Diagnostic accuracy of a novel SARS CoV-2 rapid antigen test and usefulness of specimens collected from the anterior nasal cavity.

OBJECTIVES: We aimed to validate a newly developed antigen-detecting rapid diagnostic test (Ag-RDT) for SARS-CoV-2 using anterior nasal specimens. METHODS: Between February 12 and September 30, 2021, 16 patients (age range, <1 month-76 years) were enrolled, and samples were collected simultaneously from anterior nasal and nasopharyngeal sites continuously during hospitalization. The primary end points were the diagnostic accuracy of the Ag-RDT and utility of anterior nasal specimens. RESULTS: In total, 226 sets of paired samples were obtained. In 88.2% of specimens, the viral load was high at the nasopharyngeal site. The mean cycle threshold values for the anterior nasal and nasopharyngeal sites were 32.4 and 29.9, respectively. Using the real-time polymerase chain reaction results as a reference, the Ag-RDT showed a 100% sensitivity up to day 6 of the illness, using specimens with moderate or high viral load (cycle threshold <30) from either site. From day 7, the sensitivity was 70.4-90.6% and 83.9-84.6% for the anterior nasal and nasopharyngeal sites, respectively. The specificity remained at 100%. CONCLUSION: Our novel Ag-RDT meets the World Health Organization criteria and provides stable sensitivity and specificity and accurate results with anterior nasal specimens.

TTF-2 stimulates expression of 17 genes, including one novel thyroid-specific gene which might be involved in thyroid development.

Thyroid dysgenesis is the most frequent cause of congenital hypothyroidism, but its molecular pathophysiology is largely unknown. Our hypothesis that some genes downstream to thyroid transcription factor-2 (TTF-2) might be responsible for development of the thyroid prompted us to identify genes whose expression is stimulated by TTF-2. PCR products of cDNA clones obtained by a subtraction PCR method in TTF-2 expressing cell lines were screened with labeled cDNA by microarray analysis. We isolated 17 genes up-regulated by TTF-2, which were subsequently confirmed by quantitative reverse transcription-polymerase chain reaction (RT-PCR). One of them is a novel gene designated T1560 that showed a highly thyroid-specific expression pattern. Luciferase reporter assays showed that expression of all of the 14 genes tested was stimulated by both TTF-2 and TTF-1, another thyroid-specific transcription factor. Our results have important implications for understanding normal thyroid development as well as the molecular defects underlying thyroid dysgenesis.