key: cord-0695397-vttap03e authors: Freire-Paspuel, Byron; Vega-Mariño, Patricio; Velez, Alberto; Cruz, Marilyn; Garcia-Bereguiain, Miguel Angel title: "Sample pooling of RNA extracts to speed up SARS-CoV-2 diagnosis using CDC FDA EUA RT-qPCR kit" date: 2020-09-24 journal: Virus Res DOI: 10.1016/j.virusres.2020.198173 sha: 044073b635e6db6b4e92fb1fa1eb177e1fc63286 doc_id: 695397 cord_uid: vttap03e BACKGROUND: The CDC protocol for SARS-CoV2 RT-PCR diagnosis (2019-nCoV CDC kit) is considered a gold standard worldwide; based on three different FAM probes (N1 and N2 for viral detection; RP for RNA extraction quality control), three reactions per sample are needed for SARS-CoV-2 diagnosis. RESULTS: We herein describe a sample pooling protocol: pooling 3 RNA extractions into a single PCR reaction; we tested this protocol with 114 specimens grouped in 38 pools and found no significant differences for N1 and N2 Ct values between pool and single sample PCR reaction. CONCLUSION: This pool of three protocol has a sensitivity of 100 % compared to the standard single sample protocol. For a typical 96-well plate, this pool assay allows 96 samples processing, speeding up diagnosis and reducing cost while maintaining clinical performance, particularly useful for SARS-CoV-2 diagnosis at developing countries. The COVID19 pandemia has challenged public health systems worldwide, not only for patient care but also for rapid enough surveillance and control programs. Although new technologies are becoming available like Loop-Mediated Isothermal Amplification (LAMP) Assays in point of care devices to speed up SARS-CoV-2 diagnosis (1) , the gold standard for CDC or WHO is still . Several in vitro diagnosis RT-qPCR kits are available on the market for the detection of SARS-CoV-2. Some of them have received emergency use authorization (EUA) from the U.S. Food & Drug Administration (FDA), like 2019-nCoV CDC EUA from the USA Center for Diseases Control and Prevention (CDC). The CDC assay is based on N1 and N2 probes to detect SARS-CoV-2 and RNaseP (RP) as an RNA extraction quality control (2). According to CDC protocol for 2019-nCoV CDC EUA, the 3 probes are FAM labelled so 3 PCR reactions are needed for each specimen diagnosis. With no triplex PCR protocol validated for N1, N2 and RNaseP, the current CDC protocol reduces daily sampling processing capacity for a typical 96 well plate PCR device. On developing countries like Ecuador, most of clinical microbiology laboratories running SARS-CoV-2 diagnosis operates with a single Real Time PCR device. Under this scenario, pooling samples is a powerful tool to increase SARS-CoV-2 testing capacity (4) (5) (6) (7) . Also, testing costs are reduced and supply shortage may be mitigated by using a pooling sample protocol, crucial to support surveillance at developing countries. This study evaluates the performance of a sample pooling RT-qPCR protocol where samples are pooled after RNA extraction and loaded into the same RT-qPCR reaction for SARS-CoV-2 diagnosis, using 2019-nCoV CDC EUA kit (IDT, USA). J o u r n a l P r e -p r o o f Study setting. 114 clinical specimens (nasopharyngeal swabs collected on 0.5mL TE pH 8 buffer) from individuals selected during SARS-CoV-2 surveillance in Galapagos Islands started on April 8th 2020, were included on the evaluation study. Also, a negative control (TE pH 8 buffer) was included as control for carryover contamination for each set of 23 RNA extractions. "LabGal" at "Agencia de Regulacion y Control de la Bioseguridad y Cuarentena para Galapagos" at Puerto Ayora in Galapagos Islands (Ecuador) is the only available SARS-CoV-2 diagnosis laboratory on site, operating with a single 96 well plate PCR device (CFX96 from BioRad) to cover a population above 20.000 people. Samples were tested following an adapted version of the CDC protocol: (1) using PureLink Viral RNA/DNA Mini Kit (Invitrogen, USA) as an alternate RNA extraction method; (2) using CFX96 BioRad instrument (8, 9) . We performed this protocol for 38 SARS-CoV-2 positive and 76 negative samples individually, but also pooling one positive sample with two negative samples at the RT-PCR reaction mix. While 4 uL of a single RNA was added to a single RT-PCR reaction, 2.5 uL of each RNA was added to the triplet RT-PCR reaction (in both cases, final volume of reaction was 15uL). The RT-PCR assay was validated to detect 5 viral RNA copies/uL by using 2019-nCoV N positive control (IDT, USA), following CDC recommendations (2). According to CDC protocol, a sample is considered positive when Ct values for N1 and N2 are 40 or smaller (2). Statistics. For statistical analysis of Ct values, t-student and Altman-Bland analysis were performed. Ethics statement. All samples have been submitted for routine patient care and diagnostics. Ethical approval for this study was not required since all activities are according to legal provisions defined by the "Comité de Operaciones Especiales Regional de Galápagos" that is leading the Covid19 surveillance in Galapagos Islands. No extra specimens were specifically collected for this validation study. All data used in the current study was anonymized prior to being obtained by the authors. The 114 samples included on this study were tested for SARS-CoV2 following the standard protocol described on the methods. 