Campus data

All case data come from the Fall semester in 2020 (10 August – 4 December inclusive). Approximately 7000 undergraduate students live on the University campus, about 85% of the total undergraduate population, although this may have been reduced during the pandemic. Early in the semester, the majority of cases were notified through screening of individuals with symptoms (Fig. 1a); there was initially no universal surveillance testing. The population used in this study was undergraduate students diagnosed through symptomatic testing (i.e., individuals who reported to the University health services with symptoms of COVID-19) via RT-PCR processed at an off-campus facility, in the Fall semester. This included those who lived both on- and off-campus, and excluded on-campus staff. We do not include those tested through asymptomatic screening or contact tracing, as these two routes were not consistently applied throughout the semester. Symptomatic screening proceeded throughout the semester, while a very limited amount of asymptomatic screening began on 21 August following the first peak, and proceeded through to the end of the semester. A recent study estimated the sensitivity and specificity of the RT-PCR tests to be 0.859 (95% CrI: 0.547–0.994) and 0.998 (95% CrI: 0.992–0.999) respectively [Reference Perkins15]. Students arrived back on campus in time for the start of classes on August 9; most students arrived back in the final week before classes started, i.e. beginning on 2 August. Following high incidence in the first weeks back, the University underwent a 2-week period of online classes, starting on 19 August and ending on 2 September. Following notification, cases that lived on campus entered an isolation period, which typically lasted 10 days. While some of these cases were isolated in on-campus facilities, some cases were isolated off-campus, meaning they would not have been shedding into the campus wastewater system for that period. Additionally, on-campus contacts of notified cases were required to enter a period of quarantine of variable length dependent on test results [16].

Fig. 1.

In all panels, the shaded blue region indicates a period of online instruction, where students remained on campus but did not have in person instruction, and the vertical dashed line indicates the start of classes (August 9); the majority of students arrived in the week preceding this date. (a) notified cases among students on the University campus in the fall semester, delineated by whether the case was found due to symptomatic screening or not. (b) the estimated timeseries of infections (purple line), alongside the actual (bars) and implied (green dashed line) distributions of symptomatic case notification dates. (c): wastewater measurements by date. Open circles indicate the daily mean of three recovery-corrected RNA measurements, and whiskers indicate the smallest and largest measurements on that day.

Wastewater data

From 3 August to 30 November 2020, 24-h time-based composite wastewater samples were collected each day from the manhole receiving all of the University wastewater. The wastewater system collects sewage from residence halls and facilities ranging from approximately 1600 to 5800 feet in the linear distance along the sewer lines and the average daily flow during the monitoring period was 3.29 million litres per day (s.d. ± 0.29). The low coefficient of variation (8%), coupled with the fact that storm water is collected via a separate system, suggests that the variation associated with wastewater flow rate would be small compared with other sources of variation. Sampling was interrupted from 1 September to 9 September due to a breakdown of the composite sampler. Full procedures for the processing of the wastewater samples has been detailed elsewhere [Reference Bivins17]. Briefly, the composite sample was programmed to collect one 50 ml sample every hour, 24-h per day, throughout the sampling period. The wastewater composite sample from each day was mixed well and a 100 ml aliquot was removed, spiked with a process control (bovine respiratory syncytial virus; BRSV), which has been observed to mimic the recovery of SARS-CoV-2 from wastewater [Reference Bivins18], and filtered using an electronegative membrane. After filtration, the membranes were aseptically rolled into bead tubes and homogenised using a bead beater, and the resulting liquid was extracted using a Qiagen PowerViral DNA/RNA kit. As detailed elsewhere [Reference Bivins18], the resulting purified nucleic acids were assayed in triplicate for SARS-CoV-2 RNA using the N1 assay and for the process control RNA in single reactions via RT-ddPCR. During the period of 21 September to 11 October, Qiagen PowerViral DNA/RNA kits were not available and an alternative extraction method was used; however, the resulting RT-ddPCR data from this interval did not pass quality assurance protocols and were removed from the resulting dataset. Given the recovery of BRSV was previously observed to reflect that of SARS-CoV-2 in municipal wastewater (efficiency mean: 4.0% ± s.d.: 12%) [Reference Bivins18], the SARS-CoV-2 RNA concentrations in wastewater were recovery-corrected to account for the measured process efficiency as suggested during a previous method comparison [Reference Pecson B19]. We calculated the cross-correlation of the recovery-corrected RNA concentration time series with the case notification time series at lags of up to 17 days (Fig. S2).

Infection timing estimation

To estimate the incidence of new infections, we deconvolved the symptomatic case notification time series with the distribution of the time from symptom onset to testing. We estimated the distribution of time from infection to testing as the convolution of the incubation period and a delay from symptom onset to testing. We approximated the incubation period as a log-normal distribution with parameters μ = 1. 621 and σ = 0.418, according to Lauer et al. [Reference Lauer20], and the delay between symptom onset and testing as a Poisson distribution (see Table 1 for a summary of all parameters used). In the baseline scenario, we used a mean delay from symptom onset to testing of 2 days, but also tried 0, 1 and 5 days in sensitivity analyses (Figs S5–S7). We then deconvolved this distribution from infection to testing from the case notification time series by maximum-likelihood deconvolution, using the backprojNP function in the R ‘surveillance’ package version 1.18.0 [Reference Salmon, Schumacher and Höhle21–Reference Meyer, Held and Höhle23]. This algorithm seeks to estimate the infection time series with the highest likelihood of reproducing the observed case series, using knowledge about the distribution of the delay from infection to case notification. The algorithm works by proposing an initial distribution of infection times, and then sequentially adjusting this estimate to maximise the likelihood of reproducing the notified cases. It uses a Poisson likelihood for the number of infections in a day, and makes no assumption on the temporal pattern of infections. We set the smoothing parameter k = 10 and used default settings for all other parameters. Setting the smoothing parameter to a relatively high value such as this helps ensure that the algorithm captures the features of the infection time series without overfitting the noise in the case notification time series.

