd March 2020. From mid-April to mid-June decline of the epidemic at national and regional level has been relatively slow, despite these restrictions (R values clustered around 0.81). However, these estimates of R are consistent with the relatively high average numbers of close contacts reported by confirmed cases combined with directly measured attack rates via close interactions. This implies that a significant portion of transmission is occurring in workplaces; overcrowded housing or through close contacts that are not currently lawful, routes on which nationwide lockdown will have limited impact.


Introduction
In many countries, the emergent COVID-19 epidemic has shown an initial phase of exponential growth (Huang, Yang, Dai, Tian, & Chen, 2020). Governments have responded to this with the introduction of a range of infection control measures, including extensive restriction of social and economic interactions, often referred to as "lockdown" (see Jarvis et al., 2020, for a more detailed discussion of the UK regulations). The effective reproduction number of the virus, R, is widely used as a measure of epidemic growth during the initial unrestricted growth phase, and as a measure of the effectiveness of infection control measures after these have been introduced. R > 1 indicates that case numbers are growing, while R < 1 indicates falling infection rates. A number of methods are available to estimate R from data, such as time series of infection rates, hospitalisation rates or deaths (e.g. Britton & Tomba, 2019;Chong, 2020;Cori, Ferguson, Fraser, & Cauchemez, 2013;Fraser, 2007;Ganyani et al., 2020; Government Office for Science, 2020; Wallinga & Lipsitch, 2007).
Some studies take into account population age structure and age-specific mortality rates and in some cases aggregate multiple data sources including deaths, antibody prevalence and information on contacts between individuals (Birrell et al., 2020). A number, but not all, of these calculations rely on compartment models such as SEIR (Belfin, Brodka, Radhakrishnan, & Rejula, 2020;K. Prem et al., 2020;Ridenhour, Kowalik, & Shay, 2014;J. H. Wu, Tang, Bragazzi, Nah, & McCarthy, 2020), which track numbers of susceptible, exposed, infective and recovering individuals. However, compartment models are known to give relatively poor predictions of epidemic dynamics as they do not correctly simulate the distribution of times between initial infection and either onset of symptoms or death (Grant, 2020). Although the meaning, and importance, of R is clear, this reliance on complex mathematical models makes it is difficult to understand the relationships between R and readily observable measures of the course of the epidemic, such as time series of infection rates, hospitalisation rates or deaths (Ridenhour et al., 2014). Here we present a simple model of the dynamics of COVID-19 infection that overcomes the problems in using compartment models to understand epidemic dynamics. We use this to demonstrate the accuracy of a simple approximation that allows R to be directly estimated from time series, then apply this to data on death and infection rates in England. We also outline the links between the behaviour of individuals and changes in the value of R, allowing us to examine whether our current understanding of behavioural responses to advice and regulation are consistent with the observed reductions in R.
How is the value of R linked to people's behaviour?
For an infection that is passed directly from one individual to another, R integrates the outcomes of all interactions that an individual has during the period that they are infectious. R is, therefore, dependent upon the period of time that an individual is infectious; the number of other individuals encountered per day; the probability of the disease being transmitted during an encounter and the proportion of the population that is susceptible to infection.

