Validation of a Circulating Tumor DNA-Based Next-Generation Sequencing Assay in a Cohort of Patients with Solid Tumors: A Proposed Solution for Decentralized Plasma Testing

Overview

Journal Oncologist

Publisher Oxford University Press

Specialty Oncology

Date 2021 Jul 21

PMID 34286887

Citations 10

Authors

Wael Al Zoughbi

Jesse Fox

Shaham Beg

Eniko Papp

Erika Hissong

Kentaro Ohara

Laurel Keefer

Michael Sigouros

Troy Kane

Daniel Bockelman

Donna Nichol

Emily Patchell

Rohan Bareja

Aanavi Karandikar

Hussein Alnajar

Gustavo Cerqueira

Violeta Beleva Guthrie

Ellen Verner

Jyothi Manohar

Noah Greco

David Wilkes

Scott Tagawa

Murtaza S Malbari

Kevin Holcomb

Kenneth Wha Eng

Manish Shah

Nasser K Altorki

Andrea Sboner

David Nanus

Bishoy Faltas

Cora N Sternberg

John Simmons

Yariv Houvras

Ana M Molina

Samuel Angiuoli

Olivier Elemento

Juan Miguel Mosquera

Affiliations

Soon will be listed here.

Abstract

Background: Characterization of circulating tumor DNA (ctDNA) has been integrated into clinical practice. Although labs have standardized validation procedures to develop single locus tests, the efficacy of on-site plasma-based next-generation sequencing (NGS) assays still needs to be proved.

Materials And Methods: In this retrospective study, we profiled DNA from matched tissue and plasma samples from 75 patients with cancer. We applied an NGS test that detects clinically relevant alterations in 33 genes and microsatellite instability (MSI) to analyze plasma cell-free DNA (cfDNA).

Results: The concordance between alterations detected in both tissue and plasma samples was higher in patients with metastatic disease. The NGS test detected 77% of sequence alterations, amplifications, and fusions that were found in metastatic samples compared with 45% of those alterations found in the primary tumor samples (p = .00005). There was 87% agreement on MSI status between the NGS test and tumor tissue results. In three patients, MSI-high ctDNA correlated with response to immunotherapy. In addition, the NGS test revealed an FGFR2 amplification that was not detected in tumor tissue from a patient with metastatic gastric cancer, emphasizing the importance of profiling plasma samples in patients with advanced cancer.

Conclusion: Our validation experience of a plasma-based NGS assay advances current knowledge about translating cfDNA testing into clinical practice and supports the application of plasma assays in the management of oncology patients with metastatic disease. With an in-house method that minimizes the need for invasive procedures, on-site cfDNA testing supplements tissue biopsy to guide precision therapy and is entitled to become a routine practice.

Implications For Practice: This study proposes a solution for decentralized liquid biopsy testing based on validation of a next-generation sequencing (NGS) test that detects four classes of genomic alterations in blood: sequence mutations (single nucleotide substitutions or insertions and deletions), fusions, amplifications, and microsatellite instability (MSI). Although there are reference labs that perform single-site comprehensive liquid biopsy testing, the targeted assay this study validated can be established locally in any lab with capacity to offer clinical molecular pathology assays. To the authors' knowledge, this is the first report that validates evaluating an on-site plasma-based NGS test that detects the MSI status along with common sequence alterations encountered in solid tumors.

Citing Articles

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Baseline ctDNA gene alterations as a biomarker of survival after panitumumab and chemotherapy in metastatic colorectal cancer.

Shitara K, Muro K, Watanabe J, Yamazaki K, Ohori H, Shiozawa M Nat Med. 2024; 30(3):730-739.

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A unified DNA- and RNA-based NGS strategy for the analysis of multiple types of variants at the dual nucleic acid level in solid tumors.

Chen H, Wang B, Zhang Y, Shu Y, Dong H, Zhao Q J Clin Lab Anal. 2023; 37(19-20):e24977.

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Cell-free DNA approaches for cancer early detection and interception.

Medina J, Dracopoli N, Bach P, Lau A, Scharpf R, Meijer G J Immunother Cancer. 2023; 11(9).

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