Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment

Adam J. Widman; Minita Shah; Amanda Frydendahl; Daniel Halmos; Cole C. Khamnei; Nadia Øgaard; Srinivas Rajagopalan; Anushri Arora; Aditya Deshpande; William F. Hooper; Jean Quentin; Jake Bass; Mingxuan Zhang; Theophile Langanay; Laura Andersen; Zoe Steinsnyder; Will Liao; Mads Heilskov Rasmussen; Tenna Vesterman Henriksen; Sarah Østrup Jensen; Jesper Nors; Christina Therkildsen; Jesus Sotelo; Ryan Brand; Joshua S. Schiffman; Ronak H. Shah; Alexandre Pellan Cheng; Colleen Maher; Lavinia Spain; Kate Krause; Dennie T. Frederick; Wendie den Brok; Caroline Lohrisch; Tamara Shenkier; Christine Simmons; Diego Villa; Andrew J. Mungall; Richard Moore; Elena Zaikova; Viviana Cerda; Esther Kong; Daniel Lai; Murtaza S. Malbari; Melissa Marton; Dina Manaa; Lara Winterkorn; Karen Gelmon; Margaret K. Callahan; Genevieve Boland; Catherine Potenski; Jedd D. Wolchok; Ashish Saxena; Samra Turajlic; Marcin Imielinski; Michael F. Berger; Sam Aparicio; Nasser K. Altorki; Michael A. Postow; Nicolas Robine; Claus Lindbjerg Andersen; Dan A. Landau

doi:10.1038/s41591-024-03040-4

Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment

Adam J. Widman
, Minita Shah
, Amanda Frydendahl
, Daniel Halmos
, Cole C. Khamnei
, Nadia Øgaard
, Srinivas Rajagopalan
, Anushri Arora
, Aditya Deshpande
, William F. Hooper
, Jean Quentin
, Jake Bass
, Mingxuan Zhang
, Theophile Langanay
, Laura Andersen
, Zoe Steinsnyder
, Will Liao
, Mads Heilskov Rasmussen
, Tenna Vesterman Henriksen
, Sarah Østrup Jensen

Jesper Nors, Christina Therkildsen, Jesus Sotelo, Ryan Brand, Joshua S. Schiffman, Ronak H. Shah, Alexandre Pellan Cheng, Colleen Maher, Lavinia Spain, Kate Krause, Dennie T. Frederick, Wendie den Brok, Caroline Lohrisch, Tamara Shenkier, Christine Simmons, Diego Villa, Andrew J. Mungall, Richard Moore, Elena Zaikova, Viviana Cerda, Esther Kong, Daniel Lai, Murtaza S. Malbari, Melissa Marton, Dina Manaa, Lara Winterkorn, Karen Gelmon, Margaret K. Callahan, Genevieve Boland, Catherine Potenski, Jedd D. Wolchok, Ashish Saxena, Samra Turajlic, Marcin Imielinski, Michael F. Berger, Sam Aparicio, Nasser K. Altorki, Michael A. Postow, Nicolas Robine, Claus Lindbjerg Andersen, Dan A. Landau

Research output: Contribution to journal › Journal Article › peer-review

65 Citations (Scopus)

Abstract

In solid tumor oncology, circulating tumor DNA (ctDNA) is poised to transform care through accurate assessment of minimal residual disease (MRD) and therapeutic response monitoring. To overcome the sparsity of ctDNA fragments in low tumor fraction (TF) settings and increase MRD sensitivity, we previously leveraged genome-wide mutational integration through plasma whole-genome sequencing (WGS). Here we now introduce MRD-EDGE, a machine-learning-guided WGS ctDNA single-nucleotide variant (SNV) and copy-number variant (CNV) detection platform designed to increase signal enrichment. MRD-EDGE^SNV uses deep learning and a ctDNA-specific feature space to increase SNV signal-to-noise enrichment in WGS by ~300× compared to previous WGS error suppression. MRD-EDGE^CNV also reduces the degree of aneuploidy needed for ultrasensitive CNV detection through WGS from 1 Gb to 200 Mb, vastly expanding its applicability within solid tumors. We harness the improved performance to identify MRD following surgery in multiple cancer types, track changes in TF in response to neoadjuvant immunotherapy in lung cancer and demonstrate ctDNA shedding in precancerous colorectal adenomas. Finally, the radical signal-to-noise enrichment in MRD-EDGE^SNV enables plasma-only (non-tumor-informed) disease monitoring in advanced melanoma and lung cancer, yielding clinically informative TF monitoring for patients on immune-checkpoint inhibition.

