Efficient Radial-Shell Model for 3D Tumor Spheroid Dynamics with Radiotherapy.
3D growth
cellular automaton
growth curve
minimal model
radial shell model
radiation therapy
simulation
spatio-temporal mathematical modelling
spheroids
systems biology
tumor relapse
Journal
Cancers
ISSN: 2072-6694
Titre abrégé: Cancers (Basel)
Pays: Switzerland
ID NLM: 101526829
Informations de publication
Date de publication:
29 Nov 2023
29 Nov 2023
Historique:
received:
30
10
2023
revised:
21
11
2023
accepted:
23
11
2023
medline:
9
12
2023
pubmed:
9
12
2023
entrez:
9
12
2023
Statut:
epublish
Résumé
Understanding the complex dynamics of tumor growth to develop more efficient therapeutic strategies is one of the most challenging problems in biomedicine. Three-dimensional (3D) tumor spheroids, reflecting avascular microregions within a tumor, are an advanced in vitro model system to assess the curative effect of combinatorial radio(chemo)therapy. Tumor spheroids exhibit particular crucial pathophysiological characteristics such as a radial oxygen gradient that critically affect the sensitivity of the malignant cell population to treatment. However, spheroid experiments remain laborious, and determining long-term radio(chemo)therapy outcomes is challenging. Mathematical models of spheroid dynamics have the potential to enhance the informative value of experimental data, and can support study design; however, they typically face one of two limitations: while non-spatial models are computationally cheap, they lack the spatial resolution to predict oxygen-dependent radioresponse, whereas models that describe spatial cell dynamics are computationally expensive and often heavily parameterized, impeding the required calibration to experimental data. Here, we present an effectively one-dimensional mathematical model based on the cell dynamics within and across radial spheres which fully incorporates the 3D dynamics of tumor spheroids by exploiting their approximate rotational symmetry. We demonstrate that this radial-shell (RS) model reproduces experimental spheroid growth curves of several cell lines with and without radiotherapy, showing equal or better performance than published models such as 3D agent-based models. Notably, the RS model is sufficiently efficient to enable multi-parametric optimization within previously reported and/or physiologically reasonable ranges based on experimental data. Analysis of the model reveals that the characteristic change of dynamics observed in experiments at small spheroid volume originates from the spatial scale of cell interactions. Based on the calibrated parameters, we predict the spheroid volumes at which this behavior should be observable. Finally, we demonstrate how the generic parameterization of the model allows direct parameter transfer to 3D agent-based models.
Identifiants
pubmed: 38067348
pii: cancers15235645
doi: 10.3390/cancers15235645
pmc: PMC10705470
pii:
doi:
Types de publication
Journal Article
Langues
eng
Subventions
Organisme : the EU, the European Social Fund (ESF) and by tax funds on the basis of the budget passed by the Saxon state parliament
ID : 100382145
Organisme : Sächsisches Staatsministerium für Wissenschaft und Kunst (SMWK)
ID : FORZUG II TP 3
Organisme : Bundesministerium für Bildung und Forschung
ID : BMBF 16dkwn001a/b
Organisme : DFG
ID : AL1705/11
Organisme : Open Access Publication Fund of Hochschule für Technik und Wirtschaft Dresden - University of Applied Sciences and by Deutsche Forschungsgemeinschaft
ID : 491382348
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