Pre-analytical considerations in the development of a prototype SARS-CoV-2 antigen ARCHITECT automated immunoassay.

OBJECTIVES: To evaluate pre-analytical challenges related to high-volume central laboratory SARS-CoV-2 antigen testing with a prototype qualitative SARS-CoV-2 antigen immunoassay run on the automated Abbott ARCHITECT instrument. METHODS: Contrived positive and negative specimens and de-identified nasal and nasopharyngeal specimens in transport media were used to evaluate specimen and reagent on-board stability, assay analytical performance and interference, and clinical performance. RESULTS: TCID50/mL values were similar for specimens in various transport media. Inactivated positive clinical specimens and viral lysate (USA-WA1/2020) were positive on the prototype immunoassay. Within-laboratory imprecision was ≤0.10 SD (<1.00 S/C) with a ≤10% CV (≥1.00 S/C). Assay reagents were stable on board the instrument for 14 days. No high-dose hook effect was observed with a SARS-CoV-2 stock of Ct 13.0 (RLU>1.0 × 106). No interference was observed from mucin, whole blood, 12 drugs, and more than 20 cross-reactants. While specimen stability was limited at room temperature for specimens with or without viral inactivation, a single freeze/thaw cycle or long-term storage (>30 days) at -20 °C did not adversely impact specimen stability or assay performance. Specificity of the prototype SARS-CoV-2 antigen immunoassay was ≥98.5% and sensitivity was ≥89.5% across two ARCHITECT instruments. Assay sensitivity was inversely correlated with Ct and was similar to that reported for the Roche Elecsys® SARS-CoV-2 Ag immunoassay. CONCLUSIONS: The prototype SARS-CoV-2 antigen ARCHITECT immunoassay is sensitive and specific for detection of SARS-CoV-2 in nasal and nasopharyngeal specimens. Endogenous proteases in mucus may degrade the target antigen, which limits specimen storage and transport times and complicates assay workflow.

Author Correction: Metagenomic sequencing with spiked primer enrichment for viral diagnostics and genomic surveillance.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

ARCHITECT® HIV Ag/Ab Combo assay: correlation of HIV-1 p24 antigen sensitivity and RNA viral load using genetically diverse virus isolates.

BACKGROUND: HIV antigen/antibody (Ag/Ab) combination assays represent a significant advancement in assays used for diagnosing HIV infection based on their ability to detect acute and chronic infections. During acute HIV infection (AHI), detection depends on assay sensitivity for p24 Ag. OBJECTIVE: To directly compare the Ag sensitivity of the ARCHITECT(®) HIV Ag/Ab Combo assay to RNA viral load using cell culture supernatants of virus isolates. HIV-1 isolates allow correlation in the total absence of an antibody response to infection and across genetically diverse HIV-1 group M strains. METHODS: Thirty-five HIV-1 isolates comprising subtypes A-D, F and G, CRF01_AE, CRF02_AG, and unique recombinant forms were evaluated. Cell-free culture supernatant for each isolate was diluted to four levels and tested in the HIV Combo assay to determine a signal to cutoff ratio and the RealTime(®) HIV-1 assay to quantify RNA. The RNA copies/mL at the HIV Combo assay cutoff was determined. RESULTS: The median RNA copies/mL at the HIV Combo assay cutoff was 57,900 for individual virus isolates (range 26,440-102,400). A single plot of all the data gave a value of 58,500RNA copies/mL. An analysis of data published for acute HIV infection in human subjects gave a similar result; HIV Combo detected 97% of AHIs with RNA copies/mL > 30,700. CONCLUSIONS: Based on analysis of virus isolates, the ARCHITECT HIV Combo assay can detect p24 Ag when RNA is above approximately 58,000copies/mL. The correlation of viral load and Ag sensitivity was consistent across genetically diverse HIV-1 group M strains.

Partially double-stranded linear DNA probes: novel design for sensitive detection of genetically polymorphic targets.

Genetically polymorphic targets present a significant challenge to the reliability of detection and quantification by nucleic acid-based assays. A probe system with enhanced mismatch tolerance would be advantageous for such applications. The present study introduces a novel class of DNA probes, designated as partially double-stranded linear probes, composed of a long target-specific strand 5' labeled with a fluorophore and a markedly shorter quencher strand, complementary to the 5' end of the target-specific strand, that is 3' end-labeled with a quencher moiety. The utility of this probe system for sensitive detection of amplification products was demonstrated in a real-time PCR format. Comparison of multiple partially double-stranded linear probe combinations revealed that increased asymmetry in strand length was associated with improved mismatch tolerance. Notably, for a 45-mer/11-mer combination, the difference in threshold cycle values obtained for a perfectly matched target and one containing six mismatches was <1.5 cycles. The capacity for superior mismatch tolerance, ease of design, simplicity and flexibility of application are characteristics that make this new class of probes a desirable alternative for homogeneous detection of targets with a high level of genetic heterogeneity.