= 1
Where 1/σ is the duration of the infective period (expressed as a reciprocal to preserve standard notation used in compartment models); k is the average number of people encountered per day, p is the average probability of infection transmission at each encounter and S/N is the proportion of the population that is susceptible to infection. For a novel infective agent, the whole population is susceptible. S = N so S/N = 1, and R is then known as R 0. This calculation is phrased in terms of average transmission and encounter rates, whereas there will be variations between individuals in how many other people they encounter each day (c.f. Mossong et al., 2008) and variation between encounters in their closeness and duration. For example, Bi et al. (2020) found that attack rates between household members were more than ten times higher than for contacts with others, and there was a 32 fold difference of attack rates depending upon whether close contacts between individuals were "rare" or "often". The high rates of death in occupations such as security guards (ONS, 2020a) presumably reflects encounters with large numbers of people, with a rather low probability of transmission from each individual encounter. This formulation also assumes that the duration of the infective period and rates of transmission during this are constant, whereas many studies indicate that both of them vary (Britton & Tomba, 2019;Lauer et al., 2020). Transmission may be possible for some time before individuals become symptomatic , and symptomatic individuals may reduce their interactions with others through self-isolation. But the formula can be straightforwardly generalised to:

= �
Where ki and pi are daily encounter and infectivity rates, and the summation is over the whole infective period. The daily infectivity can take into account both variation in viral shedding over time and variations in the duration of the infective period. This formulation clearly displays how the spread of an epidemic can be controlled by reducing numbers of contacts between individuals (bringing down the value of k), as well as by reducing the probability on transmission, p, during each encounter by measures such as hand washing, avoiding skin contact, maintaining larger social distances than previously and self-isolation by individuals who are symptomatic.
Estimates of R 0 for COVID-19 mostly lie between 2 and 4, although some are above this range and in the confined conditions of the Diamond Princess cruise ship R 0 may have been as high as 14.8 (Belfin et al., 2020;Rocklöv, Sjödin, & Wilder-Smith, 2020). If infectivity remains constant then reductions in R will be proportional to reductions in the average number of contacts between individuals. In a 2008 study across 8 European countries, individuals reported a mean of 13.4 contacts per day, but data were right skewed with some reporting more than 50 contacts a day (Mossong et al., 2008). In the UK, a survey using similar methods carried out after the introduction of a requirement for people to stay at home, except in very restricted circumstances, found that numbers of contacts were 74% lower than the UK data in the 2008 study (reducing from 10.8 to 2.8). Skin to skin contacts were reduced even more (Jarvis et al., 2020). The authors estimated that these would correspond to a reduction in R from 2.6 before social distancing to 0.62 based on all contacts and 0.37 based on transmission via skin contact alone. The changes in behaviour may also have altered the value of p, as the proportion of contacts that occurred at home increased from 34% to 58%. The average probability of transmission from an infective individual to a single contact will have increased, but only because contacts with those from outside of the home, which have a lower individual transmission probability, have reduced. This will lead to reduced transmission between homes and, in time, mean that many of the contacts of infective individuals will be with the previously infected (and therefore immune) individuals in the same household from who they acquired the infection. In Wuhan and Shanghai, mean daily contacts decreased by 86-89% (Zhang et al., 2020) while Rothwell (2020) suggests that in the USA the reduction lies between 75 and 90%. These should result in a four to 10 fold reduction in R, without taking into account any additional effects due to social distancing or improved personal hygiene. However, gathering information on average numbers of contacts per individual may not capture a key element of transmission dynamics, which is that a small proportion of cases may lead to the infection of very large numbers of others as a result of them interacting with large numbers of others in areas of high population density (Rader et al., 2020)  . These models are straightforward to use, and can be readily parameterised using estimates of transmission rate and mean times to becoming symptomatic and recovering (or more correctly, mean time to becoming infective and mean duration of the infective period -see below for a more detailed discussion). However, as we have shown elsewhere (Grant, 2020), compartment models do not simulate realistic distributions of the times that individuals spend in each compartment. The most common time taken to incubate the disease or recover after showing symptoms is zero in a continuous time model or one time step in a discrete time model, but some individuals spend very much longer than the mean residence time in individual compartments.
As a result, the models make poor predictions of the dynamics of an epidemic (Krylova & Earn, 2013;Lloyd, 2001aLloyd, , 2001bWearing, Rohani, & Keeling, 2005). They under-estimate the growth of numbers of cases and numbers of deaths during the initial exponential growth phase of an epidemic such as COVID-19, but after transmission rates are reduced by the introduction of social distancing or a sufficient proportion of the population has had the disease to see infection rates reduced by "herd immunity", they over-estimate case numbers and the duration of epidemics. This also obscures the relationship between R and numbers of cases or numbers of deaths that we outline in the next section. Compartment models are, therefore, likely to be misleading if used to guide, or judge the effectiveness of, policy interventions to reduce the effects of an epidemic.
