Timely and accurate detection of Philadelphia chromosome–like acute lymphoblastic leukemia (Ph-like ALL)-related fusion gene is essential for treatment decisions. However, due to the complexity of possible gene fusion combinations of Ph-like ALL, current diagnostic workflows face critical limitations: prolonged turnaround (7–14 days), high costs, and deficiency in degraded specimens. In this study, we introduce Partial Anchored Capture and Long-Read Sequencing (PACLseq), a nanopore-sequencing-technology-based approach. We designed a detection panel associated with Ph-like ALL, specifically ABL2, CSF1R, PDGFRB, JAK2, ABL1, EPOR, and CRLF2 as target genes. Validated on 47 clinical samples, PACLseq achieved 93.3% sensitivity and 100% specificity in 26 degraded RNA samples (RIN > 3). Crucially, PACLseq maintained detection accuracy in nine low-RIN samples (RIN ≤ 3) with fragmented transcripts. The method requires only 10 ng of RNA input, delivers results in 3 days (vs. 7–14 days for conventional methods), and reduces costs by 50%. By offering rapid and accurate fusion detection, PACLseq has the potential to significantly improve diagnostic efficiency, facilitate timely treatment decisions, and enhance patient outcomes in the management of Ph-like ALL.
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