A pilot study of on-site evaluation as external quality assessment for ISO 15189 accreditation of laboratories performing next-generation sequencing oncology tests.

BACKGROUND: As next-generation sequencing (NGS) oncology tests vary by platform, application, and target of genes, specific methods for external quality assessment (EQA) have not been universally applied. Hence, we have attempted to implement on-site evaluation as EQA in the accreditation program under ISO 15189 for laboratories that perform NGS oncology tests. METHODS: A total of 10 laboratories that performed NGS oncology tests were enrolled. Two types of EQA samples were prepared (Acrometrix Oncology Hotspot Control DNA and OncoSpan gDNA DNA samples), and the variant allele frequency of targeted genes was assigned. The samples were subjected to NGS oncology tests in participant laboratories according to their routine protocols. Based on the result reports, auditors visited the participant laboratories to perform on-site evaluations and provided feedback regarding possible laboratory process improvement. RESULTS: The participant laboratories identified the targeted variants in the Acrometrix Oncology Hotspot Control DNA and OncoSpan gDNA samples with a success rate of 31-100% and 9.5-100%, respectively, compared with reference information, depending on their sequencing systems, and reported a few lower-variant allele frequencies. Six of the eight evaluated laboratories failed to report at least three pathogenic variants due to errors in wet-lab and/or dry-lab processes. Based on the feedback reports and self-assessment, auditors and laboratory staff discussed potential improvements to processes during on-site evaluations for laboratory accreditations. CONCLUSIONS: On-site evaluation as EQA for NGS oncology tests in the laboratory accreditation program under ISO 15189 was successfully implemented and proved applicable to a broad spectrum of NGS tests.

A Local Community Outreach Educational Program on Genetic Testing: A Pilot Study.

OBJECTIVE: To develop and implement a pilot educational program on genetic testing at the Tokai University School of Medicine with a public engagement approach through a local junior-high school outreach program. METHODS: Seven medical students underwent 2 weeks of education and training to act as instructors for a one-day course on genetic testing for local junior-high school students. The one-day course comprised a lecture and an experimental lesson. The variation of UDP-glucuronosyltransferase 1A1 gene (UGT1A1) was selected as the teaching topic. A commercially available cultured human leukemia cell line was used as the source of human genomic DNA to circumvent the ethical concerns associated with obtaining samples from participants for genomic analysis. The medical students received instructions on the basics of conducting laboratory work and handling the equipment and reagents during the 2-week training. RESULTS: The seven medical students completed the 2-week training. They then taught PCR and restriction enzyme experiments and the meaning of the results to junior-high school students. CONCLUSION: A pilot educational program on genetic testing with a local community outreach approach was successfully developed and implemented.

Electrical biosensing system utilizing ion-producing enzymes conjugated with aptamers for the sensing of severe acute respiratory syndrome coronavirus 2.

Viral outbreaks, which include the ongoing coronavirus disease 2019 (COVID-19) pandemic provoked by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), are a major global crisis that enormously threaten human health and social activities worldwide. Consequently, the rapid and repeated treatment and isolation of these viruses to control their spread are crucial to address the COVID-19 pandemic and future epidemics of novel emerging viruses. The application of cost-efficient, rapid, and easy-to-operate detection devices with miniaturized footprints as a substitute for the conventional optic-based polymerase chain reaction (PCR) and immunoassay tests is critical. In this context, semiconductor-based electrical biosensors are attractive sensing platforms for signal readout. Therefore, this study aimed to examine the electrical sensing of patient-derived SARS-CoV-2 samples by harnessing the activity of DNA aptamers directed against spike proteins on viral surfaces. We obtained rapid and sensitive virus detection beyond the Debye length limitation by exploiting aptamers coupled with alkaline phosphatases, which catalytically generate free hydrogen ions which can readily be measured on pH meters or ion-sensitive field-effect transistors. Furthermore, we demonstrated the detection of the viruses of approximately 100 copies/µL in 10 min, surpassing the capability of typical immunochromatographic assays. Therefore, our newly developed technology has great potential for point-of-care testing not only for SARS-CoV-2, but also for other types of pathogens and biomolecules.