Standardization of next-generation sequencing for detecting mutations associated with targeted therapy and immunotherapy based on dynamic pattern of expandable detection range

Abstract

Next-generation sequencing (NGS) has laid the foundation for precision oncology care. NGS technologynot only represents an innovation in the methodology but also brings about a revolution in the concept of detecting gene alterations for targeted therapy and immunotherapy of cancers. As basic biomedical research and drug development progress, the landscape of biomarkers associated with gene alterations continues to evolve. Thus, the standardization of NGS-based gene alterations detection should take into account the characteristics of NGS methods and the gene alteration biomarkers. To be specific, whether employed as in vitro diagnostic products or laboratory-developed tests, the detection range can be expanded in response to changes in the clinical evidence level of biomarkers during the process of assay development and clinical application. Such adjustment needs the analytical validation results for supplemented genes or mutant sites within a predefined detection system, which will maximally fulfill the evolving clinical demands in cancer diagnosis and treatment, simultaneously mitigate potential risks effectively. This article primarily discusses the standardization pathway for NGS testing of gene alterations in cancer by focusing on the characteristics of NGS methods, gene alteration biomarkers, and the current status of the standardization of NGS application.