Time-since-infection models have some major theoretical advantages (see, e.g., Fraser, 2007;Katriel, 2013) but require the use of more challenging mathematical methods than many of the published applications of compartment models. We have shown that these shortfalls can be readily addressed by using a matrix model which is similar to a time since infection model (c.f. Katriel, 2013), but allows separate specification of time to becoming symptomatic and subsequent time to death or recovery and can be analysed using straightforward mathematical methods (Grant, 2020). In this paper we assume that the proportion of the population that is immune is negligible enabling us to use an even simpler version this model to predict the time course of the reduction in the epidemic in response to the introduction of restrictions on interactions between individuals, often referred to as "social distancing" and "lockdown".

The model
As in our previous paper, rather than combining all individuals which are in each compartment, the number of individuals in each compartment, and how long they have been there, are tracked in a vector. If the proportion of the population that is immune is small (so that we are in a period of exponential growth or decline, at a rate determined only by R), then we can simplify this model and only track exposed and infective individuals: At each time step, this vector is multiplied by a projection matrix in which the number of new exposed individuals is determined by the number of infective individuals and the value of R. In the simplest case, where infectivity is constant across the I j age classes, then each I individual gives rise to R/j individuals in class E1. Individuals that acquire infection move into the E 1 compartment, then move through the remaining E and then I compartments. With fixed incubation and infection periods, all individuals move to the final E i and Ij compartments before moving to the I1 and R compartments respectively, but varying incubation and infective periods can easily be accommodated (see Grant, 2020, for full details). If we assume a five day incubation period and an eight day infective period, then our population vector consists of five Exposed stages and eight Infective stages and the population projection matrix (with zeros other than those in the first row blanked out) is: The daily rate of change in the number of exposed and infective individuals is given by the largest eigenvalue of this matrix, λ. In this case, the mean serial interval (or generation time) from one newly infected individual to the next is 9 days, so R 0 ≈ λ 9. The equality is only exact when R0 = λ = 1, but the approximation is very close for R values in the range 0.25 to 3 (see blue line in Figure 1). The page 7 equivalent compartment model (including only the EI components of an SEIR model) has the projection matrix: . However, the approximation is poorer except for R0 = 1, particularly for values of R that are less than 1 (orange line in Figure 1). So as noted previously, compartment models underestimate infection rate increases when R is high, but overestimate R when an infection is under control and R is small. Variation in the incubation period reduces R at high values (as would be expected for any variance in vital rates, Ganyani et al., 2020;Lewontin & Cohen, 1969;Tuljapurkar, 1982), but has only a limited effect when R is less than 1.0 (purple line in Figure 1). 2020) was based on a data set that included negative serial intervals. Uncertainties about the value of the serial interval will affect the absolute value of R, but not comparisons over time; comparisons between geographical areas or between different data series. If R is equal to 1, the true value of the serial interval has no effect. For simplicity, if we assume that the serial interval is 7 days, then we can estimate R from time series that are reported at weekly intervals, using a 7 day running average for data that are reported daily. If the serial interval is less than this, then values of R that are less than 1 will be underestimated, while those greater than 1 will be overestimated. If, for example, the serial interval is actually 5 days, then assuming that it was 7 days would yield an estimate of 0.7 for a true value of 0.78 (= 0.7 5/7 ) and a value of 4 for a true value of 2.69. But uncertainties about the serial interval will affect estimates of R 0 from more detailed analyses in exactly the same way as they impact on our approximate calculation, as the serial interval or generation time is incorporated into most procedures to estimate R, either explicitly, or implicitly via the parameters of a compartment or other population model. The approach also assumes that a time series represents a constant proportion of numbers infected in the underlying population, but again, that challenge also affects more sophisticated analyses of data.