38 of this samples tested positive for N1 and N2 viral probes, and Ct values are detailed on Table 1 . These 114 samples were also pool on group of 3 samples after RNA extraction and prior to RT-PCR following the pool protocol detailed on the methods. The Ct values for N1 and N2 for the 38 positives samples on the RT-PCR pool reaction are detailed on Table 1 . All positive pools included only a positive sample and two negative samples, with exception of a pool that included 3 positives samples (samples 10, 11 and 12 on Table 1 ). All the 36 pools including at least a positive sample tested positive on the pool RT-PCR reaction, so the sensitivity obtained for our 3 sample pooling protocol was 100%. We found no significant differences for Ct values between the single sample reaction and the 3 sample pool RT-qPCR reaction: 31,30 ± 3,69 vs 31,16 ± 4,04 for N1 (p= 0.72); 34,09 ± 3,83 vs 33,25 ± 3,96 for N2 (p=0.14). Results are detailed on Table 2 . Moreover, Altman Bland analysis confirmed that all Ct values for 3 samples pools reactions were included within the 95% CI, with the only exceptions of samples 11 and 12. These samples were pooled with sample 10 (all 3 samples were SARS-CoV2 positive) and so the Ct values for N1 and N2 for the pool reaction is the same for all these samples (See Table 1 ) and higher for samples 11 and 12 than single sample Ct values. Our results support the use of a 3 samples pool RT-qPCR protocol for SARS-CoV-2 diagnosis without reducing sensitivity compared to the standard single sample RT-qPCR protocol (2). As no lost of sensitivity was found associated to the RT-PCR reaction (no shift on Ct values for N1 and N2), the only potential source for false negative results would be low quality of RNA extraction of sample included on a pool, where the other samples would mask the RNaseP amplification on the RT-PCR. However, on our experience, less than 0.5% of samples does not yield a positive amplification for RNaseP. So, we J o u r n a l P r e -p r o o f recommend to improve this 3 samples pool protocol only for laboratories with high performance on RNA extraction and also run periodically RNA extraction quality control tests. This protocol is an easy way to speed up SARS-CoV-2 diagnosis when using the CDC RT-qPCR protocol: the need of three PCR reactions per sample due to FAM labelling for the three probes is corrected by pooling 3 samples for PCR. This protocol allows to optimize the number of samples per running at a typical 96 well PCR device like the one used in our "LabGal" laboratory at Galapagos Islands. For small scale labs at developing countries like Ecuador, this is an useful way for reagents savings and increase diagnosis capacity without losing sensitivity, and also to compensate supply shortage (8) . Although a few reports regarding sample pooling for SARS-CoV-2 diagnosis have been published recently (3) (4) (5) (6) (7) , only 3 of those include sensitivity evaluation (3, 4, 6) . Moreover, this is the first study to our knowledge using CDC FDA EUA RT-qPCR kit and also not showing Ct shifts and reduced sensitivity for sample pooling. We have been successfully using this protocol during COVID19 surveillance at Galapagos Islands where more than 5% (over 2000 subjects) of the population has been tested on a single lab with only a Real Time PCR device within a month period. Our data with over 600 pools tested also endorses a 100% specificity for the 3 sample pooling protocol, as we never found a positive pool that did not yield at least a positive single sample. The main limitation of our 3 sample pool protocol is the need for running an extra RT-PCR reaction for positives pools on a single sample mode that delays diagnosis a few hours; although overall laboratory diagnosis is clearly speed up on our experience. On one hand, this protocol would not be useful when high prevalence of SARS-CoV-2 is expected and diagnosis is expedited as for hospitalized individuals. On the other, when a low prevalence below 5% is expected and a wide screening is the goal, the 3 samples pool protocol would be of great help as less than 15% of pools would test positive. Novel Coronavirus Disease (COVID-19): Paving the Road for Rapid Detection and Point-of-Care Diagnostics Interim Guidelines for Collecting, Handling, and Testing Clinical Specimens from Persons for Center for Diseases Control and Prevention Pooling of samples for testing for SARS Pooling of nasopharyngeal swab specimens for SARS-CoV-2 detection by RT-PCR Sample Pooling as a Strategy to Detect Community Transmission of SARS-CoV-2. JAMA 2020 Evaluation of COVID-19 RT-qPCR test in multi-sample pools Efficient high throughput SARS-CoV-2 testing to detect asymptomatic carriers Tipped Plastic Swabs for SARS-CoV-2 RT-qPCR Diagnosis to Prevent Supply Shortages. Front Cell Infect Microbiol Evaluation of nCoV-QS (MiCo BioMed) for RT-qPCR detection of SARS-CoV-2 We thank the medical personnel from "Ministerio de Salud Pública" at Galapagos Islands and the staff from the "Agencia de Regulación y Control de la Bioseguridad y Cuarentena para Galápagos" for their support. We specially thank Gabriel Iturralde, Oscar Espinosa and Dr Tannya Lozada from "Dirección General de Investigación de la Universidad de Las Américas", and the authorities from Universidad de Las Américas, for logistic support to make SARS-CoV-2 diagnosis possible in Galapagos Islands.