After the first reports of a new Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2), low-middle income countries (LMIC) like the Dominican Republic started facing the urgency of extensive rapid testing to limit the impact of this public health threat. SARS-CoV-2 is the causing agent of Coronavirus Disease 2019 (COVID-19), which has been spread all over the world. After a year, more than 70 million cases have been confirmed, and it is estimated that a million of them were detected across the Americas.1 A crucial part of the public health response to COVID-19 response is prompt diagnosis, tracing, and isolation of infected individuals to prevent further spreading.2

The standard diagnostic test, the real-time reverse transcriptase-polymerase chain reaction (qRT-PCR), has been implemented worldwide to confirm SARS-CoV-2 infection, allowing results with satisfactory levels of sensitivity and specificity.3 However, due to the high demand, there has been a limited number of reagents, requiring researchers to consider pool testing strategies.3–5 Pool testing is a diagnostic strategy used to identify viral infections, such as viral hepatitis.6 Several samples must be combined, analyzed in a single reaction, and if test results are negative, all the samples are considered undetected.7 Whereas, if the results are positive, all the individual samples in the pool must be analyzed to elucidate the positive cases.3,4,6

Pooling strategies have proven to prevent wasting SARS-CoV-2 testing resources and time, improving the testing capability in countries with an incidence rate of SARS-CoV-2 infection of 10% or less. However, the role of sample titration has not been fully elucidated.8,9 Scaling up of this methodology may be convenient in countries experiencing a shortage of resources and an increased demand throughout the pandemic.10,11 Dominican Republic response has been substantially affected by implementing a rapid deployment of test and tracing strategy in transmission hot spots throughout the country, mainly due to the limitations in importing and cold chains in the Caribbean customs system.12

This study aims to evaluate the effectiveness of the SARS-CoV-2 detection by pooled sample testing compared to individual testing in the context of COVID-19 response in a Caribbean country.

We analyzed saliva and nasopharyngeal samples from several hospitals in the Dominican Republic. Experiments were conducted at the Institute for Tropical Medicine and Global Health from October 5 to November 23, 2020. Samples used had a previously known diagnosis for COVID-2019.

We evaluated 210 pools out of 245 samples, among which SARS-CoV-2 was detected in 31% (n=77) and not detected in 69% (n=168). We distributed the positive samples according to the threshold cycle value (Ct), being the specific ranges <30Ct, ≥30Ct–≤33Ct, and >33Ct–≤36Ct. Positive samples were diluted with negative sample sets in 2ml viral transport media (VTM) to perform the pooling dilution. Each group included a single positive sample and the remaining volume of negative samples, depending on group size. Hence, the total volume of the smaller group (n=4) was 800ml, whereas the largest group (n=10) was 2ml.

We used the AdvanSure™ Nucleic Acid kit for RNA extraction following manufacturers’ protocol. Afterwards, we conducted a 1step RT-qPCR assay to detect the SARS-CoV-2-specific RdRp/E genes (RNA-dependent RNA polymerase), employing the PowerChek™ 2019-nCoV PCR kit and using FAST ABI 7500 Real-Time PCR (Applied Biosystems, Foster City, CA). A pool with a Ct value ≤37 was considered positive for SARS-CoV-2. Once we obtained the results, we evaluated the concordance, the rate of false negatives, the estimated increase in Ct obtained by the sample dilution, and the use of positive samples with low viral load. Identificators were eliminated from samples to protect patients’ identities, the Institutional Review Board (IRB) at Universidad Iberoamericana (CEI# 2020-16) approved this study.

To estimate the effectiveness of the pooling technique according to the group size, we calculated the concordance rate between the pooled tested and individual samples, as shown in Fig. 1.

Fig. 1.

Concordance of testing between pooling of samples and individual samples.

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Afterwards, the comparison between the Ct values of the positive samples used with the Ct obtained from the pools, enable us to identify how the dilution of the samples and the positive samples used with low viral load directly affect the analytical sensitivity of RT-PCR. As a result, for the groups of 4, 5, 6, and 7 samples, an estimated increase of 2Ct was obtained. Concerning the groups of 8 and 9, we attained an estimated increase of 3Ct. Finally, for the groups of 10 samples, an estimated increase of 4Ct was obtained. In addition, the rate of false negative results was obtained by dividing the number of negative tests and the total samples analyzed, as shown in Table 1.

Sample pooling strategy has been implemented in different countries to increase the SARS-CoV-2 detection capacity and reduce reagent wasting.5 Our findings have important implications in countries with a high positivity rate. To date, Latin-America is an epicenter for new infections in America. The higher the positivity rate, the lower the number of samples chosen for pooling analysis to ensure the RT-PCR sensitivity and guarantee non-reagent exhaustions in limited settings. As shown in Fig. 1, for pools of 4 samples, we obtained a concordance of 100% for all Ct values. Additionally, the false negative rate was 0% even for pools with positive samples with Ct≥36. These results suggest that the viral RNA concentration in the positive samples used was not affected after the dilution of the samples tested. Therefore, pooling of four samples for SARS CoV-2 detection by real-time RT-PCR may be an adequate strategy without the loss of sensitivity for low viral loads.

Praharaj et al.5 created 110 pools out of 5 samples and obtained a concordance of 100% for a Ct less than 30. Whereas concordance for values with Ct≥30–≤33 and >33–≤36 was 95.5% and 69.7%, respectively. Their results affirm that concordance rates for samples with a Ct value greater than 33 cycles were considerably lower.5 When we compared our findings, we noticed the same concordance for Ct values less than 30. However, the concordance for Ct values with a Ct≥30–≤33 and >33–≤36 was 80% and 66%, respectively. Our results suggest that pools of five samples are a viable size, in case the evaluated tests have a low positivity rate (less than 10%), being ideal to employ this strategy in asymptomatic individuals. For pools of 6 samples, concordance and false-negative results demonstrate how the efficiency of the strategy flattens out due to the dilution and viral load of the samples used.

This information is crucial for selecting the ideal pool size for the Dominican Republic, since using a pool of 5 samples or greater could fail to detect SARS-CoV-2 positive cases. In contrast with our findings, Bateman et al.13 obtained fewer false negatives for pools of 5 and 10 samples. Unlike us, they used Ct values between 14 and 35 instead of setting the limit on 36, which probably affected the sensitivity of RT-PCR for those pools that had such number of samples.13

One limitation of our study is the use of two types of samples, saliva and nasopharyngeal swabs. Although the use of a single sample type would have been more meticulous, we selected different types of samples due to the current restraints in the accessibility of collection tools in LMIC countries.

Based on official data provided by the Dominican Ministry of Health, the positivity rate in our country as of February 2021 was 17.34%.14 Aragón-Caqueo et al. suggested that the optimal number of samples per pool is three, since the positivity rate of cases is inversely proportional to the optimal pool size. Furthermore, the minimum net savings in detection kits for a positivity rate in the range of 8–20% is 17.9%. Choosing to perform pools of three samples entails evaluating all the subjects in the event of a positive pool sample to detect the cases that are positive. It implies an increase in the logistical complexity of this strategy.3

In conclusion, according to the positivity rate in the Dominican Republic, the optimal size to perform a pooling strategy shall be three samples. However, our results indicate that a pooling of four samples is an optimal strategy for SARS-CoV-2 detection that helps to reduce the amounts of reagents used. We do not recommend using pooling testing with more than five samples since the detection sensitivity of the RT-PCR is affected after the dilution of samples. This strategy might be a useful tool in pandemic responses, especially in countries with limited technical personnel and where investment on avant-garde technologies is not available.

The authors declare that they have no conflicts of interest.