Modeling TGF-β in Early Stages of Cancer Tissue Dynamics

Ascolani, Gianluca; Lió, Píetro

doi:10.1371/journal.pone.0088533

Cited by 7 publications

(11 citation statements)

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“…a mutated clone) moving only in a directed manner following self-adhesive and cross-adhesive cell-cell forces, as well as matrix interactions. Since TGF-β does not affect only tumour growth, but impacts also cell adhesion, 4 we model the interactions between TGF-β and integrins that influence the cell-cell and cell-matrix adhesive forces. The computational results show a range of heterogeneous invasion patterns, as a result of the opposite role of TGF-β in early and late stages of cancer.…”

mentioning

confidence: 99%

Mathematical modelling of cancer invasion: The multiple roles of TGF-β pathway on tumour proliferation and cell adhesion

Bitsouni

Chaplain

Eftimie

2017

Math. Models Methods Appl. Sci.

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In this paper, we develop a non-local mathematical model describing cancer cell invasion and movement as a result of integrin-controlled cell-cell adhesion and cell-matrix adhesion, and transforming growth factor-beta (TGF-β) effect on cell proliferation and adhesion, for two cancer cell populations with different levels of mutation. The model consists of partial integro-differential equations describing the dynamics of two cancer cell populations, coupled with ordinary differential equations describing the extracellular matrix (ECM) degradation and the production and decay of integrins, and with a parabolic PDE governing the evolution of TGF-β concentration. We prove the global This is an Open Access article published by World Scientific Publishing Company. It is distributed under the terms of the Creative Commons Attribution 4.0 (CC-BY) License. Further distribution of this work is permitted, provided the original work is properly cited.

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mentioning

confidence: 99%

Mathematical modelling of cancer invasion: The multiple roles of TGF-β pathway on tumour proliferation and cell adhesion

Bitsouni

Chaplain

Eftimie

2017

Math. Models Methods Appl. Sci.

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“…Mammary duct compartment. In order to describe the tissue dynamics as populations of healthy and mutated cells, we introduce a branching process based on the tissue scale model proposed in [ 2 ] where the cell populations are ρ ( ϕ , t ) and the index ϕ ∈ [0, Φ] represents the cell state which is identified with the cell phenotype.…”

Section: Resultsmentioning

confidence: 99%

“…TGF- β is among the most abundant growth factors in bone, and its role in skeletal metastases is established. It is deposited in the bone matrix by osteoblasts, released and activated during osteoclastic resorption, and it regulates bone development and remodelling [ 2 ]. Advanced cancers frequently escape growth inhibition by TGF- β , which also activates epithelial-mesenchymal transition (EMT) and invasion, promoting metastases.…”

Section: Introductionmentioning

confidence: 99%

“…In a recent work [ 2 ], we have modeled how TGF- β drives the formation of early neoplastic signature in breast and perturbs the bone remodelling process. Here, we present a multi-compartment mathematical model that aims at elucidating the effects of the TGF- β and the concomitant therapies in the three microenvironments (mammary duct, circulatory system and bone niche).…”

Section: Introductionmentioning

confidence: 99%

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Modelling Circulating Tumour Cells for Personalised Survival Prediction in Metastatic Breast Cancer

2015

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Ductal carcinoma is one of the most common cancers among women, and the main cause of death is the formation of metastases. The development of metastases is caused by cancer cells that migrate from the primary tumour site (the mammary duct) through the blood vessels and extravasating they initiate metastasis. Here, we propose a multi-compartment model which mimics the dynamics of tumoural cells in the mammary duct, in the circulatory system and in the bone. Through a branching process model, we describe the relation between the survival times and the four markers mainly involved in metastatic breast cancer (EPCAM, CD47, CD44 and MET). In particular, the model takes into account the gene expression profile of circulating tumour cells to predict personalised survival probability. We also include the administration of drugs as bisphosphonates, which reduce the formation of circulating tumour cells and their survival in the blood vessels, in order to analyse the dynamic changes induced by the therapy.We analyse the effects of circulating tumour cells on the progression of the disease providing a quantitative measure of the cell driver mutations needed for invading the bone tissue. Our model allows to design intervention scenarios that alter the patient-specific survival probability by modifying the populations of circulating tumour cells and it could be extended to other cancer metastasis dynamics.

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“…This discrete depletion models Marotti's hypothesis that osteocytes prompt the burial of osteoblasts when they become sufficiently covered with bone matrix [6,21]. In purely temporal settings, Moroz, Wimpenny et al [26,27] assume osteocytes to be generated at constant density in the matrix and removed in proportion to the level of mechanical stress, Ascolani and Liò [28] assume osteocytes to be generated in proportion to the number of osteoblasts and removed at a constant rate for one day after an explicit microfracture, and Graham, Ayati etal [29] consider a single remodelling event during which osteocytes are generated in proportion to the number of osteoblasts with a logistic rate of growth, and removed artificially at the start of the simulation to initiate the remodelling event. Several other models have included the effect of local mechanical stimuli onto bone remodelling events [30][31][32][33][34][35][36][37][38].…”

Section: Introductionmentioning

confidence: 96%

Osteocytes as a record of bone formation dynamics: A mathematical model of osteocyte generation in bone matrix

Buenzli

2015

Journal of Theoretical Biology

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The formation of new bone involves both the deposition of bone matrix, and the formation of a network of cells embedded within the bone matrix, called osteocytes. Osteocytes derive from bone-synthesising cells (osteoblasts) that become buried in bone matrix during bone deposition. The generation of osteocytes is a complex process that remains incompletely understood. Whilst osteoblast burial determines the density of osteocytes, the expanding network of osteocytes regulates in turn osteoblast activity and osteoblast burial. In this paper, a spatiotemporal continuous model is proposed to investigate the osteoblast-to-osteocyte transition. The aims of the model are (i) to link dynamic properties of osteocyte generation with properties of the osteocyte network imprinted in bone, and (ii) to investigate Marotti׳s hypothesis that osteocytes prompt the burial of osteoblasts when they become covered with sufficient bone matrix. Osteocyte density is assumed in the model to be generated at the moving bone surface by a combination of osteoblast density, matrix secretory rate, rate of entrapment, and curvature of the bone substrate, but is found to be determined solely by the ratio of the instantaneous burial rate and matrix secretory rate. Osteocyte density does not explicitly depend on osteoblast density nor curvature. Osteocyte apoptosis is also included to distinguish between the density of osteocyte lacuna and the density of live osteocytes. Experimental measurements of osteocyte lacuna densities are used to estimate the rate of burial of osteoblasts in bone matrix. These results suggest that: (i) burial rate decreases during osteonal infilling, and (ii) the control of osteoblast burial by osteocytes is likely to emanate as a collective signal from a large group of osteocytes, rather than from the osteocytes closest to the bone deposition front.

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Modeling TGF-β in Early Stages of Cancer Tissue Dynamics

Cited by 7 publications

References 58 publications

Mathematical modelling of cancer invasion: The multiple roles of TGF-β pathway on tumour proliferation and cell adhesion

Mathematical modelling of cancer invasion: The multiple roles of TGF-β pathway on tumour proliferation and cell adhesion

Modelling Circulating Tumour Cells for Personalised Survival Prediction in Metastatic Breast Cancer

Osteocytes as a record of bone formation dynamics: A mathematical model of osteocyte generation in bone matrix

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