Clinically oriented translational cancer multilevel modeling: the ContraCancrum project

Konstantinos Marias; V. Sakkalis; A. Roniotis; C. Farmaki; G. Stamatakos; D. Dionysiou; S. Giatili; N. Uzunoglou; N. Graf; R. Bohle; E. Messe; P. V. Coveney; S. Manos; S. Wan; A. Folarin; S. Nagl; P. Büchler; T. Bardyn; M. Reyes; G. Clapworthy; N. Mcfarlane; E. Liu; T. Bily; M. Balek; M. Karasek; V. Bednar; J. Sabczynski; R. Opfer; S. Renisch; I. C. Carlsen

doi:10.1007/978-3-642-03882-2_564

Clinically oriented translational cancer multilevel modeling: the ContraCancrum project

Konstantinos Marias^*
, V. Sakkalis
, A. Roniotis
, C. Farmaki
, G. Stamatakos
, D. Dionysiou
, S. Giatili
, N. Uzunoglou
, N. Graf
, R. Bohle
, E. Messe
, P. V. Coveney
, S. Manos
, S. Wan
, A. Folarin
, S. Nagl
, P. Büchler
, T. Bardyn
, M. Reyes
, G. Clapworthy

N. Mcfarlane, E. Liu, T. Bily, M. Balek, M. Karasek, V. Bednar, J. Sabczynski, R. Opfer, S. Renisch, I. C. Carlsen

^*Corresponding author for this work

Institute for Research in Applicable Computing (IRAC)

Foundation for Research and Technology-Hellas
National Technical University of Athens
Saarland University
University College London
Institute of Cancer Research
Institute for Surgical Technology and Biomechanics
Charles University
Koninklijke Philips N.V.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

14 Citations (Scopus)

Abstract

The ContraCancrum project aims at developing a composite multilevel platform for simulating malignant tumor development and tumor and normal tissue response to therapeutic modalities and treatment schedules. The project aims at having an impact primarily in (a) the better understanding of the natural phenomenon of cancer at different levels of biocomplexity and most importantly (b) the disease treatment optimization procedure in the patient's individualized context by simulating the response to various therapeutic regimens. Fundamental biological mechanisms involved in tumor development and tumor and normal tissue treatment response such as metabolism, cell cycle, tissue mechanics, cell survival following treatment etc. are modeled also addressing stem cells in the context of both tumor and normal tissue behavior. The simulators exploit several discrete and continuous mathematics methods such as cellular automata, the generic Monte Carlo technique, finite elements, differential equations, novel dedicated algorithms etc. The predictions of the simulators rely on the imaging, histopathological, molecular and clinical data of the patient. ContraCancrum deploys two important clinical studies for validating the models, one on lung cancer and one on gliomas. The crucial validation work is based on comparing the multi-level therapy simulation predictions with multi-level patient data, acquired before and after therapy. ContraCancrum aims to pave the way for translating clinically validated multilevel cancer models into clinical practice.

Original language	English
Title of host publication	World Congress on Medical Physics and Biomedical Engineering
Subtitle of host publication	Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics
Publisher	Springer
Pages	2124-2127
Number of pages	4
Edition	4
ISBN (Print)	9783642038815
DOIs	https://doi.org/10.1007/978-3-642-03882-2_564
Publication status	Published - 1 Oct 2009
Event	World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics - Munich, Germany Duration: 7 Sept 2009 → 12 Sept 2009

Publication series

Name	IFMBE Proceedings
Number	4
Volume	25
ISSN (Print)	1680-0737

Conference

Conference	World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics
Country/Territory	Germany
City	Munich
Period	7/09/09 → 12/09/09

UN SDGs

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

SDG 3 Good Health and Well-being

Keywords

Cancer modeling
In silico oncology
Multi-level models
VPH

ASJC Scopus subject areas

Bioengineering
Biomedical Engineering

Access to Document

10.1007/978-3-642-03882-2_564

Clinically_Oriented_Translational_Cancer_MultileveAccepted author manuscript, 61.7 KBLicence: CC BY-NC-ND

https://link.springer.com/chapter/10.1007/978-3-642-03882-2_564

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Marias, K., Sakkalis, V., Roniotis, A., Farmaki, C., Stamatakos, G., Dionysiou, D., Giatili, S., Uzunoglou, N., Graf, N., Bohle, R., Messe, E., Coveney, P. V., Manos, S., Wan, S., Folarin, A., Nagl, S., Büchler, P., Bardyn, T., Reyes, M., ... Carlsen, I. C. (2009). Clinically oriented translational cancer multilevel modeling: the ContraCancrum project. In World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics (4 ed., pp. 2124-2127). (IFMBE Proceedings; Vol. 25, No. 4). Springer. https://doi.org/10.1007/978-3-642-03882-2_564

