Modelling pooled testing

We aimed to estimate the population prevalence over time, represented by the latent variable $ \pi (t) $ , from pooled testing data concerning $ {N}_t $ individuals divided into $ {P}_t $ pools of size $ {M}_t $ , of which $ {K}_t $ have a positive test. From the prevalence $ \pi (t) $ , we computed the probability $ \theta (t) $ that a single pooled test returns positive. In case of perfect specificity and sensitivity of RT-PCR tests, the probability $ \theta (t) $ is

$$ \theta (t)=1-{\left(1-\pi (t)\right)}^{M_t}. $$

We then accounted for the imperfect sensitivity $ ( Se) $ and specificity $ ( Sp $ ) of RT-PCR tests. We followed the approach of Daon et al. who observed that test sensitivity increases with pool size and assumed that imperfect specificity was caused by sample contamination and thus does not depend on pool size [Reference Daon, Huppert and Obolski15]. The probability $ \theta (t) $ that a single pooled test returns positive becomes:

$$ \theta (t)=1- Sp{\left(1- Se\cdot \pi (t)\right)}^{M_t}. $$

See Supplementary Material S1, Section 1.1 for more details.

Inference

The sensitivity and the specificity were treated differently. We assumed a fixed specificity of 100% (this assumption was relaxed in a sensitivity analysis, Supplementary Material S1, Section 2.3). On the other hand, due to varying estimates reported for the sensitivity, we treated it as a free parameter, propagating the uncertainty about $ Se $ into the population prevalence estimate. The sensitivity $ Se $ was jointly estimated alongside the prevalence using the number of positive RT-PCR tests $ L $ among $ M $ individuals with confirmed SARS-CoV-2 infection:

$$ \Pr \left(k=L\right)=\mathrm{Binomial}\left(M, Se\right). $$

For this, we used data from 20 studies, with a total sample size of 8,026 [Reference Marando, Tamburello, Gianella, Taylor, Bernasconi and Fusi-Schmidhauser17], resulting in a mean $ Se $ value of 84.6%. Last, we linked this probability to the pooled test results using a binomial likelihood:

$$ \Pr \left(k={K}_t\right)=\mathrm{Binomial}\left({P}_t,\theta (t)\right). $$

Information about prior distributions and parameter choice can be found in Supplementary Material S1, Section 1.2.

Spatio-temporal structure

We used inverse-logit transformed GPs to express the temporal correlation of prevalence $ \pi (t) $ [Reference Riutort-Mayol, Bürkner, Andersen, Solin and Vehtari18]:

$$ \pi (t)\sim {\mathrm{logit}}^{-1}\left(\mathrm{GP}\left(\mu, \varSigma \right)\right) $$

where the GP is defined by a mean $ \mu $ and a kernel $ \varSigma $ . $ \varSigma $ is characterized by an exponentiated quadratic kernel, where the covariance between prevalence at two time points decreases exponentially with the interval between these points. The two parameters of the exponentiated quadratic kernel, that is, the length scale and the variance parameters, were estimated during the fitting procedure. We used a hierarchical structure with two levels expressing the spatial correlation of prevalence. To provide an aggregated prevalence estimated for each higher-level area while allowing for some variation between the subareas belonging to the same higher-level area, we used a beta-binomial distribution [Reference Kim and Lee19]:

$$ \Pr \left(k={K}_{i,j,t}\right)=\mathrm{Beta}\hbox{-} \mathrm{binomial}\left({P}_{i,j,t},\kappa {\theta}_j(t),\kappa \left(1-{\theta}_j(t)\right)\right), $$

where $ i $ refers to the subarea, $ j $ refers to the higher-level area, and $ \kappa $ is a dispersion parameter. This approach can be adapted to any two nested geographical areas to estimate the prevalence at the highest level. For Switzerland, the subareas correspond to the cantons (NUTS-3 in the Eurostat nomenclature of territorial units), which are nested within regions (NUTS-2) or the entire country [20].

