AI Article Synopsis

  • The study investigates the use of cell-free DNA (cfDNA) from cerebrospinal fluid (CSF) as a less invasive alternative to brain biopsies for diagnosing brain tumors and addressing tumor heterogeneity.
  • A total of 33 CSF samples were collected from 30 patients, and shallow whole-genome sequencing was performed, revealing significant somatic copy number aberrations (SCNAs) in brain tumor patients' cfDNA.
  • The findings suggest that cfDNA analysis can effectively identify relevant genomic alterations, offering insights into tumor evolution and heterogeneity, thus enhancing diagnostic accuracy for CNS cancers.

Article Abstract

The gold standard for precise diagnostic classification of brain tumors requires tissue sampling, which carries relevant procedural risks. Brain biopsies often have limited sensitivity and fail to address tumor heterogeneity, because small tissue parts are being examined. This study aims to explore the detection and quantification of diagnostically relevant somatic copy number aberrations (SCNAs) in cell-free DNA (cfDNA) extracted from cerebrospinal fluid (CSF) in a real-world cohort of patients with defined brain tumor subtypes. A total of 33 CSF samples were collected from 30 patients for cfDNA extraction. Shallow whole-genome sequencing was conducted on CSF samples containing > 3ng of cfDNA and corresponding tissue DNA from nine patients. The sequencing cohort encompassed 26 samples of 23 patients, comprising 12 with confirmed CNS cancer as compared to 11 patients with either ambiguous CNS lesions (n = 5) or non-cancer CNS lesions (n = 6). After mapping and quality filtering SCNAs were called by depth-of-coverage analyses with a binning of 5.5 Mbp. SCNAs were exclusively identified in CSF cfDNA from brain tumor patients (10/12, 83%). In tumor patients, SCNAs were detectable in cfDNA from all patients with, but also in five of seven patients without tumor cells detected by CSF cytopathology. A substantial number of shared SCNAs were traceable between tissue and CSF in matched pair analyses. Additionally, some SCNAs unique to either CSF or tissue indicating spatial heterogeneity or tumor evolution. Also, diagnostically relevant genomic alterations as well as essential and desirable SCNAs as implemented in the current WHO classification of CNS tumors for certain primary brain tumor subtypes were traceable. In summary, this minimally invasive cfDNA-based LB approach employing shallow whole genome sequencing demonstrates potential for providing a molecularly informed diagnosis of CNS cancers, mapping tumor heterogeneity, tracking tumor evolution, and surveilling tumor patients. Further prospective trials are warranted.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11580493PMC
http://dx.doi.org/10.1186/s40478-024-01887-9DOI Listing

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