Multiscale model of the different modes of cancer cell invasion

Ruscone, Marco; Montagud, Arnau; Chavrier, Philippe; Destaing, Olivier; Bonnet, Isabelle; Zinovyev, Andreï; Barillot, Emmanuel; Noël, Vincent; Calzone, Laurence

doi:10.1093/bioinformatics/btad374

Cited by 6 publications

(8 citation statements)

References 58 publications

(71 reference statements)

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“… Criterion Quantities Reference(s) Accuracy MSE, RMSE, F-score, ROC curve 28 , 95 Complexity # of model parameters, # of agents, connectivity density of ontology graph, Bayesian Information Criterion 119–122 Explanatory power black box vs . white box model, accordance with experimental data across scales 7 , 13 , 17 , 86 Model robustness/sensitivity coefficient of variation, sensitivity indices 28 , 66 , 124 Computational efficacy lines of code, run-time, memory usage, energy demand 125–128 …”

Section: Strategies For Agent-based Models Calibration and Validationmentioning

confidence: 87%

“…They probed for the effect of the spatial distribution of cancer cells on the treatment parameters optimizing the supply strategies in cell monolayers and three-dimensional tumor spheroids; similarly, they interrogated the robustness of the effective treatments with respect to the cell population heterogeneity of the cancer cells. Following the modeling work in, 85 Ruscone et al 86 proposed an enhanced multi-scale model to interrogate possible targets that can help block or suppress the invasive phenotypes of cancer cells. More specifically, the improvements are focused at the intracellular scale where they incorporated mechanisms of epithelialto-mesenchymal transition and cell metastasis.…”

Section: Agent-based Modeling In Cancer Biomedicinementioning

confidence: 99%

“…The larger the range of spatial and temporal scales that an agent-based model allows to capture and reproduce, the higher its explanatory power. Along those lines, Wijeratne and Vavourakis 7 studied the impact of drug-borne nanoparticles on multiple levels including the fluid dynamics, biochemics, vasculature, and overall solid tumor, while Ruscone et al 86 also proposed an agent-based model and probe dynamics on the scales of genetics, metabolism, cell behavior and population.…”

Section: Strategies For Agent-based Models Calibration and Validationmentioning

confidence: 99%

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Agent-based modeling in cancer biomedicine: applications and tools for calibration and validation

Cogno,

Axenie,

Bauer

et al. 2024

Cancer Biology & Therapy

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Computational models are not just appealing because they can simulate and predict the development of biological phenomena across multiple spatial and temporal scales, but also because they can integrate information from well-established in vitro and in vivo models and test new hypotheses in cancer biomedicine. Agent-based models and simulations are especially interesting candidates among computational modeling procedures in cancer research due to the capability to, for instance, recapitulate the dynamics of neoplasia and tumor – host interactions. Yet, the absence of methods to validate the consistency of the results across scales can hinder adoption by turning fine-tuned models into black boxes. This review compiles relevant literature that explores strategies to leverage high-fidelity simulations of multi-scale, or multi-level, cancer models with a focus on verification approached as simulation calibration. We consolidate our review with an outline of modern approaches for agent-based models’ validation and provide an ambitious outlook toward rigorous and reliable calibration.

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Section: Strategies For Agent-based Models Calibration and Validationmentioning

confidence: 87%

Section: Agent-based Modeling In Cancer Biomedicinementioning

confidence: 99%

Section: Strategies For Agent-based Models Calibration and Validationmentioning

confidence: 99%

See 1 more Smart Citation

Agent-based modeling in cancer biomedicine: applications and tools for calibration and validation

Cogno,

Axenie,

Bauer

et al. 2024

Cancer Biology & Therapy

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“…PhysiBoSS allows bridging microenvironment signals, such as drugs, their effect on signalling pathways and the resulting population-level phenotypes 23 , 26 – 28 . The introduction of this hybrid simulation framework was an important step toward the mechanistic multi-scale description of complex biological systems such as healthy tissues and tumours 9 .…”

