Abstract 1136: Analytical evaluation of a whole genome tumor-informed molecular residual disease detection assay with high sensitivity and specificity

Abstract Introduction: Molecular residual disease (MRD) testing involves the detection of circulating tumor DNA (ctDNA) in plasma after cancer treatment. Tumor-informed Whole Genome Sequencing (WGS) workflows for the qualitative detection of MRD have been shown to be highly sensitive. We present an automated and scalable solution for patients with bladder, breast, melanoma, non-small cell lung (NSCLC), and colorectal (CRC) cancers with turnaround as fast as 8 to 9 days. This includes automation of DNA extraction, library preparation, sequencing, data analyses, and reporting. Here, we summarize the analytical performance of a research use only workflow intended as a service for research and clinical partners, such as pharmaceutical companies. Methods: The workflow requires 3 different sample types: formalin-fixed, paraffin-embedded (FFPE), Buffy Coat, and 2 to 4ml plasma aliquots. The optimal inputs are: i) 5ng (minimum 2ng) cell-free DNA (cfDNA) from plasma, ii) 100ng (minimum 50ng) tumor tissue DNA, and iii) 50ng DNA from Buffy Coat. DNA is extracted from different sample types with WGS libraries preparation and sequencing on NovaSeqTM 6000. Sequencing analyses, fingerprint generation, and MRD detection are performed using DRAGENTM. The assay uses a patient’s tumor and germline sample to generate a patient-specific somatic variant list, i.e. fingerprint. Subsequently, the cfDNA sequence data is evaluated against the fingerprint to determine the presence or absence of tumor DNA indicative of MRD. Both clinical and contrived samples were used to evaluate accuracy, analytical sensitivity, analytical specificity and precision. Results: Twenty-five clinical samples (5 samples for each cancer type) resulted in 100% overall percent agreement (OPA) in MRD status relative to a reference method, with ctDNA concentration as low as 0.035%. A panel of 20 healthy plasma samples assessed against 25 fingerprints across multiple cancer types resulted in a 100% negative percent agreement. Sensitivity analysis demonstrated 100% detection rate at variant allele frequency of 0.003% for NSCLC, 0.005% for bladder and CRC, and 0.006% for melanoma and breast samples. Precision was evaluated using all specimen types across multiple operators, instruments, and library preparation start days. There was 100% OPA in MRD status across intra-run and inter-run replicates at ctDNA concentrations of 0.009% to 0.018%. Conclusions: We present a whole genome fully automated workflow capable of generating tumor- informed MRD status with high analytical sensitivity and specificity. The assay requires low DNA input from plasma samples and enables a sample-to-report turnaround time as fast as 8 to 9 days. The results demonstrate that the WGS MRD detection platform is a scalable, robust, and highly sensitive assay for multiple cancer types. Citation Format: Weida Gong, Sung Kim, Guidantonio Malagoli Tagliazucchi, Tevfik Umut Dincer, Megha Ghildiyal, Magdalena Gantuz, Grace Kim, Quyen Bui, Yuan Ding, Jacob Gibson, Leland Mencik, Ambrose Vuong, Marcus Valancius, Kimberly Gietzen, Jennifer Becq, Carey Davis, Josh Bernd, Martin Chian, Dan Schmidt, Eileen de Feo. Analytical evaluation of a whole genome tumor-informed molecular residual disease detection assay with high sensitivity and specificity abstract. In: Proceedings of the American Association for Cancer Research Annual Meeting 2026; Part 1 (Regular Abstracts); 2026 Apr 17-22; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2026;86(7 Suppl):Abstract nr 1136.