@inproceedings{434a71c1210740f39a7ceeac7a005ace,

title = "Clinically oriented translational cancer multilevel modeling: the ContraCancrum project",

abstract = "The ContraCancrum project aims at developing a composite multilevel platform for simulating malignant tumor development and tumor and normal tissue response to therapeutic modalities and treatment schedules. The project aims at having an impact primarily in (a) the better understanding of the natural phenomenon of cancer at different levels of biocomplexity and most importantly (b) the disease treatment optimization procedure in the patient's individualized context by simulating the response to various therapeutic regimens. Fundamental biological mechanisms involved in tumor development and tumor and normal tissue treatment response such as metabolism, cell cycle, tissue mechanics, cell survival following treatment etc. are modeled also addressing stem cells in the context of both tumor and normal tissue behavior. The simulators exploit several discrete and continuous mathematics methods such as cellular automata, the generic Monte Carlo technique, finite elements, differential equations, novel dedicated algorithms etc. The predictions of the simulators rely on the imaging, histopathological, molecular and clinical data of the patient. ContraCancrum deploys two important clinical studies for validating the models, one on lung cancer and one on gliomas. The crucial validation work is based on comparing the multi-level therapy simulation predictions with multi-level patient data, acquired before and after therapy. ContraCancrum aims to pave the way for translating clinically validated multilevel cancer models into clinical practice.",

keywords = "Cancer modeling, In silico oncology, Multi-level models, VPH",

author = "Konstantinos Marias and V. Sakkalis and A. Roniotis and C. Farmaki and G. Stamatakos and D. Dionysiou and S. Giatili and N. Uzunoglou and N. Graf and R. Bohle and E. Messe and Coveney, \{P. V.\} and S. Manos and S. Wan and A. Folarin and S. Nagl and P. B{\"u}chler and T. Bardyn and M. Reyes and G. Clapworthy and N. Mcfarlane and E. Liu and T. Bily and M. Balek and M. Karasek and V. Bednar and J. Sabczynski and R. Opfer and S. Renisch and Carlsen, \{I. C.\}",

year = "2009",

month = oct,

day = "1",

doi = "10.1007/978-3-642-03882-2\_564",

language = "English",

isbn = "9783642038815",

series = "IFMBE Proceedings",

publisher = "Springer",

number = "4",

pages = "2124--2127",

booktitle = "World Congress on Medical Physics and Biomedical Engineering",

address = "Germany",

edition = "4",

note = "World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics ; Conference date: 07-09-2009 Through 12-09-2009",

}

Marias, K, Sakkalis, V, Roniotis, A, Farmaki, C, Stamatakos, G, Dionysiou, D, Giatili, S, Uzunoglou, N, Graf, N, Bohle, R, Messe, E, Coveney, PV, Manos, S, Wan, S, Folarin, A, Nagl, S, Büchler, P, Bardyn, T, Reyes, M, Clapworthy, G, Mcfarlane, N, Liu, E, Bily, T, Balek, M, Karasek, M, Bednar, V, Sabczynski, J, Opfer, R, Renisch, S & Carlsen, IC 2009, Clinically oriented translational cancer multilevel modeling: the ContraCancrum project. in World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics. 4 edn, IFMBE Proceedings, no. 4, vol. 25, Springer, pp. 2124-2127, World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics, Munich, Germany, 7/09/09. https://doi.org/10.1007/978-3-642-03882-2_564

Clinically oriented translational cancer multilevel modeling: the ContraCancrum project. / Marias, Konstantinos; Sakkalis, V.; Roniotis, A. et al.
World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics. 4. ed. Springer, 2009. p. 2124-2127 (IFMBE Proceedings; Vol. 25, No. 4).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Clinically oriented translational cancer multilevel modeling

T2 - World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics

AU - Marias, Konstantinos

AU - Sakkalis, V.

AU - Roniotis, A.

AU - Farmaki, C.

