Decoding pan-cancer treatment outcomes using multimodal real-world data and explainable artificial intelligence

Julius Keyl; Philipp Keyl; Grégoire Montavon; René Hosch; Alexander Brehmer; Liliana Mochmann; Philipp Jurmeister; Gabriel Dernbach; Moon Kim; Sven Koitka; Sebastian Bauer; Nikolaos Bechrakis; Michael Forsting; Dagmar Führer-Sakel; Martin Glas; Viktor Grünwald; Boris Hadaschik; Johannes Haubold; Ken Herrmann; Stefan Kasper; Rainer Kimmig; Stephan Lang; Tienush Rassaf; Alexander Roesch; Dirk Schadendorf; Jens T. Siveke; Martin Stuschke; Ulrich Sure; Matthias Totzeck; Anja Welt; Marcel Wiesweg; Hideo A. Baba; Felix Nensa; Jan Egger; Klaus Robert Müller; Martin Schuler; Frederick Klauschen; Jens Kleesiek

doi:10.1038/s43018-024-00891-1

Decoding pan-cancer treatment outcomes using multimodal real-world data and explainable artificial intelligence

Julius Keyl
, Philipp Keyl
, Grégoire Montavon
, René Hosch
, Alexander Brehmer
, Liliana Mochmann
, Philipp Jurmeister
, Gabriel Dernbach
, Moon Kim
, Sven Koitka
, Sebastian Bauer
, Nikolaos Bechrakis
, Michael Forsting
, Dagmar Führer-Sakel
, Martin Glas
, Viktor Grünwald
, Boris Hadaschik
, Johannes Haubold
, Ken Herrmann
, Stefan Kasper

Rainer Kimmig, Stephan Lang, Tienush Rassaf, Alexander Roesch, Dirk Schadendorf, Jens T. Siveke, Martin Stuschke, Ulrich Sure, Matthias Totzeck, Anja Welt, Marcel Wiesweg, Hideo A. Baba, Felix Nensa, Jan Egger, Klaus Robert Müller, Martin Schuler, Frederick Klauschen, Jens Kleesiek

University Hospital of Essen
University of Munich
BIFOLD – Berlin Institute for the Foundations of Learning and Data
Technische Universität Berlin
Free University of Berlin
University Medicine Essen
University of Duisburg-Essen
German Cancer Research Center
Korea University
Max-Planck Institute for Informatics
Bavarian Cancer Research Center (BZKF)

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

25 Scopus citations

Abstract

Despite advances in precision oncology, clinical decision-making still relies on limited variables and expert knowledge. To address this limitation, we combined multimodal real-world data and explainable artificial intelligence (xAI) to introduce AI-derived (AID) markers for clinical decision support. We used xAI to decode the outcome of 15,726 patients across 38 solid cancer entities based on 350 markers, including clinical records, image-derived body compositions, and mutational tumor profiles. xAI determined the prognostic contribution of each clinical marker at the patient level and identified 114 key markers that accounted for 90% of the neural network’s decision process. Moreover, xAI enabled us to uncover 1,373 prognostic interactions between markers. Our approach was validated in an independent cohort of 3,288 patients with lung cancer from a US nationwide electronic health record-derived database. These results show the potential of xAI to transform the assessment of clinical variables and enable personalized, data-driven cancer care.

Original language	English
Article number	24
Pages (from-to)	307-322
Number of pages	16
Journal	Nature Cancer
Volume	6
Issue number	2
DOIs	https://doi.org/10.1038/s43018-024-00891-1
State	Published - Feb 2025
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/s43018-024-00891-1

Cite this

Keyl, J., Keyl, P., Montavon, G., Hosch, R., Brehmer, A., Mochmann, L., Jurmeister, P., Dernbach, G., Kim, M., Koitka, S., Bauer, S., Bechrakis, N., Forsting, M., Führer-Sakel, D., Glas, M., Grünwald, V., Hadaschik, B., Haubold, J., Herrmann, K., ... Kleesiek, J. (2025). Decoding pan-cancer treatment outcomes using multimodal real-world data and explainable artificial intelligence. Nature Cancer, 6(2), 307-322. Article 24. https://doi.org/10.1038/s43018-024-00891-1

@article{a5e02108d5e04dc7922ec3f7d8a14a9c,

title = "Decoding pan-cancer treatment outcomes using multimodal real-world data and explainable artificial intelligence",

abstract = "Despite advances in precision oncology, clinical decision-making still relies on limited variables and expert knowledge. To address this limitation, we combined multimodal real-world data and explainable artificial intelligence (xAI) to introduce AI-derived (AID) markers for clinical decision support. We used xAI to decode the outcome of 15,726 patients across 38 solid cancer entities based on 350 markers, including clinical records, image-derived body compositions, and mutational tumor profiles. xAI determined the prognostic contribution of each clinical marker at the patient level and identified 114 key markers that accounted for 90\% of the neural network{\textquoteright}s decision process. Moreover, xAI enabled us to uncover 1,373 prognostic interactions between markers. Our approach was validated in an independent cohort of 3,288 patients with lung cancer from a US nationwide electronic health record-derived database. These results show the potential of xAI to transform the assessment of clinical variables and enable personalized, data-driven cancer care.",