Simulation study

We performed a simulation study to validate the ability of the model including a spatiotemporal structure (thereafter named GP model) to estimate population prevalence. We simulated four scenarios mimicking different dynamics of SARS-CoV-2 prevalence in five hypothetical subareas over 30 weeks, using a deterministic susceptible-exposed-infected-recovered (SEIR) model (Supplementary Material S1, Section 1.3). In scenario 1, the prevalence was kept relatively stable at around 2.5%, while it increased from 0% to 5% in scenario 2, increased up to 7.5% in one wave in scenario 3, and increased up to 10% in two successive waves in scenario 4 (Figure 1a). We introduced heterogeneity in prevalence across subareas with a beta distribution. For each scenario and region, we simulated pooled test data for each week of different pool sizes (5, 10, or 20) and total sample sizes (100, 500, 1,000, or 5,000, equally spread over the five subareas). We then applied the GP model to the simulated data to estimate the weekly overall prevalence and compared estimates to the true values used in the simulation. For comparison, we also assessed the performance of a naive model that ignored the temporal correlation and estimated the prevalence for each week independently. We repeated the procedure 100 times for each scenario and combination of pool size and total sample size, and calculated two metrics: (1) the root mean squared error (RMSE) of the point estimate of prevalence, measuring accuracy, and (2) the half-width of the 95% credible interval (95%CrI) around the prevalence estimate, measuring sharpness [Reference Gneiting, Balabdaoui and Raftery21].

Figure 1. Simulation study (a) Three scenarios of prevalence over time were used to simulate pooled test data. The dashed line shows the overall prevalence, and the circles show the prevalence values across five subareas. (b) Example of model fit to scenario 3 for the naive model and the Gaussian process (GP) model. (c) Root mean squared error (RMSE) measuring the accuracy of prevalence estimates obtained from the naive model or the GP model (lower values are better), for each combination of pool size $ P $ (5, 10, or 20) and total sample size $ N $ (100, 500, 1,000, or 5,000). (d) Half-width of the 95% credible interval measuring the sharpness of prevalence estimates obtained from the naive model or the GP model (lower values are better). (e) RMSE of prevalence estimates obtained from the naive model or the GP model according to the population prevalence (<2%, 2–5%, and 5–10%).

Analysis of Swiss data

We applied the model to the Swiss weekly pooled test data from 19 April 2021 to 29 August 2022. During this period, repeated pooled testing was conducted as part of the wider health protection response, with the primary objective of identifying and isolating infectious cases of SARS-CoV-2 infection. It was not designed to produce prevalence estimates, so the data collection was secondary to the immediate use of information by local health authorities. The program was implemented in each canton independently but followed similar modalities. The implementation was supported by the federal government with seed financing of the software and logistical infrastructure, and cost coverage of each test. All samples were tested using RT-PCR, and most cantons used the same infrastructures and laboratories. All laboratories were accredited. The data were collected by the 26 Swiss cantons and it was legally required to be sent to the Federal Office of Public Health (FOPH) weekly. Each canton had to report the weekly numbers of total pools, positive pools and number of participants. We summarized the data by the seven Swiss NUTS-2 regions (Central, Eastern, Lake Geneva, Middle (‘Mittelland’), Northwest, Ticino, and Zurich [20]) to estimate weekly regional prevalence estimates from multiple observations at the cantonal level (except for canton Ticino which is also a NUTS-2 region by itself). We also summarized cantonal-level observations to obtain country-level estimations of prevalence for each week with the same approach. We used multiple imputation to impute missing pool sizes (0.7% of cases, Supplementary Material S1, Section 1.4) [Reference Azur, Stuart, Frangakis and Leaf22].

Pooled tests with a pool size of 4 or larger were financed by the state and performed in a selection of (1) schools, (2) care centres, and (3) workplaces in order to reduce the need for global control measures indiscriminate to local conditions. Samples from schools included children and their teachers. The care setting included long-term care facilities, elderly people homes and hospitals and comprised both staff and patients or residents. Workplaces included several companies and public administrations. In most cases, saliva samples were pooled on-site, before being transported to the laboratory, but the pooling could also be done at the laboratory. There were standardized recommendations for all processes including sample collection and pooling, transportation, waste management, and molecular analysis (Supplementary Material S2). In all settings, individuals could contribute repeatedly over successive weeks.

We considered the three settings separately and obtained prevalence estimates over time for each setting and NUTS-2 region, and at the national level. We used Spearman’s rank correlation coefficient on posterior samples to compare the prevalence estimates across areas and settings and with other data on the SARS-CoV-2 epidemic in Switzerland (counts of reported cases of SARS-CoV-2 infection, COVID-19 hospitalizations and COVID-19 deaths). We performed all the analyses in R version 4.2.1 [23] and Stan version 2.29.1 [Reference Carpenter24]. The code is available from https://github.com/erikstuder/poolprevBAG. We also developed the R package poolprev that can be used to apply these methods in other settings (https://github.com/anthonyhauser/poolprev).