A continuum mechanical framework for modeling tumor growth and treatment in two- and three-phase systems

Miller, Cass T.; Gray, William G.; Schrefler, Bernhard A.

doi:10.1007/s00419-021-01891-8

Cited by 8 publications

(7 citation statements)

References 62 publications

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“…Note that we model the growing tumour spheroid itself as a viscous fluid, as in the previous tumour models [23]. When averaging the equations, we maintain a strong connection between the microscopic and the macroscopic descriptions by employing the thermodynamically constrained averaging theory (TCAT) [42]. This has the additional advantage that all quantities at the macroscale have a clear relation to their counterparts at the microscale and therefore lend themselves to precise physical interpretation [23].…”

Section: Methodsmentioning

confidence: 99%

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Tumour growth: Bayesian parameter calibration of a multiphase porous media model based on in vitro observations of Neuroblastoma spheroid growth in a hydrogel microenvironment

Hervas-Raluy

Wirthl

Guerrero

et al. 2022

Preprint

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To unravel processes that lead to the growth of solid tumours, it is necessary to link knowledge of cancer biology with the physical properties of the tumour and its interaction with the surrounding microenvironment. Our understanding of the underlying mechanisms is however still imprecise. We therefore developed computational physics-based models, which incorporate the interaction of the tumour with its surroundings based on the theory of porous media. However, the experimental validation of such models represents a challenge to its clinical use as a prognostic tool. This study combines a physics-based model with in vitro experiments based on microfluidic devices used to mimic a 3D tumour microenvironment. By conducting a global sensitivity analysis, we identify the most influential input parameters and infer their posterior distribution based on Bayesian calibration. The resulting probability density is in agreement with the scattering of the experimental data and thus validates the modelling approach. Using the proposed workflow, we demonstrate that we can indirectly characterise the mechanical properties of neuroblastoma spheroids that cannot feasibly be measured experimentally.

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Section: Methodsmentioning

confidence: 99%

“…Further experimental analyses of how tumour cells interact with their surroundings (ECM and other phases) are clearly necessary. From the computational side however, Miller et al [42] have already proposed a theoretically sound version which considers the interfaces between the phases.…”

Section: Bayesian Calibrationmentioning

confidence: 99%

Tumour growth: Bayesian parameter calibration of a multiphase porous media model based on in vitro observations of Neuroblastoma spheroid growth in a hydrogel microenvironment

Hervas-Raluy

Wirthl

Guerrero

et al. 2022

Preprint

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“…We include three fluid phases: tumour cells, host cells, and interstitial fluid (IF), denoted by superscripts t, h and l, respectively. In addition, the vasculature is modelled as an independent porous network and denoted by superscript v. The governing equations of the model are formulated on the macroscale by employing the Thermodynamically Constrained Averaging Theory (TCAT) [64,65]. Each phase is modelled in an averaged sense based on volume fractions ε α with α denoting an arbitrary phase.…”

Section: Underlying Tumour-growth Modelmentioning

confidence: 99%

Global sensitivity analysis based on Gaussian-process metamodelling for complex biomechanical problems

Wirthl¹,

Brandstaeter²,

Nitzler³

et al. 2022

Preprint

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Biomechanical models often need to describe very complex systems, organs or diseases, and hence also include a large number of parameters. One of the attractive features of physics-based models is that in those models (most) parameters have a clear physical meaning. Nevertheless, the determination of these parameters is often very elaborate and costly and shows a large scatter within the population. Hence, it is essential to identify the most important parameter (worth the effort) for a particular problem at hand. In order to distinguish parameters which have a significant influence on a specific model output from non-influential parameters, we use sensitivity analysis, in particular the Sobol method as a global variance-based method. However, the Sobol method requires a large number of model evaluations, which is prohibitive for computationally expensive models. We therefore employ Gaussian processes as a metamodel for the underlying full model. Metamodelling introduces further uncertainty, which we also quantify. We demonstrate the approach by applying it to two different problems: nanoparticle-mediated drug delivery in a complex, multiphase tumour-growth model, and arterial growth and remodelling. Even relatively small numbers of evaluations of the full model suffice to identify the influential parameters in both cases and to separate them from non-influential parameters. The approach also allows the quantification of higher-order interaction effects. We thus show that a variance-based global sensitivity analysis is feasible for complex, computationally expensive biomechanical models. Different aspects of sensitivity analysis are covered including a transparent declaration of the uncertainties involved in the estimation process. Such a global sensitivity analysis not only helps to massively reduce costs for experimental determination of parameters but is also highly beneficial for inverse analysis of such complex models.

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“…The macroscale is a phenomenological scale that is far larger than the microscale of cells and voids, but substantially smaller than the system length scale. Macroscale considerations are important because of the possible complications caused by a large number of particles at the molecular scale or the complex microscale structure of biological tissues [ 74 , 75 ]. Good separation of the length scales is pivotal for establishing a macroscale representation identical to the microscale behavior [ 76 , 77 ].…”

Section: Mathematical Models Of Tissue and Heat Transportmentioning

confidence: 99%

Computational Modeling of Microwave Tumor Ablation

Radmilović-Radjenović

Bošković

Radjenović

2022

Bioengineering

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Microwave ablation is recognized as a minimally invasive, fast-recovery treatment for destroying cancer cells using the heat generated by microwave energy. Despite the unquestionable benefits of microwave ablation, the interaction of the microwave applicator with the tissue may result in localized heating and damage to the surrounding tissue. The majority of the tissue damage can be removed by clarifying the conditions for their development. In addition to experimental methods, computer modeling has proven to be an effective tool for optimizing the performance of microwave ablation. Furthermore, because the thermal spread in biological tissue is difficult to measure, developing a predictive model from procedural planning to execution may have a substantial influence on patient care. The comprehension of heat transport in biological tissues plays a significant role in gaining insight into the mechanisms underlying microwave ablation. Numerical methods that enable ablation size control are required to guarantee tumor destruction and minimize damage to healthy tissues. Various values of input power and ablation time correspond to different tumor shapes ensuring the preservation of healthy tissues. The optimal conditions can be estimated by performing full three-dimensional simulations. This topical review recapitulates numerous computational studies on microwave tumor ablation. Novel areas emerging in treatment planning that exploit the advantages of numerical methods are also discussed. As an illustration, the results of the three-dimensional simulations of real liver tumors in the 3D-IRCADb-01 database are presented and analyzed. The simulation results confirm that numerical methods are very useful tools for modeling microwave tumor ablation with minimal invasiveness and collateral damage.

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A continuum mechanical framework for modeling tumor growth and treatment in two- and three-phase systems

Cited by 8 publications

References 62 publications

Tumour growth: Bayesian parameter calibration of a multiphase porous media model based on in vitro observations of Neuroblastoma spheroid growth in a hydrogel microenvironment

Tumour growth: Bayesian parameter calibration of a multiphase porous media model based on in vitro observations of Neuroblastoma spheroid growth in a hydrogel microenvironment

Global sensitivity analysis based on Gaussian-process metamodelling for complex biomechanical problems

Computational Modeling of Microwave Tumor Ablation

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