author = "Julius Keyl and Philipp Keyl and Gr{\'e}goire Montavon and Ren{\'e} Hosch and Alexander Brehmer and Liliana Mochmann and Philipp Jurmeister and Gabriel Dernbach and Moon Kim and Sven Koitka and Sebastian Bauer and Nikolaos Bechrakis and Michael Forsting and Dagmar F{\"u}hrer-Sakel and Martin Glas and Viktor Gr{\"u}nwald and Boris Hadaschik and Johannes Haubold and Ken Herrmann and Stefan Kasper and Rainer Kimmig and Stephan Lang and Tienush Rassaf and Alexander Roesch and Dirk Schadendorf and Siveke, \{Jens T.\} and Martin Stuschke and Ulrich Sure and Matthias Totzeck and Anja Welt and Marcel Wiesweg and Baba, \{Hideo A.\} and Felix Nensa and Jan Egger and M{\"u}ller, \{Klaus Robert\} and Martin Schuler and Frederick Klauschen and Jens Kleesiek",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = feb,

doi = "10.1038/s43018-024-00891-1",

language = "English",

volume = "6",

pages = "307--322",

journal = "Nature Cancer",

issn = "2662-1347",

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Keyl, J, Keyl, P, Montavon, G, Hosch, R, Brehmer, A, Mochmann, L, Jurmeister, P, Dernbach, G, Kim, M, Koitka, S, Bauer, S, Bechrakis, N, Forsting, M, Führer-Sakel, D, Glas, M, Grünwald, V, Hadaschik, B, Haubold, J, Herrmann, K, Kasper, S, Kimmig, R, Lang, S, Rassaf, T, Roesch, A, Schadendorf, D, Siveke, JT, Stuschke, M, Sure, U, Totzeck, M, Welt, A, Wiesweg, M, Baba, HA, Nensa, F, Egger, J, Müller, KR, Schuler, M, Klauschen, F & Kleesiek, J 2025, 'Decoding pan-cancer treatment outcomes using multimodal real-world data and explainable artificial intelligence', Nature Cancer, vol. 6, no. 2, 24, pp. 307-322. https://doi.org/10.1038/s43018-024-00891-1

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AU - Keyl, Philipp

AU - Montavon, Grégoire

AU - Hosch, René

AU - Brehmer, Alexander

AU - Mochmann, Liliana

AU - Jurmeister, Philipp

AU - Dernbach, Gabriel

AU - Kim, Moon

AU - Koitka, Sven

AU - Bauer, Sebastian

AU - Bechrakis, Nikolaos

AU - Forsting, Michael

AU - Führer-Sakel, Dagmar

AU - Glas, Martin

AU - Grünwald, Viktor

AU - Hadaschik, Boris

AU - Haubold, Johannes

AU - Herrmann, Ken

AU - Kasper, Stefan

AU - Kimmig, Rainer

AU - Lang, Stephan

AU - Rassaf, Tienush

AU - Roesch, Alexander

AU - Schadendorf, Dirk

AU - Siveke, Jens T.

AU - Stuschke, Martin

AU - Sure, Ulrich

AU - Totzeck, Matthias

AU - Welt, Anja

AU - Wiesweg, Marcel

AU - Baba, Hideo A.

AU - Nensa, Felix

AU - Egger, Jan

AU - Müller, Klaus Robert

AU - Schuler, Martin

AU - Klauschen, Frederick

AU - Kleesiek, Jens

PY - 2025/2

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N2 - Despite advances in precision oncology, clinical decision-making still relies on limited variables and expert knowledge. To address this limitation, we combined multimodal real-world data and explainable artificial intelligence (xAI) to introduce AI-derived (AID) markers for clinical decision support. We used xAI to decode the outcome of 15,726 patients across 38 solid cancer entities based on 350 markers, including clinical records, image-derived body compositions, and mutational tumor profiles. xAI determined the prognostic contribution of each clinical marker at the patient level and identified 114 key markers that accounted for 90% of the neural network’s decision process. Moreover, xAI enabled us to uncover 1,373 prognostic interactions between markers. Our approach was validated in an independent cohort of 3,288 patients with lung cancer from a US nationwide electronic health record-derived database. These results show the potential of xAI to transform the assessment of clinical variables and enable personalized, data-driven cancer care.

AB - Despite advances in precision oncology, clinical decision-making still relies on limited variables and expert knowledge. To address this limitation, we combined multimodal real-world data and explainable artificial intelligence (xAI) to introduce AI-derived (AID) markers for clinical decision support. We used xAI to decode the outcome of 15,726 patients across 38 solid cancer entities based on 350 markers, including clinical records, image-derived body compositions, and mutational tumor profiles. xAI determined the prognostic contribution of each clinical marker at the patient level and identified 114 key markers that accounted for 90% of the neural network’s decision process. Moreover, xAI enabled us to uncover 1,373 prognostic interactions between markers. Our approach was validated in an independent cohort of 3,288 patients with lung cancer from a US nationwide electronic health record-derived database. These results show the potential of xAI to transform the assessment of clinical variables and enable personalized, data-driven cancer care.

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DO - 10.1038/s43018-024-00891-1

M3 - Article

AN - SCOPUS:85217166090

SN - 2662-1347

VL - 6

SP - 307

EP - 322

JO - Nature Cancer

JF - Nature Cancer

IS - 2

M1 - 24

ER -

Decoding pan-cancer treatment outcomes using multimodal real-world data and explainable artificial intelligence

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