Time to becoming symptomatic, testing positive and time to death.
We cannot observe infection occurring. The data that we can observe are time series of numbers of individual becoming symptomatic; testing positive; being hospitalised or dying. As a first approximation, these data will lag behind changes in infection rates at an interval equal to the mean time from infection until that event occurs. Flaxman et al. (2020)

Using the tool on example time series
This approach allows the straightforward estimation of epidemic growth or decline rates from any time series of infection or death rates. The method involves some approximations, but the errors introduced by these are small when epidemics are declining and are smaller than those that result from uncertainties about the value of the serial interval, which also affect more sophisticated methods of estimating R. Data on COVID-19 infection and mortality rates vary in quality between countries depending upon intensity of testing; the criteria used to attribute deaths to COVID-19 and whether or not deaths in care homes are reported in the main national time series. The capacity for testing may have increased over time, leading to an increase in the number of cases which are identified by testing. The criteria used to select who is tested may have changed leading to a reduction in the proportion of tests that give a positive result. These are substantial challenges, but we do not examine them in detail here. We obtained the following data sets: 1) Daily data on deaths in hospital in England of patients with a confirmed COVID-19 test up until 17 th June (NHS England, 2020), from which data from 13 th June onwards were excluded from analysis as figures from the most recent few days are incomplete. Data were averaged weekly and the ratio of the average daily deaths in one week to that in the week before calculated. Data were analysed for the whole of England, and for each of seven English regions.
2) Deaths registered each week in England and Wales up until 5 th June 2020 where COVID-19 was identified as a cause of death (ONS, 2020b). Ratios of deaths in one week to those in the week before were calculated.
3) Daily numbers of positive test results in England from "Pillar 1" of the English testing program. These are based on hospital based testing of health and care workers and those with a "clinical need" but exclude swabs collected in the community and processed via commercial laboratories (Burn-Murdoch, Neville, Hughes, & Bounds, 2020;Public Health England, 2020a). Ratios between seven day averages were calculated.
In the presentation of these analyses, the ratio of numbers one week apart is referred to as a "weekly change". If the serial interval is close to 7 days, then these numbers will be close to the value of R. If, as is likely, the serial interval is less than seven days, these numbers will be biased away from 1, with the magnitude of this bias being greater for values substantially greater than 1 (see above). For comparisons between adjacent weeks, the date used to identify a weekly change is that of the last day in the second week used to calculate the ratio, so changes reflect events occurring, on average, 3.5 days earlier than this In late March, death rates in hospital in England for those with a positive COVID-19 test result initially increased by a factor of 6.7 per week ( Figure 2; equivalent to an R value of 3.9 if the serial interval is actually equal to 5 days), but then decreased, with the rate of change falling below 1 for the comparison between week ending 10 th April and week ending 17 th April. Regional data show a similar pattern (Fig. 3), with all but North West England having a rate of change lower than 1.0 at the same point in time. Weekly rates of change were then mostly in the range 0.6 to 0.9, with the regional geometrical means for the period 10 th April to 12 th July ranging from 0.64 in London to 0.93 in the North West, with an overall value for England of 0.75. Values are plotted using the date at the end of the second week used to calculate the ratio.  Availability of COVID testing data for England is problematic. As at 1 st July 2020, only "pillar 1" data, which includes health care works and patients presenting to hospitals are made publically available, even though the great majority of positive test results now come from commercial "pillar 2" testing (Burn-Murdoch et al., 2020;Public Health England, 2020c

Discussion
These three data sets give a consistent pattern, with peak increases in numbers of positive tests in early March, followed by peak increases in death rates in hospital a week later and peak increases in registered deaths a week after that. Rates of increase at the start of the epidemic were very high, corresponding to R values of 3.8 to 5 if the serial interval is equal to five days. It is possible that these initial values represent an over-estimate, as there may have been lower identification rates of symptomatic COVID cases in the early period of the epidemic, and limitations on testing capacity may have reduced the proportion of infected individuals being tested. So some of this initial high rate of increase may reflect an increase in diagnosis rates over time rather than an increase in disease prevalence. In all cases the rates of increase reduce below 1.0 around week ending 17 th April 2020. At a national level all show geometric mean weekly rates of change close to 0.75 over this period (equivalent to R = 0.81 for a serial interval of 5 days), although there is some spatial and temporal variability in rates of decline.