Section: Introductionmentioning

confidence: 99%

PhysiBoSS 2.0: a sustainable integration of stochastic Boolean and agent-based modelling frameworks

Ponce-de-Leon,

Montagud,

Noël

et al. 2023

npj Syst Biol Appl

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In systems biology, mathematical models and simulations play a crucial role in understanding complex biological systems. Different modelling frameworks are employed depending on the nature and scales of the system under study. For instance, signalling and regulatory networks can be simulated using Boolean modelling, whereas multicellular systems can be studied using agent-based modelling. Herein, we present PhysiBoSS 2.0, a hybrid agent-based modelling framework that allows simulating signalling and regulatory networks within individual cell agents. PhysiBoSS 2.0 is a redesign and reimplementation of PhysiBoSS 1.0 and was conceived as an add-on that expands the PhysiCell functionalities by enabling the simulation of intracellular cell signalling using MaBoSS while keeping a decoupled, maintainable and model-agnostic design. PhysiBoSS 2.0 also expands the set of functionalities offered to the users, including custom models and cell specifications, mechanistic submodels of substrate internalisation and detailed control over simulation parameters. Together with PhysiBoSS 2.0, we introduce PCTK, a Python package developed for handling and processing simulation outputs, and generating summary plots and 3D renders. PhysiBoSS 2.0 allows studying the interplay between the microenvironment, the signalling pathways that control cellular processes and population dynamics, suitable for modelling cancer. We show different approaches for integrating Boolean networks into multi-scale simulations using strategies to study the drug effects and synergies in models of cancer cell lines and validate them using experimental data. PhysiBoSS 2.0 is open-source and publicly available on GitHub with several repositories of accompanying interoperable tools.

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“…Goncalves and Garcia-Aznar represent the ECM as a density and use experimental migration data to explore tumor spheroids [35]. Lastly, Ruscone et al study cancer invasion using PhysiBoSS [36, 37], an implementation of PhyisCell [38] with the MaBoSS Boolean network simulator [39], with a model incorporating intracellular signaling activated by contact with a bulk ECM [40].…”

Section: Introductionmentioning

confidence: 99%

A simple framework for agent-based modeling with extracellular matrix

Metzcar

Duggan

Fischer

et al. 2022

Preprint

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Extracellular matrix (ECM) is a key part of the cellular microenvironment and critical in multiple disease and developmental processes. Representing ECM and cell–ECM interactions is a challenging multi–scale problem that acts across the tissue and cell scales. While several computational frameworks exist for ECM modeling, they typically focus on very detailed modeling of individual ECM fibers or represent only a single aspect of the ECM. Using the PhysiCell agent–based modeling platform, we combine aspects of previous modeling efforts and develop a framework of intermediate detail that addresses direct cell–ECM interactions. We represent a small region of ECM as an ECM element containing 3 variables: anisotropy, density, and orientation. We then place many ECM elements through a space to form an ECM. Cells have a mechanical response to the local ECM variables and remodel ECM based on their velocity. We demonstrate aspects of this framework with a model of cell invasion where the cell's motile phenotype is driven by the ECM microstructure patterned by prior cells' movements. Investigating the limit of high–speed communication and with stepwise introduction of the framework features, we generate a range of cellular dynamics and ECM patterns — from recapitulating a homeostatic tissue, to indirect communication of paths (stigmergy), to collective migration. When we relax the high–speed communication assumption, we find that the behaviors persist but can be lost as rate of signal generation declines. This result suggests that cell–cell communication mitigated via the ECM can constitute an important mechanism for pattern formation in dynamic cellular patterning while other processes likely also contribute to leader-follower behavior.

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Multiscale model of the different modes of cancer cell invasion

Cited by 6 publications

References 58 publications

Agent-based modeling in cancer biomedicine: applications and tools for calibration and validation

Agent-based modeling in cancer biomedicine: applications and tools for calibration and validation

PhysiBoSS 2.0: a sustainable integration of stochastic Boolean and agent-based modelling frameworks

A simple framework for agent-based modeling with extracellular matrix

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