Original language	English
Pages (from-to)	1655-1666
Number of pages	12
Journal	Nature Medicine
Volume	30
Issue number	6
DOIs	https://doi.org/10.1038/s41591-024-03040-4
Publication status	Published - Jun 2024
Externally published	Yes

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This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

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10.1038/s41591-024-03040-4

Cite this

Widman, A. J., Shah, M., Frydendahl, A., Halmos, D., Khamnei, C. C., Øgaard, N., Rajagopalan, S., Arora, A., Deshpande, A., Hooper, W. F., Quentin, J., Bass, J., Zhang, M., Langanay, T., Andersen, L., Steinsnyder, Z., Liao, W., Rasmussen, M. H., Henriksen, T. V., ... Landau, D. A. (2024). Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment. Nature Medicine, 30(6), 1655-1666. https://doi.org/10.1038/s41591-024-03040-4

@article{9933e9730b974b7f81cb3f3b7ea7b7f5,

title = "Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment",

abstract = "In solid tumor oncology, circulating tumor DNA (ctDNA) is poised to transform care through accurate assessment of minimal residual disease (MRD) and therapeutic response monitoring. To overcome the sparsity of ctDNA fragments in low tumor fraction (TF) settings and increase MRD sensitivity, we previously leveraged genome-wide mutational integration through plasma whole-genome sequencing (WGS). Here we now introduce MRD-EDGE, a machine-learning-guided WGS ctDNA single-nucleotide variant (SNV) and copy-number variant (CNV) detection platform designed to increase signal enrichment. MRD-EDGESNV uses deep learning and a ctDNA-specific feature space to increase SNV signal-to-noise enrichment in WGS by \textasciitilde{}300× compared to previous WGS error suppression. MRD-EDGECNV also reduces the degree of aneuploidy needed for ultrasensitive CNV detection through WGS from 1 Gb to 200 Mb, vastly expanding its applicability within solid tumors. We harness the improved performance to identify MRD following surgery in multiple cancer types, track changes in TF in response to neoadjuvant immunotherapy in lung cancer and demonstrate ctDNA shedding in precancerous colorectal adenomas. Finally, the radical signal-to-noise enrichment in MRD-EDGESNV enables plasma-only (non-tumor-informed) disease monitoring in advanced melanoma and lung cancer, yielding clinically informative TF monitoring for patients on immune-checkpoint inhibition.",

author = "Widman, \{Adam J.\} and Minita Shah and Amanda Frydendahl and Daniel Halmos and Khamnei, \{Cole C.\} and Nadia {\O}gaard and Srinivas Rajagopalan and Anushri Arora and Aditya Deshpande and Hooper, \{William F.\} and Jean Quentin and Jake Bass and Mingxuan Zhang and Theophile Langanay and Laura Andersen and Zoe Steinsnyder and Will Liao and Rasmussen, \{Mads Heilskov\} and Henriksen, \{Tenna Vesterman\} and Jensen, \{Sarah {\O}strup\} and Jesper Nors and Christina Therkildsen and Jesus Sotelo and Ryan Brand and Schiffman, \{Joshua S.\} and Shah, \{Ronak H.\} and Cheng, \{Alexandre Pellan\} and Colleen Maher and Lavinia Spain and Kate Krause and Frederick, \{Dennie T.\} and \{den Brok\}, Wendie and Caroline Lohrisch and Tamara Shenkier and Christine Simmons and Diego Villa and Mungall, \{Andrew J.\} and Richard Moore and Elena Zaikova and Viviana Cerda and Esther Kong and Daniel Lai and Malbari, \{Murtaza S.\} and Melissa Marton and Dina Manaa and Lara Winterkorn and Karen Gelmon and Callahan, \{Margaret K.\} and Genevieve Boland and Catherine Potenski and Wolchok, \{Jedd D.\} and Ashish Saxena and Samra Turajlic and Marcin Imielinski and Berger, \{Michael F.\} and Sam Aparicio and Altorki, \{Nasser K.\} and Postow, \{Michael A.\} and Nicolas Robine and Andersen, \{Claus Lindbjerg\} and Landau, \{Dan A.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature America, Inc. 2024.",