Is the pattern of these changes consistent with the expected consequences for R of policy interventions? On 16 th March 2020, the English government introduced recommendations on "social distancing" and voluntary self-isolation of those with pre-exiting health conditions that made them more vulnerable to COVID-19 (Public Health England, 2020b). Advice on personal hygiene and maintaining vigilance for COVID symptoms was in place before this and there is evidence that travel, and particularly use of public transport, began to decrease around 9 th March 2020 (Rieger, 2020).
This was followed on 23 rd of March 2020 by mandatory restrictions on movement, meetings between more than two people, and non-essential economic activity, usually abbreviated as "lockdown" (Cabinet Office, 2020). Given the respective 7+ and 20+ day intervals between becoming infected and obtaining a positive test result or dying, then impacts of lockdown on the rate of increase of positive tests and deaths would be expected to occur from around 30 th March and 12 th April respectively. However, the rates of increase in the time series decline some time before these dates, with the discrepancy being particularly marked for the two death rate time series, which both move into decline only shortly before we would expect to see any effects of the introduction on lockdown. This suggests that the voluntary changes in behaviour, including increased personal hygiene and self-isolation of symptomatic individuals had a much greater impact on transmission rates than the subsequent lockdown.
Given the severity of the reduction in social and economic activity that has occurred in England as a result of lockdown (Cabinet Office, 2020; Jarvis et al., 2020) it is perhaps surprising that R values remain only a little less than 1. However, there is evidence that population averages of reductions in interactions between individuals may give a poor guide to transmission dynamics to and from those who are acquiring the infection. Confirmed cases who gave details to the English "Test and Trace" system between 28 th May and 10 th June 2020 reported an average of 9.5 "close" contacts during the period from 48 hours before symptoms appeared until 7 days afterwards once missing data are removed (Department of Health and Social Care, 2020). Here, "close" contact was defined as being in the same household; spending more than 15 minutes within 2m; a face to face conversation at closer than 1m, or sexual contact. This is a much more restrictive definition of contact than that used by Jarvis et al (2020), who counted all interactions in which "a few words were exchanged" or there was skin to skin contact. All the forms of "close" contact identified by Test and Trace were at the time unlawful except in an individual's household or in a work environment where tight infection control measures were mandated. Average household size in the UK is 2.4 persons (ONS, 2017) so these interactions must be dominated by workplace and/or illicit interactions, unless many of the cases are occurring in overcrowded housing or large residential contexts. COVID-19 Attack rates within households may be as high as 17%, and overall attack rates with close contacts of 9.7% and 12.7% have been reported (Bi et al., 2020;Jing et al.;Mizumoto, Omori, & Nishiura, 2020).
Multiplying these latter two attack rates by the numbers of reported close contacts from Test and Trace would yield R values of 0.92 and 1.2 respectively. This suggests that the failure of R to reduce substantially below 1.0 may result from transmission of the infection between individuals who continue to have relatively high frequency of close contacts with others. Individuals with higher than average numbers of close contacts are likely to interact disproportionately with each other, as a result of overcrowded housing, work places like meat packing facilities and residential care homes where social distancing is difficult (O'Neill et al.;Reuben, 2020) or as a result of lifestyle choices. If this is the case, unselective nationwide "lockdowns" will have much less impact on the time course of an epidemic. Many of their restrictions will fall on interactions between individuals where attack rates are already very low as a result of social distancing, while they have much less impact on those interactions where attack rates are much higher. There appears to be considerable heterogeneity of