Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection

Peter J. Mazzone; Peter B. Bach; Jacob Carey; Caitlin A. Schonewolf; Katalin Bognar; Manmeet S. Ahluwalia; Marcia Cruz-Correa; David Gierada; Sonali Kotagiri; Kathryn Lloyd; Fabien Maldonado; Jesse D. Ortendahl; Lecia V. Sequist; Gerard A. Silvestri; Nichole Tanner; Jeffrey C. Thompson; Anil Vachani; Kwok Kin Wong; Ali H. Zaidi; Joseph Catallini; Ariel Gershman; Keith Lumbard; Laurel K. Millberg; Jeff Nawrocki; Carter Portwood; Aakanksha Rangnekar; Carolina Campos Sheridan; Niti Trivedi; Tony Wu; Yuhua Zong; Lindsey Cotton; Allison Ryan; Christopher Cisar; Alessandro Leal; Nicholas Dracopoli; Robert B. Scharpf; Victor E. Velculescu; Luke R.G. Pike

doi:10.1158/2159-8290.CD-24-0519

Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection

Peter J. Mazzone, Peter B. Bach, Jacob Carey, Caitlin A. Schonewolf, Katalin Bognar, Manmeet S. Ahluwalia, Marcia Cruz-Correa, David Gierada, Sonali Kotagiri, Kathryn Lloyd, Fabien Maldonado, Jesse D. Ortendahl, Lecia V. Sequist, Gerard A. Silvestri, Nichole Tanner, Jeffrey C. Thompson, Anil Vachani, Kwok Kin Wong, Ali H. Zaidi, Joseph CatalliniAriel Gershman, Keith Lumbard, Laurel K. Millberg, Jeff Nawrocki, Carter Portwood, Aakanksha Rangnekar, Carolina Campos Sheridan, Niti Trivedi, Tony Wu, Yuhua Zong, Lindsey Cotton, Allison Ryan, Christopher Cisar, Alessandro Leal, Nicholas Dracopoli, Robert B. Scharpf, Victor E. Velculescu, Luke R.G. Pike

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12 Scopus citations

Abstract

Lung cancer screening via annual low-dose computed tomography has poor adoption. We conducted a prospective case-control study among 958 individuals eligible for lung cancer screening to develop a blood-based lung cancer detection test that when positive is followed by a low-dose computed tomography. Changes in genome-wide cell-free DNA fragmentation profiles (fragmentomes) in peripheral blood reflected genomic and chromatin characteristics of lung cancer. We applied machine learning to fragmentome features to identify individuals who were more or less likely to have lung cancer. We trained the classifier using 576 cases and controls from study samples and validated it in a held-out group of 382 cases and controls. The validation demonstrated high sensitivity for lung cancer and consistency across demographic groups and comorbid conditions. Applying test performance to the screening eligible population in a 5-year model with modest utilization assumptions suggested the potential to prevent thousands of lung cancer deaths. Significance: Lung cancer screening has poor adoption. Our study describes the development and validation of a novel blood-based lung cancer screening test utilizing a highly affordable, low-coverage genome-wide sequencing platform to analyze cell-free DNA fragmentation patterns. The test could improve lung cancer screening rates leading to substantial public health benefits. See related commentary by Haber and Skates, p. 2025.

Original language	English
Pages (from-to)	2224-2242
Number of pages	19
Journal	Cancer discovery
Volume	14
Issue number	11
DOIs	https://doi.org/10.1158/2159-8290.CD-24-0519
State	Published - Nov 1 2024

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10.1158/2159-8290.CD-24-0519

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Mazzone, P. J., Bach, P. B., Carey, J., Schonewolf, C. A., Bognar, K., Ahluwalia, M. S., Cruz-Correa, M., Gierada, D., Kotagiri, S., Lloyd, K., Maldonado, F., Ortendahl, J. D., Sequist, L. V., Silvestri, G. A., Tanner, N., Thompson, J. C., Vachani, A., Wong, K. K., Zaidi, A. H., ... Pike, L. R. G. (2024). Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection. Cancer discovery, 14(11), 2224-2242. https://doi.org/10.1158/2159-8290.CD-24-0519

