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A multidisciplinary hyper-modeling scheme in personalized in silico oncology: coupling cell kinetics with metabolism, signaling networks, and biomechanics as plug-in component models of a cancer digital twin

  • on behalf of the CHIC Project Consortium
    ,
  • Eleni Kolokotroni(Author)
    ,
  • Daniel Abler(Author)
    ,
  • Alokendra Ghosh(Author)
    ,
  • Eleftheria Tzamali(Author)
    ,
  • James Grogan(Author)
  • Institute of Communication and Computer Systems
    ,
  • University of Lausanne
    ,
  • University of Geneva
    ,
  • University of Pennsylvania
    ,
  • Foundation for Research and Technology-Hellas
    ,
  • University of Galway
Research Output: Contribution to journal Article Peer-review

Open access

Sustainable Development Goals

  • SDG 3 - Good Health and Well-being
    SDG 3 Good Health and Well

Abstract

The massive amount of human biological, imaging, and clinical data produced by multiple and diverse sources necessitates integrative modeling approaches able to summarize all this information into answers to specific clinical questions. In this paper, we present a hypermodeling scheme able to combine models of diverse cancer aspects regardless of their underlying method or scale. Describing tissue-scale cancer cell proliferation, biomechanical tumor growth, nutrient transport, genomic-scale aberrant cancer cell metabolism, and cell-signaling pathways that regulate the cellular response to therapy, the hypermodel integrates mutation, miRNA expression, imaging, and clinical data. The constituting hypomodels, as well as their orchestration and links, are described. Two specific cancer types, Wilms tumor (nephroblastoma) and non-small cell lung cancer, are addressed as proof-of-concept study cases. Personalized simulations of the actual anatomy of a patient have been conducted. The hypermodel has also been applied to predict tumor control after radiotherapy and the relationship between tumor proliferative activity and response to neoadjuvant chemotherapy. Our innovative hypermodel holds promise as a digital twin-based clinical decision support system and as the core of future in silico trial platforms, although additional retrospective adaptation and validation are necessary.

Publication Information

Output type

Research Output: Contribution to journal Article Peer-review

Original language

English

Article number

475

Journal (Volume, Issue Number)

Journal of Personalized Medicine (Volume 14, Issue 5)

Publication milestones

  • Accepted/In press - 17/04/2024
  • Published - 29/04/2024

Publication status

Published - 29/04/2024

External Publication IDs

  • Scopus: 85194421170

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