A discrete in continuous mathematical model of cardiac progenitor cells formation and growth as spheroid clusters (Cardiospheres)

被引：9

作者：

Di Costanzo, Ezio ^{[1
]}

Giacomello, Alessandro ^{[2
]}

Messina, Elisa ^{[3
]}

Natalini, Roberto ^{[1
]}

Pontrelli, Giuseppe ^{[1
]}

Rossi, Fabrizio ^{[2
]}

Smits, Robert ^{[4
]}

Twarogowska, Monika ^{[1
]}

机构：

[1] CNR, Ist Applicaz Calcolo, Via Taurini 19, I-00185 Rome, Italy

[2] Sapienza Univ Rome, Bolognetti Fdn, Pasteur Inst Cenci, Dept Mol Med, Viale Policlin, I-00161 Rome, Italy

[3] Sapienza Univ Rome, Dept Pediat Cardiol, Viale Regina Elena 324, I-00161 Rome, Italy

[4] New Mexico State Univ, Dept Math Sci, Las Cruces, NM 88003 USA

来源：

MATHEMATICAL MEDICINE AND BIOLOGY-A JOURNAL OF THE IMA | 2018年 / 35卷 / 01期

关键词：

mathematical biology; differential equations; hybrid models; Poisson stochastic process; collective dynamics; cell movements; cellular signalling; chemotaxis; stem cells; Cardiospheres; LATERAL-LINE PRIMORDIUM; COLLECTIVE MOTION; ZEBRAFISH; MIGRATION; DIFFERENTIATION; PROLIFERATION; EXPRESSION; HEART;

D O I：

10.1093/imammb/dqw022

中图分类号：

Q [生物科学];

学科分类号：

07 ; 0710 ; 09 ;

摘要：

We propose a discrete in continuous mathematical model describing the in vitro growth process of biophsy-derived mammalian cardiac progenitor cells growing as clusters in the form of spheres (Cardiospheres). The approach is hybrid: discrete at cellular scale and continuous at molecular level. In the present model, cells are subject to the self-organizing collective dynamics mechanism and, additionally, they can proliferate and differentiate, also depending on stochastic processes. The two latter processes are triggered and regulated by chemical signals present in the environment. Numerical simulations show the structure and the development of the clustered progenitors and are in a good agreement with the results obtained from in vitro experiments.

引用

页码：121 / 144

页数：24

共 50 条

[21] A DISCRETE MATHEMATICAL MODEL FOR SINGLE AND COLLECTIVE MOVEMENT IN AMOEBOID CELLS
Tarfulea, Nicoleta
JOURNAL OF BIOLOGICAL SYSTEMS, 2018, 26 (02) : 275 - 300
[22] Discrete Coupling and Synchronization in the Insulin Release in the Mathematical Model of the β Cells
Ontanon-Garcia, L. J.
Campos-Canton, E.
DISCRETE DYNAMICS IN NATURE AND SOCIETY, 2013, 2013
[23] Capillary network formation and structure in a modified discrete mathematical model of angiogenesis
Soltani, M.
BIOMEDICAL PHYSICS & ENGINEERING EXPRESS, 2022, 8 (01)
[24] A mathematical model for electrical stimulation of a monolayer of cardiac cells
Srinivasan, Ranjini
Roth, Bradley J.
BIOMEDICAL ENGINEERING ONLINE, 2004, 3 (1)
[25] A mathematical model for electrical stimulation of a monolayer of cardiac cells
Ranjini Srinivasan
Bradley J Roth
BioMedical Engineering OnLine, 3
[26] Discrete stochastic model for self-renewal and differentiation of progenitor cells
Sahimi, M
Mehrabi, AR
Naeim, F
PHYSICAL REVIEW E, 1997, 55 (03) : R2111 - R2114
[27] Mathematical model of the tumor cells’ population growth
Nishant Namdev
Himanshu Jain
Arvind Kumar Sinha
Network Modeling Analysis in Health Informatics and Bioinformatics, 12
[28] Mathematical model of the tumor cells' population growth
Namdev, Nishant
Jain, Himanshu
Sinha, Arvind Kumar
NETWORK MODELING AND ANALYSIS IN HEALTH INFORMATICS AND BIOINFORMATICS, 2022, 12 (01):
[29] Analysis of a mathematical model for the growth of cancer cells
Kohlmann, Martin
MATHEMATICAL MEDICINE AND BIOLOGY-A JOURNAL OF THE IMA, 2013, 30 (02): : 175 - 189
[30] A two-fluid model for the formation of clusters close to a continuous or almost continuous transition
Harald Pleiner
Helmut R. Brand
Rheologica Acta, 2021, 60 : 675 - 690

← 1 2 3 4 5 →