P14.07.B CELL-FREE DNA IN LONGITUDINALLY-ACQUIRED CEREBROSPINAL FLUID FOR DISEASE MONITORING

Abstract BACKGROUND Few methods exist via which to assess treatment response with high fidelity in gliomas. Cell-free DNA (cfDNA) is of growing interest as a liquid biomarker in plasma and CSF and has been used in other cancer types to optimize therapeutic regimens for individual patients. While CSF...

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Published in:Neuro-oncology (Charlottesville, Va.) Va.), 2023-09, Vol.25 (Supplement_2), p.ii106-ii107
Main Authors: Riviere-Cazaux, C, Mo, W, Dong, X, Luo, S, Wang, A, Du, P, Ghadimi, K, Warrington, A, Burns, T
Format: Article
Language:English
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Summary:Abstract BACKGROUND Few methods exist via which to assess treatment response with high fidelity in gliomas. Cell-free DNA (cfDNA) is of growing interest as a liquid biomarker in plasma and CSF and has been used in other cancer types to optimize therapeutic regimens for individual patients. While CSF has previously been used as a source of cfDNA for gliomas, it remains unknown how cfDNA abundance and sequencing change throughout treatment and inevitable recurrence. To that end, we leveraged our growing biobank of longitudinal CSF specimens, acquired via CSF access devices, to determine the potential utility of CSF cfDNA as a monitoring tool for treatment response in patients with gliomas. MATERIAL AND METHODS Longitudinal CSF specimens were acquired via Ommaya reservoirs (NCT04692337) or ventriculoperitoneal shunts (NCT04692324) in patients with brain tumors, including gliomas. cfDNA was extracted from 1-5 mL of CSF based on available sample volumes and quantified via Qubit. Next-Generation sequencing (PredicineCARE) or low-pass whole genome sequencing (LPWGS) was performed by Predicine, Inc based on the amount of cfDNA available. RESULTS CSF acquired prior to versus after resection demonstrated an increase in quantified cfDNA (2.97x, range: 1.58-5.26x), consistent with the impact of increased parenchymal disruption and closer contact with CSF. Thereafter, CSF cfDNA continued to decrease throughout chemoradiation and adjuvant treatment and increased at recurrence, including in patients co-enrolled in immunotherapy trials for IL-7 agonists and pembrolizumab. Interestingly, copy number burden (CNB) increased by the time of recurrence in three patients with known disease progression, and continued to decrease throughout immunotherapy treatment in one patient despite concerns of pseudoprogression. In one patient with a hypermutated glioblastoma, CSF cfDNA revealed over 59 genomic alterations, including MAP2K1, KIT, and PDGFRA, and over 100 more variants of unknown significance, each of which had been detected in sequencing of the tissue acquired at resection and subsequently decreased with chemoradiation. In another patient with a known progressing EGFR-amplified GBM, over 200 new variants were identified by the patient’s final sample and EGFR copy number increased from 2 to over 30. CONCLUSION Analysis of cfDNA over a patient’s disease course, including resection and treatment with standard-of-care and experimental therapies, may be of use for disease monitori
ISSN:1522-8517
1523-5866
DOI:10.1093/neuonc/noad137.358