ONT in Clinical Diagnostics of Repeat Expansion Disorders: Detection and Reporting Challenges.

While whole-genome sequencing (WGS) using short-read technology has become a standard diagnostic test, this technology has limitations in analyzing certain genomic regions, particularly short tandem repeats (STRs). These repetitive sequences are associated with over 50 diseases, primarily affecting neurological function, including Huntington disease, frontotemporal dementia, and Friedreich's ataxia. We analyzed 2689 cases with movement disorders and dementia-related phenotypes processed at Variantyx in 2023-2024 using a two-tiered approach, with an initial short-read WGS followed by ONT long-read sequencing (when necessary) for variant characterization. Of the 2038 cases (75.8%) with clinically relevant genetic variants, 327 (16.0%) required additional long-read analysis. STR variants were reported in 338 cases (16.6% of positive cases), with approximately half requiring long-read sequencing for definitive classification. The combined approach enabled the precise determination of repeat length, composition, somatic mosaicism, and methylation status. Notable advantages included the detection of complex repeat structures in several genes such as RFC1, FGF14, and FXN, where long-read sequencing allowed to determine somatic repeat unit variations and accurate allele phasing. Further studies are needed to establish technology-specific guidelines for the standardized interpretation of long-read sequencing data for the clinical diagnostics of repeat expansion disorders.