year = "2024",

month = jun,

doi = "10.1038/s41591-024-03040-4",

language = "English",

volume = "30",

pages = "1655--1666",

journal = "Nature Medicine",

issn = "1078-8956",

publisher = "Nature Research",

number = "6",

}

Widman, AJ, Shah, M, Frydendahl, A, Halmos, D, Khamnei, CC, Øgaard, N, Rajagopalan, S, Arora, A, Deshpande, A, Hooper, WF, Quentin, J, Bass, J, Zhang, M, Langanay, T, Andersen, L, Steinsnyder, Z, Liao, W, Rasmussen, MH, Henriksen, TV, Jensen, SØ, Nors, J, Therkildsen, C, Sotelo, J, Brand, R, Schiffman, JS, Shah, RH, Cheng, AP, Maher, C, Spain, L, Krause, K, Frederick, DT, den Brok, W, Lohrisch, C, Shenkier, T, Simmons, C, Villa, D, Mungall, AJ, Moore, R, Zaikova, E, Cerda, V, Kong, E, Lai, D, Malbari, MS, Marton, M, Manaa, D, Winterkorn, L, Gelmon, K, Callahan, MK, Boland, G, Potenski, C, Wolchok, JD, Saxena, A, Turajlic, S, Imielinski, M, Berger, MF, Aparicio, S, Altorki, NK, Postow, MA, Robine, N, Andersen, CL & Landau, DA 2024, 'Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment', Nature Medicine, vol. 30, no. 6, pp. 1655-1666. https://doi.org/10.1038/s41591-024-03040-4

TY - JOUR

T1 - Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment

AU - Widman, Adam J.

AU - Shah, Minita

AU - Frydendahl, Amanda

AU - Halmos, Daniel

AU - Khamnei, Cole C.

AU - Øgaard, Nadia

AU - Rajagopalan, Srinivas

AU - Arora, Anushri

AU - Deshpande, Aditya

AU - Hooper, William F.

AU - Quentin, Jean

AU - Bass, Jake

AU - Zhang, Mingxuan

AU - Langanay, Theophile

AU - Andersen, Laura

AU - Steinsnyder, Zoe

AU - Liao, Will

AU - Rasmussen, Mads Heilskov

AU - Henriksen, Tenna Vesterman

AU - Jensen, Sarah Østrup

AU - Nors, Jesper

AU - Therkildsen, Christina

AU - Sotelo, Jesus

AU - Brand, Ryan

AU - Schiffman, Joshua S.

AU - Shah, Ronak H.

AU - Cheng, Alexandre Pellan

AU - Maher, Colleen

AU - Spain, Lavinia

AU - Krause, Kate

AU - Frederick, Dennie T.

AU - den Brok, Wendie

AU - Lohrisch, Caroline

AU - Shenkier, Tamara

AU - Simmons, Christine

AU - Villa, Diego

AU - Mungall, Andrew J.

AU - Moore, Richard

AU - Zaikova, Elena

AU - Cerda, Viviana

AU - Kong, Esther

AU - Lai, Daniel

AU - Malbari, Murtaza S.