@article{bbd03782496b4afc8e6ddbbcb9214212,

title = "Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection",

abstract = "Lung cancer screening via annual low-dose computed tomography has poor adoption. We conducted a prospective case-control study among 958 individuals eligible for lung cancer screening to develop a blood-based lung cancer detection test that when positive is followed by a low-dose computed tomography. Changes in genome-wide cell-free DNA fragmentation profiles (fragmentomes) in peripheral blood reflected genomic and chromatin characteristics of lung cancer. We applied machine learning to fragmentome features to identify individuals who were more or less likely to have lung cancer. We trained the classifier using 576 cases and controls from study samples and validated it in a held-out group of 382 cases and controls. The validation demonstrated high sensitivity for lung cancer and consistency across demographic groups and comorbid conditions. Applying test performance to the screening eligible population in a 5-year model with modest utilization assumptions suggested the potential to prevent thousands of lung cancer deaths. Significance: Lung cancer screening has poor adoption. Our study describes the development and validation of a novel blood-based lung cancer screening test utilizing a highly affordable, low-coverage genome-wide sequencing platform to analyze cell-free DNA fragmentation patterns. The test could improve lung cancer screening rates leading to substantial public health benefits. See related commentary by Haber and Skates, p. 2025.",

author = "Mazzone, {Peter J.} and Bach, {Peter B.} and Jacob Carey and Schonewolf, {Caitlin A.} and Katalin Bognar and Ahluwalia, {Manmeet S.} and Marcia Cruz-Correa and David Gierada and Sonali Kotagiri and Kathryn Lloyd and Fabien Maldonado and Ortendahl, {Jesse D.} and Sequist, {Lecia V.} and Silvestri, {Gerard A.} and Nichole Tanner and Thompson, {Jeffrey C.} and Anil Vachani and Wong, {Kwok Kin} and Zaidi, {Ali H.} and Joseph Catallini and Ariel Gershman and Keith Lumbard and Millberg, {Laurel K.} and Jeff Nawrocki and Carter Portwood and Aakanksha Rangnekar and Sheridan, {Carolina Campos} and Niti Trivedi and Tony Wu and Yuhua Zong and Lindsey Cotton and Allison Ryan and Christopher Cisar and Alessandro Leal and Nicholas Dracopoli and Scharpf, {Robert B.} and Velculescu, {Victor E.} and Pike, {Luke R.G.}",

note = "Publisher Copyright: {\textcopyright}2024 The Authors; Published by the American Association for Cancer Research.",

year = "2024",

month = nov,

day = "1",

doi = "10.1158/2159-8290.CD-24-0519",

language = "English",

volume = "14",

pages = "2224--2242",

journal = "Cancer discovery",

issn = "2159-8274",

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Mazzone, PJ, Bach, PB, Carey, J, Schonewolf, CA, Bognar, K, Ahluwalia, MS, Cruz-Correa, M, Gierada, D, Kotagiri, S, Lloyd, K, Maldonado, F, Ortendahl, JD, Sequist, LV, Silvestri, GA, Tanner, N, Thompson, JC, Vachani, A, Wong, KK, Zaidi, AH, Catallini, J, Gershman, A, Lumbard, K, Millberg, LK, Nawrocki, J, Portwood, C, Rangnekar, A, Sheridan, CC, Trivedi, N, Wu, T, Zong, Y, Cotton, L, Ryan, A, Cisar, C, Leal, A, Dracopoli, N, Scharpf, RB, Velculescu, VE & Pike, LRG 2024, 'Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection', Cancer discovery, vol. 14, no. 11, pp. 2224-2242. https://doi.org/10.1158/2159-8290.CD-24-0519

TY - JOUR

T1 - Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection

AU - Mazzone, Peter J.

AU - Bach, Peter B.

AU - Carey, Jacob

AU - Schonewolf, Caitlin A.

AU - Bognar, Katalin

AU - Ahluwalia, Manmeet S.

