Simulating tissue mechanics with agent-based models: concepts, perspectives and some novel results

Liedekerke, Paul Van; Palm, Margriet; Jagiella, Nick; Drasdo, Dirk

doi:10.1007/s40571-015-0082-3

Cited by 229 publications

(249 citation statements)

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“…(1) describe damping mechanisms related to the friction forces resulting from the contact of cell i with, respectively, the substrate and the other individuals, as λ cs i and λ cc i j are the corresponding coefficients (which may be, for instance, constant parameters in common for all cells ( Costanzo et al, 2015 ) or time-dependent individuallyspecific tensors ( Liedekerke et al, 2015 )). These contributions have the effect to slow down individual movement and eventually to increase the characteristic time scale of the overall cell collective patterning.…”

Section: Basic Mathematical Modelmentioning

confidence: 99%

“…On the right hand side, F i instead denotes the sum of all forces influencing cell behavior. However, in order to simplify the picture, we can first notice that cells move in extremely viscous environments, characterized by very small Reynolds numbers: inertial effects in cell dynamics can therefore be neglected, if a sufficiently large observation time is considered ( Liedekerke et al, 2015;Odell et al, 1981 ). In fact, in these conditions, biological cells can maintain a persistent ballistic locomotion only for a substantially small time, giving rise to straight displacements shorter than their typical dimensions.…”

Section: Basic Mathematical Modelmentioning

confidence: 99%

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Adhesion and volume constraints via nonlocal interactions determine cell organisation and migration profiles

Carrillo

Colombi

Scianna

2018

Journal of Theoretical Biology

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a b s t r a c tThe description of the cell spatial pattern and characteristic distances is fundamental in a wide range of physio-pathological biological phenomena, from morphogenesis to cancer growth. Discrete particle models are widely used in this field, since they are focused on the cell-level of abstraction and are able to preserve the identity of single individuals reproducing their behavior. In particular, a fundamental role in determining the usefulness and the realism of a particle mathematical approach is played by the choice of the intercellular pairwise interaction kernel and by the estimate of its parameters. The aim of the paper is to demonstrate how the concept of H-stability, deriving from statistical mechanics, can have important implications in this respect. For any given interaction kernel, it in fact allows to a priori predict the regions of the free parameter space that result in stable configurations of the system characterized by a finite and strictly positive minimal interparticle distance, which is fundamental when dealing with biological phenomena. The proposed analytical arguments are indeed able to restrict the range of possible variations of selected model coefficients, whose exact estimate however requires further investigations (e.g., fitting with empirical data), as illustrated in this paper by series of representative simulations dealing with cell colony reorganization, sorting phenomena and zebrafish embryonic development.

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Section: Basic Mathematical Modelmentioning

confidence: 99%

Section: Basic Mathematical Modelmentioning

confidence: 99%

Adhesion and volume constraints via nonlocal interactions determine cell organisation and migration profiles

Carrillo

Colombi

Scianna

2018

Journal of Theoretical Biology

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“…Here, F C X ij denotes the interaction force between a cell i and object j (X denotes an object which can be a cell or a piece of the sinusoid, see A-8), u ij the normal vector pointing from cell i to object j, A ij the interface between cell i and object j. An extension to tensors able to measure shear contributions is straightforward but not needed here (Liedekerke et al 2015). Table 1).…”

Section: Ad (A-4)mentioning

confidence: 99%

“…There is in the meanwhile a wide range of different single-cell-based models both on lattices and in lattice-free space. The pros and cons of different types of agentbased models have been discussed in-depth in Liedekerke et al (2015). Simulations with single-cell-based models can be considered as experiments in silico, i.e., on the were used, which had been constructed based on the following pipeline: (a) A stack of confocal laser scanning micrographs were transformed by image processing into a full 3D volume data set.…”

Section: Introductionmentioning

confidence: 99%

Model Prediction and Validation of an Order Mechanism Controlling the Spatiotemporal Phenotype of Early Hepatocellular Carcinoma

et al. 2018

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Recently, hepatocyte-sinusoid alignment (HSA) has been identified as a mechanism that supports the coordination of hepatocytes during liver regeneration to reestablish a functional micro-architecture (Hoehme et al. in Proc Natl Acad Sci 107(23): [10371][10372][10373][10374][10375][10376] 2010). HSA means that hepatocytes preferentially align along the closest micro-vessels. Here, we studied whether this mechanism is still active in early hepatocellular tumors. The same agent-based spatiotemporal model that previously correctly predicted HSA in liver regeneration was further developed to simulate scenarios in early tumor development, when individual initiated hepatocytes gain increased proliferation capacity. The model simulations were performed under conditions of realistic liver micro-architectures obtained from 3D reconstructions of confocal laser scanning micrographs. Interestingly, the established model predicted that initiated hepatocytes at first arrange in elongated patterns. Only when the tumor Stefan Hoehme, Francois Bertaux and Dirk Drasdo shared first authorship.

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“…In general, vertex-based and Cellular Potts models have similar capabilities in a static setting; the major differences emerge when they are used to model cellular growth. This discussion is not within the scope of this paper and is covered in detail elsewhere (Prusinkiewicz and Runions, 2012;Liedekerke et al, 2015).…”

Section: Model Constructionmentioning

confidence: 99%

Theoretical approaches to understanding root vascular patterning: a consensus between recent models

Mellor

Adibi

El‐Showk

et al. 2016

EXBOTJ

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A note on versions:The version presented here may differ from the published version or from the version of record. If you wish to cite this item you are advised to consult the publisher's version. Please see the repository url above for details on accessing the published version and note that access may require a subscription. AbstractThe root vascular tissues provide an excellent system for studying organ patterning, as the specification of these tissues signals a transition from radial symmetry to bisymmetric patterns. The patterning process is controlled by the combined action of hormonal signaling/transport pathways, transcription factors, and miRNA that operate through a series of non-linear pathways to drive pattern formation collectively. With the discovery of multiple components and feedback loops controlling patterning, it has become increasingly difficult to understand how these interactions act in unison to determine pattern formation in multicellular tissues. Three independent mathematical models of root vascular patterning have been formulated in the last few years, providing an excellent example of how theoretical approaches can complement experimental studies to provide new insights into complex systems. In many aspects these models support each other; however, each study also provides its own novel findings and unique viewpoints. Here we reconcile these models by identifying the commonalities and exploring the differences between them by testing how transferable findings are between models. New simulations herein support the hypothesis that an asymmetry in auxin input can direct the formation of vascular pattern. We show that the xylem axis can act as a sole source of cytokinin and specify the correct pattern, but also that broader patterns of cytokinin production are also able to pattern the root. By comparing the three modeling approaches, we gain further insight into vascular patterning and identify several key areas for experimental investigation.

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Simulating tissue mechanics with agent-based models: concepts, perspectives and some novel results

Cited by 229 publications

References 253 publications

Adhesion and volume constraints via nonlocal interactions determine cell organisation and migration profiles

Adhesion and volume constraints via nonlocal interactions determine cell organisation and migration profiles

Model Prediction and Validation of an Order Mechanism Controlling the Spatiotemporal Phenotype of Early Hepatocellular Carcinoma

Theoretical approaches to understanding root vascular patterning: a consensus between recent models

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