AU - Marton, Melissa

AU - Manaa, Dina

AU - Winterkorn, Lara

AU - Gelmon, Karen

AU - Callahan, Margaret K.

AU - Boland, Genevieve

AU - Potenski, Catherine

AU - Wolchok, Jedd D.

AU - Saxena, Ashish

AU - Turajlic, Samra

AU - Imielinski, Marcin

AU - Berger, Michael F.

AU - Aparicio, Sam

AU - Altorki, Nasser K.

AU - Postow, Michael A.

AU - Robine, Nicolas

AU - Andersen, Claus Lindbjerg

AU - Landau, Dan A.

PY - 2024/6

Y1 - 2024/6

N2 - In solid tumor oncology, circulating tumor DNA (ctDNA) is poised to transform care through accurate assessment of minimal residual disease (MRD) and therapeutic response monitoring. To overcome the sparsity of ctDNA fragments in low tumor fraction (TF) settings and increase MRD sensitivity, we previously leveraged genome-wide mutational integration through plasma whole-genome sequencing (WGS). Here we now introduce MRD-EDGE, a machine-learning-guided WGS ctDNA single-nucleotide variant (SNV) and copy-number variant (CNV) detection platform designed to increase signal enrichment. MRD-EDGESNV uses deep learning and a ctDNA-specific feature space to increase SNV signal-to-noise enrichment in WGS by ~300× compared to previous WGS error suppression. MRD-EDGECNV also reduces the degree of aneuploidy needed for ultrasensitive CNV detection through WGS from 1 Gb to 200 Mb, vastly expanding its applicability within solid tumors. We harness the improved performance to identify MRD following surgery in multiple cancer types, track changes in TF in response to neoadjuvant immunotherapy in lung cancer and demonstrate ctDNA shedding in precancerous colorectal adenomas. Finally, the radical signal-to-noise enrichment in MRD-EDGESNV enables plasma-only (non-tumor-informed) disease monitoring in advanced melanoma and lung cancer, yielding clinically informative TF monitoring for patients on immune-checkpoint inhibition.

AB - In solid tumor oncology, circulating tumor DNA (ctDNA) is poised to transform care through accurate assessment of minimal residual disease (MRD) and therapeutic response monitoring. To overcome the sparsity of ctDNA fragments in low tumor fraction (TF) settings and increase MRD sensitivity, we previously leveraged genome-wide mutational integration through plasma whole-genome sequencing (WGS). Here we now introduce MRD-EDGE, a machine-learning-guided WGS ctDNA single-nucleotide variant (SNV) and copy-number variant (CNV) detection platform designed to increase signal enrichment. MRD-EDGESNV uses deep learning and a ctDNA-specific feature space to increase SNV signal-to-noise enrichment in WGS by ~300× compared to previous WGS error suppression. MRD-EDGECNV also reduces the degree of aneuploidy needed for ultrasensitive CNV detection through WGS from 1 Gb to 200 Mb, vastly expanding its applicability within solid tumors. We harness the improved performance to identify MRD following surgery in multiple cancer types, track changes in TF in response to neoadjuvant immunotherapy in lung cancer and demonstrate ctDNA shedding in precancerous colorectal adenomas. Finally, the radical signal-to-noise enrichment in MRD-EDGESNV enables plasma-only (non-tumor-informed) disease monitoring in advanced melanoma and lung cancer, yielding clinically informative TF monitoring for patients on immune-checkpoint inhibition.

UR - https://www.scopus.com/pages/publications/85195853582

U2 - 10.1038/s41591-024-03040-4

DO - 10.1038/s41591-024-03040-4

M3 - Journal Article

C2 - 38877116

AN - SCOPUS:85195853582

SN - 1078-8956

VL - 30

SP - 1655

EP - 1666

JO - Nature Medicine

JF - Nature Medicine

IS - 6

ER -

Ultrasensitive plasma-based monitoring of tumor burden using machine-learning-guided signal enrichment

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