Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases

BACKGROUND: Circulating cell‐free tumor DNA (ctDNA)‐based mutation profiling, if sufficiently sensitive and comprehensive, can efficiently identify genomic targets in advanced lung adenocarcinoma. Therefore, the authors investigated the accuracy and clinical utility of a commercially available digit...

Descripción completa

Detalles Bibliográficos
Autores principales: Mack, Philip C., Banks, Kimberly C., Espenschied, Carin R., Burich, Rebekah A., Zill, Oliver A., Lee, Christine E., Riess, Jonathan W., Mortimer, Stefanie A., Talasaz, AmirAli, Lanman, Richard B., Gandara, David R.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2020
Materias:
Original Articles
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7383626/
https://www.ncbi.nlm.nih.gov/pubmed/32365229
http://dx.doi.org/10.1002/cncr.32876
_version_ 1783563458286977024
author Mack, Philip C.
Banks, Kimberly C.
Espenschied, Carin R.
Burich, Rebekah A.
Zill, Oliver A.
Lee, Christine E.
Riess, Jonathan W.
Mortimer, Stefanie A.
Talasaz, AmirAli
Lanman, Richard B.
Gandara, David R.
author_facet Mack, Philip C.
Banks, Kimberly C.
Espenschied, Carin R.
Burich, Rebekah A.
Zill, Oliver A.
Lee, Christine E.
Riess, Jonathan W.
Mortimer, Stefanie A.
Talasaz, AmirAli
Lanman, Richard B.
Gandara, David R.
author_sort Mack, Philip C.
collection PubMed
description BACKGROUND: Circulating cell‐free tumor DNA (ctDNA)‐based mutation profiling, if sufficiently sensitive and comprehensive, can efficiently identify genomic targets in advanced lung adenocarcinoma. Therefore, the authors investigated the accuracy and clinical utility of a commercially available digital next‐generation sequencing platform in a large series of patients with non–small cell lung cancer (NSCLC). METHODS: Plasma‐based comprehensive genomic profiling results from 8388 consecutively tested patients with advanced NSCLC were analyzed. Driver and resistance mutations were examined with regard to their distribution, frequency, co‐occurrence, and mutual exclusivity. RESULTS: Somatic alterations were detected in 86% of samples. The median variant allele fraction was 0.43% (range, 0.03%‐97.62%). Activating alterations in actionable oncogenes were identified in 48% of patients, including EGFR (26.4%), MET (6.1%), and BRAF (2.8%) alterations and fusions (ALK, RET, and ROS1) in 2.3%. Treatment‐induced resistance mutations were common in this cohort, including driver‐dependent and driver‐independent alterations. In the subset of patients who had progressive disease during EGFR therapy, 64% had known or putative resistance alterations detected in plasma. Subset analysis revealed that ctDNA increased the identification of driver mutations by 65% over standard‐of‐care, tissue‐based testing at diagnosis. A pooled data analysis on this plasma‐based assay demonstrated that targeted therapy response rates were equivalent to those reported from tissue analysis. CONCLUSIONS: Comprehensive ctDNA analysis detected the presence of therapeutically targetable driver and resistance mutations at the frequencies and distributions predicted for the study population. These findings add support for comprehensive ctDNA testing in patients who are incompletely tested at the time of diagnosis and as a primary option at the time of progression on targeted therapies.
format Online
Article
Text
id pubmed-7383626
institution National Center for Biotechnology Information
language English
publishDate 2020
publisher John Wiley and Sons Inc.
record_format MEDLINE/PubMed
spelling pubmed-73836262020-07-27 Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases Mack, Philip C. Banks, Kimberly C. Espenschied, Carin R. Burich, Rebekah A. Zill, Oliver A. Lee, Christine E. Riess, Jonathan W. Mortimer, Stefanie A. Talasaz, AmirAli Lanman, Richard B. Gandara, David R. Cancer Original Articles BACKGROUND: Circulating cell‐free tumor DNA (ctDNA)‐based mutation profiling, if sufficiently sensitive and comprehensive, can efficiently identify genomic targets in advanced lung adenocarcinoma. Therefore, the authors investigated the accuracy and clinical utility of a commercially available digital next‐generation sequencing platform in a large series of patients with non–small cell lung cancer (NSCLC). METHODS: Plasma‐based comprehensive genomic profiling results from 8388 consecutively tested patients with advanced NSCLC were analyzed. Driver and resistance mutations were examined with regard to their distribution, frequency, co‐occurrence, and mutual exclusivity. RESULTS: Somatic alterations were detected in 86% of samples. The median variant allele fraction was 0.43% (range, 0.03%‐97.62%). Activating alterations in actionable oncogenes were identified in 48% of patients, including EGFR (26.4%), MET (6.1%), and BRAF (2.8%) alterations and fusions (ALK, RET, and ROS1) in 2.3%. Treatment‐induced resistance mutations were common in this cohort, including driver‐dependent and driver‐independent alterations. In the subset of patients who had progressive disease during EGFR therapy, 64% had known or putative resistance alterations detected in plasma. Subset analysis revealed that ctDNA increased the identification of driver mutations by 65% over standard‐of‐care, tissue‐based testing at diagnosis. A pooled data analysis on this plasma‐based assay demonstrated that targeted therapy response rates were equivalent to those reported from tissue analysis. CONCLUSIONS: Comprehensive ctDNA analysis detected the presence of therapeutically targetable driver and resistance mutations at the frequencies and distributions predicted for the study population. These findings add support for comprehensive ctDNA testing in patients who are incompletely tested at the time of diagnosis and as a primary option at the time of progression on targeted therapies. John Wiley and Sons Inc. 2020-05-04 2020-07-15 /pmc/articles/PMC7383626/ /pubmed/32365229 http://dx.doi.org/10.1002/cncr.32876 Text en © 2020 The Authors. Cancer published by Wiley Periodicals LLC on behalf of American Cancer Society This is an open access article under the terms of the http://creativecommons.org/licenses/by-nc-nd/4.0/ License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non‐commercial and no modifications or adaptations are made.
spellingShingle Original Articles
Mack, Philip C.
Banks, Kimberly C.
Espenschied, Carin R.
Burich, Rebekah A.
Zill, Oliver A.
Lee, Christine E.
Riess, Jonathan W.
Mortimer, Stefanie A.
Talasaz, AmirAli
Lanman, Richard B.
Gandara, David R.
Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases
title Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases
title_full Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases
title_fullStr Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases
title_full_unstemmed Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases
title_short Spectrum of driver mutations and clinical impact of circulating tumor DNA analysis in non–small cell lung cancer: Analysis of over 8000 cases
title_sort spectrum of driver mutations and clinical impact of circulating tumor dna analysis in non–small cell lung cancer: analysis of over 8000 cases
topic Original Articles
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7383626/
https://www.ncbi.nlm.nih.gov/pubmed/32365229
http://dx.doi.org/10.1002/cncr.32876
work_keys_str_mv AT mackphilipc spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT bankskimberlyc spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT espenschiedcarinr spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT burichrebekaha spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT zillolivera spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT leechristinee spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT riessjonathanw spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT mortimerstefaniea spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT talasazamirali spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT lanmanrichardb spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases
AT gandaradavidr spectrumofdrivermutationsandclinicalimpactofcirculatingtumordnaanalysisinnonsmallcelllungcanceranalysisofover8000cases

Ejemplares similares