AU - Stamatakos, G.

AU - Dionysiou, D.

AU - Giatili, S.

AU - Uzunoglou, N.

AU - Graf, N.

AU - Bohle, R.

AU - Messe, E.

AU - Coveney, P. V.

AU - Manos, S.

AU - Wan, S.

AU - Folarin, A.

AU - Nagl, S.

AU - Büchler, P.

AU - Bardyn, T.

AU - Reyes, M.

AU - Clapworthy, G.

AU - Mcfarlane, N.

AU - Liu, E.

AU - Bily, T.

AU - Balek, M.

AU - Karasek, M.

AU - Bednar, V.

AU - Sabczynski, J.

AU - Opfer, R.

AU - Renisch, S.

AU - Carlsen, I. C.

PY - 2009/10/1

Y1 - 2009/10/1

N2 - The ContraCancrum project aims at developing a composite multilevel platform for simulating malignant tumor development and tumor and normal tissue response to therapeutic modalities and treatment schedules. The project aims at having an impact primarily in (a) the better understanding of the natural phenomenon of cancer at different levels of biocomplexity and most importantly (b) the disease treatment optimization procedure in the patient's individualized context by simulating the response to various therapeutic regimens. Fundamental biological mechanisms involved in tumor development and tumor and normal tissue treatment response such as metabolism, cell cycle, tissue mechanics, cell survival following treatment etc. are modeled also addressing stem cells in the context of both tumor and normal tissue behavior. The simulators exploit several discrete and continuous mathematics methods such as cellular automata, the generic Monte Carlo technique, finite elements, differential equations, novel dedicated algorithms etc. The predictions of the simulators rely on the imaging, histopathological, molecular and clinical data of the patient. ContraCancrum deploys two important clinical studies for validating the models, one on lung cancer and one on gliomas. The crucial validation work is based on comparing the multi-level therapy simulation predictions with multi-level patient data, acquired before and after therapy. ContraCancrum aims to pave the way for translating clinically validated multilevel cancer models into clinical practice.

AB - The ContraCancrum project aims at developing a composite multilevel platform for simulating malignant tumor development and tumor and normal tissue response to therapeutic modalities and treatment schedules. The project aims at having an impact primarily in (a) the better understanding of the natural phenomenon of cancer at different levels of biocomplexity and most importantly (b) the disease treatment optimization procedure in the patient's individualized context by simulating the response to various therapeutic regimens. Fundamental biological mechanisms involved in tumor development and tumor and normal tissue treatment response such as metabolism, cell cycle, tissue mechanics, cell survival following treatment etc. are modeled also addressing stem cells in the context of both tumor and normal tissue behavior. The simulators exploit several discrete and continuous mathematics methods such as cellular automata, the generic Monte Carlo technique, finite elements, differential equations, novel dedicated algorithms etc. The predictions of the simulators rely on the imaging, histopathological, molecular and clinical data of the patient. ContraCancrum deploys two important clinical studies for validating the models, one on lung cancer and one on gliomas. The crucial validation work is based on comparing the multi-level therapy simulation predictions with multi-level patient data, acquired before and after therapy. ContraCancrum aims to pave the way for translating clinically validated multilevel cancer models into clinical practice.

KW - Cancer modeling

KW - In silico oncology

KW - Multi-level models

KW - VPH

UR - https://www.scopus.com/pages/publications/77950174068

U2 - 10.1007/978-3-642-03882-2_564

DO - 10.1007/978-3-642-03882-2_564

M3 - Conference contribution

AN - SCOPUS:77950174068

SN - 9783642038815

T3 - IFMBE Proceedings

SP - 2124

EP - 2127

BT - World Congress on Medical Physics and Biomedical Engineering

PB - Springer

Y2 - 7 September 2009 through 12 September 2009

ER -

Marias K, Sakkalis V, Roniotis A, Farmaki C, Stamatakos G, Dionysiou D et al. Clinically oriented translational cancer multilevel modeling: the ContraCancrum project. In World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics. 4 ed. Springer. 2009. p. 2124-2127. (IFMBE Proceedings; 4). doi: 10.1007/978-3-642-03882-2_564

Clinically oriented translational cancer multilevel modeling: the ContraCancrum project

Abstract

Publication series

Conference

UN SDGs

Keywords

ASJC Scopus subject areas

Access to Document

Handle.net

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