AU - Cruz-Correa, Marcia

AU - Gierada, David

AU - Kotagiri, Sonali

AU - Lloyd, Kathryn

AU - Maldonado, Fabien

AU - Ortendahl, Jesse D.

AU - Sequist, Lecia V.

AU - Silvestri, Gerard A.

AU - Tanner, Nichole

AU - Thompson, Jeffrey C.

AU - Vachani, Anil

AU - Wong, Kwok Kin

AU - Zaidi, Ali H.

AU - Catallini, Joseph

AU - Gershman, Ariel

AU - Lumbard, Keith

AU - Millberg, Laurel K.

AU - Nawrocki, Jeff

AU - Portwood, Carter

AU - Rangnekar, Aakanksha

AU - Sheridan, Carolina Campos

AU - Trivedi, Niti

AU - Wu, Tony

AU - Zong, Yuhua

AU - Cotton, Lindsey

AU - Ryan, Allison

AU - Cisar, Christopher

AU - Leal, Alessandro

AU - Dracopoli, Nicholas

AU - Scharpf, Robert B.

AU - Velculescu, Victor E.

AU - Pike, Luke R.G.

PY - 2024/11/1

Y1 - 2024/11/1

N2 - Lung cancer screening via annual low-dose computed tomography has poor adoption. We conducted a prospective case-control study among 958 individuals eligible for lung cancer screening to develop a blood-based lung cancer detection test that when positive is followed by a low-dose computed tomography. Changes in genome-wide cell-free DNA fragmentation profiles (fragmentomes) in peripheral blood reflected genomic and chromatin characteristics of lung cancer. We applied machine learning to fragmentome features to identify individuals who were more or less likely to have lung cancer. We trained the classifier using 576 cases and controls from study samples and validated it in a held-out group of 382 cases and controls. The validation demonstrated high sensitivity for lung cancer and consistency across demographic groups and comorbid conditions. Applying test performance to the screening eligible population in a 5-year model with modest utilization assumptions suggested the potential to prevent thousands of lung cancer deaths. Significance: Lung cancer screening has poor adoption. Our study describes the development and validation of a novel blood-based lung cancer screening test utilizing a highly affordable, low-coverage genome-wide sequencing platform to analyze cell-free DNA fragmentation patterns. The test could improve lung cancer screening rates leading to substantial public health benefits. See related commentary by Haber and Skates, p. 2025.

AB - Lung cancer screening via annual low-dose computed tomography has poor adoption. We conducted a prospective case-control study among 958 individuals eligible for lung cancer screening to develop a blood-based lung cancer detection test that when positive is followed by a low-dose computed tomography. Changes in genome-wide cell-free DNA fragmentation profiles (fragmentomes) in peripheral blood reflected genomic and chromatin characteristics of lung cancer. We applied machine learning to fragmentome features to identify individuals who were more or less likely to have lung cancer. We trained the classifier using 576 cases and controls from study samples and validated it in a held-out group of 382 cases and controls. The validation demonstrated high sensitivity for lung cancer and consistency across demographic groups and comorbid conditions. Applying test performance to the screening eligible population in a 5-year model with modest utilization assumptions suggested the potential to prevent thousands of lung cancer deaths. Significance: Lung cancer screening has poor adoption. Our study describes the development and validation of a novel blood-based lung cancer screening test utilizing a highly affordable, low-coverage genome-wide sequencing platform to analyze cell-free DNA fragmentation patterns. The test could improve lung cancer screening rates leading to substantial public health benefits. See related commentary by Haber and Skates, p. 2025.

UR - http://www.scopus.com/inward/record.url?scp=85202670542&partnerID=8YFLogxK

U2 - 10.1158/2159-8290.CD-24-0519

DO - 10.1158/2159-8290.CD-24-0519

M3 - Article

C2 - 38829053

AN - SCOPUS:85202670542

SN - 2159-8274

VL - 14

SP - 2224

EP - 2242

JO - Cancer discovery

JF - Cancer discovery

IS - 11

ER -

Clinical Validation of a Cell-Free DNA Fragmentome Assay for Augmentation of Lung Cancer Early Detection

Abstract

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