Table 1.

Summary of parameter. Where the symbol column is empty, there was no symbol used for that parameter

Shedding distribution inference

We modelled the individual shedding distribution, σ(t), as a gamma distribution with the shape α and rate β, with the origin being the date of infection for that individual. We then adjusted this for entry and exit from isolation using the probability that the individual had entered isolation t days after infection, p_enter(t), the probability they had exited isolation by t days after infection, p_exit(t), the probability that they are reported, p_r and the proportion of reported cases entering isolation on day s of the epidemic, p_i(s). The parameter p_enter(t) was given by the cumulative probability that the incubation period and delay from symptom onset to testing (described in the previous section) had been completed by day t, and p_exit(t) was just this lagged by 10 days – i.e.

$$p_{exit}( t ) = p_{enter}( {t-10} ) \; {\rm if} \ge 10 \; $$

$$p_{exit}( t ) = 0\; {\rm otherwise}. $$

We estimated p_i(s) by fitting a generalised additive model with a logit link to the proportion of infections entering isolation on day s, using the mgcv package (version 1.8–31) in R [Reference Wood25] (Fig. S1). We estimated the fraction of infections reported, p_r, in the calibration (see below), assuming that it did not vary through time. In a sensitivity analysis, we set p _r = 0.24, to reflect the number of infections per reported case used by the CDC [24]. Given all these parameters, the individual shedding distribution adjusted for isolation was

$$\sigma _i( t ) = ( {1-p_rp_i( {s_0 + t} ) ( {\,p_{enter}( t ) -p_{exit}( t ) } ) } ) \sigma ( t ) , \;$$

where s ₀ is the day of the epidemic on which the individual was infected. Note that as $p_{exit}( t ) \le p_{enter}( t ) \forall t$, it follows that σ _i(t) ≤ σ(t).

The number of new infections per day, I(t), was found by dividing the number of infected individuals on a given day that were ultimately reported, I’(t), by the proportion of infections that were reported, such that I(t) = I ^′(t)/p _r. We then estimated the expected temporal pattern of SARS-CoV-2 RNA in the wastewater over time by summing the shedding distribution for each individual infected on a given day through time. We then multiplied this by a scaling constant, θ, to capture the magnitude of shedding. This yielded the reconstructed mean RNA concentration,

$$C_m( t ) = \theta \mathop \sum \limits_{s = {-}\infty }^t I( {s-t} ) \sigma _i( s ) .$$

We fitted C_m(t) to the observed RNA concentration in wastewater, C_d(t), for each of the three daily replicate subsamples, using Markov chain Monte Carlo methods in the BayesianTools (version 0.1.7) R package [Reference Hartig, Minunno and Paul26], with a negative binomial likelihood, for which the dispersion parameter, r, was also fitted. When the RNA concentration in the wastewater was below the 95% limit of detection, we use the cumulative distribution function of the negative binomial distribution to determine the probability of observing data below that threshold. The baseline 95% limit of detection was 220 GC / l, which was then recovery-corrected, D ₉₅(t), and so varies through time (Fig. 2c). As a result, there were five free parameters: α, β, θ, r, and p_r, with their likelihood given by

$$L( {\alpha , \;\beta , \;\theta , \;r\vert C_d( t ) } ) = \displaystyle{{C_d( t ) + r-1} \over {C_d( t ) }}( {1-p} ) ^rp^{C_d( t ) \; {\rm if} C_d( t ) > D_{95}( t ) }$$

$$L( {\alpha , \;\beta , \;\theta , \;r\vert C_d( t ) } ) = \mathop \sum \limits_{c = 0}^{D_{95}( t ) } \displaystyle{{c + r-1} \over c}( {1-p} )^rp^{C \;{\rm otherwise} , \;}$$

where p = C _m/C _m + r. We used default settings from the BayesianTools package, and a uniform prior on all parameters with the following ranges: α ∈ (1, 10³), β ∈ (0, 10³), θ ∈ (0, 10⁵), r ∈ (0, 10⁵) and p _r ∈ (0, 1). We insisted that the shape parameter α was greater than 1 so that σ(0) = 0; i.e., people are not shedding at the moment they are infected. The MCMC chains and posterior parameter densities are shown in Fig. S9 and correlations between parameters are shown in Fig. S10. There were strong positive correlations between α and β and between θ and p_r. In the former case, this was likely due to the fact that the mean of the gamma distribution was α/β. In the latter case, this was likely due to the fact that θ and p_r appear as a ratio in the equation for C_m(t), although p_r does also appear in the isolation adjustment of the shedding distribution, so the two parameters could be separately identified. See Fig. S3 for examples of how different gamma distributions and delays from symptom onset to testing translate into different temporal patterns of viral RNA measurements in wastewater.

Fig. 2.

(a) Implied shedding distribution and 95% credible interval. The vertical dashed line indicates the day of peak shedding (8 days). The red line indicates the average shedding distribution of someone who enters isolation (b) Distribution of predicted daily recovery-corrected measurements at the peak intensity (August 16) implied by the negative binomial likelihood. The red shaded bar shows the range in which the predicted mean measurement fell (c) Mean predicted RNA concentration (red line), 95% prediction interval (light grey line). White open circles and whiskers indicate the daily mean measurements and minimum/maximum values respectively. The dashed line indicates the recovery-corrected 95% limit of detection. Data points below the 95% limit of detection are plotted as the midpoint of 0 and the 95% limit of detection for that day.