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Literature DB >> 8953213

A mechanical model for the formation of vascular networks in vitro.

D Manoussaki¹, S R Lubkin, R B Vernon, J D Murray.

Abstract

Endothelial cells, when cultured on gelled basement membrane matrix exert forces of tension through which they deform the matrix and at the same time they aggregate into clusters. The cells eventually form a network of cord-like structures connecting cell aggregates. In this network, almost all of the matrix has been pulled underneath the cell cords and cell clusters. This phenomenon has been proposed as a possible model for the growth and development of planar vascular systems in vitro. Our hypothesis is that the matrix is reorganized and the cellular networks form as a result of traction forces exerted by the cells on the matrix and the latter's elasticity. We construct and analyze a mathematical model based on this hypothesis and examine conditions necessary for the formation of the pattern. We show cell migration is not necessary for pattern formation and that isotropic, strain-stimulated traction is sufficient to form the observed patterns.

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Year: 1996 PMID： 8953213 DOI： 10.1007/bf00046533

Source DB: PubMed Journal: Acta Biotheor ISSN： 0001-5342 Impact factor: 1.774

9 in total

1. Reorganization of basement membrane matrices by cellular traction promotes the formation of cellular networks in vitro.

Authors: R B Vernon; J C Angello; M L Iruela-Arispe; T F Lane; E H Sage
Journal: Lab Invest Date: 1992-05 Impact factor: 5.662

2. Organized type I collagen influences endothelial patterns during "spontaneous angiogenesis in vitro": planar cultures as models of vascular development.

Authors: R B Vernon; S L Lara; C J Drake; M L Iruela-Arispe; J C Angello; C D Little; T N Wight; E H Sage
Journal: In Vitro Cell Dev Biol Anim Date: 1995-02 Impact factor: 2.416

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Authors: T J Poole; J D Coffin
Journal: J Exp Zool Date: 1989-08

Review 4. Between molecules and morphology. Extracellular matrix and creation of vascular form.

Authors: R B Vernon; E H Sage
Journal: Am J Pathol Date: 1995-10 Impact factor: 4.307

5. Constitutive equations for fibrous connective tissues.

Authors: Y Lanir
Journal: J Biomech Date: 1983 Impact factor: 2.712

6. A mechanical model for mesenchymal morphogenesis.

Authors: J D Murray; G F Oster; A K Harris
Journal: J Math Biol Date: 1983 Impact factor: 2.259

7. Fibroblast traction as a mechanism for collagen morphogenesis.

Authors: A K Harris; D Stopak; P Wild
Journal: Nature Date: 1981-03-19 Impact factor: 49.962

8. Silicone rubber substrata: a new wrinkle in the study of cell locomotion.

Authors: A K Harris; P Wild; D Stopak
Journal: Science Date: 1980-04-11 Impact factor: 47.728

Review 9. Regulation of angiogenesis by extracellular matrix: the growth and the glue.

Authors: E H Sage; R B Vernon
Journal: J Hypertens Suppl Date: 1994-12

9 in total

47 in total

1. Modeling the early stages of vascular network assembly.

Authors: Guido Serini; Davide Ambrosi; Enrico Giraudo; Andrea Gamba; Luigi Preziosi; Federico Bussolino
Journal: EMBO J Date: 2003-04-15 Impact factor: 11.598

Review 2. Mathematical modeling of tumor-induced angiogenesis.

Authors: Nikos V Mantzaris; Steve Webb; Hans G Othmer
Journal: J Math Biol Date: 2004-02-06 Impact factor: 2.259

3. An investigation of the influence of extracellular matrix anisotropy and cell-matrix interactions on tissue architecture.

Authors: R J Dyson; J E F Green; J P Whiteley; H M Byrne
Journal: J Math Biol Date: 2015-09-02 Impact factor: 2.259

A mechanical model for the formation of vascular networks in vitro.

1. Reorganization of basement membrane matrices by cellular traction promotes the formation of cellular networks in vitro.

2. Organized type I collagen influences endothelial patterns during "spontaneous angiogenesis in vitro": planar cultures as models of vascular development.

3. Vasculogenesis and angiogenesis: two distinct morphogenetic mechanisms establish embryonic vascular pattern.

Review 4. Between molecules and morphology. Extracellular matrix and creation of vascular form.

5. Constitutive equations for fibrous connective tissues.

6. A mechanical model for mesenchymal morphogenesis.

7. Fibroblast traction as a mechanism for collagen morphogenesis.

8. Silicone rubber substrata: a new wrinkle in the study of cell locomotion.

Review 9. Regulation of angiogenesis by extracellular matrix: the growth and the glue.

1. Modeling the early stages of vascular network assembly.

Review 2. Mathematical modeling of tumor-induced angiogenesis.

3. An investigation of the influence of extracellular matrix anisotropy and cell-matrix interactions on tissue architecture.

4. Cell elongation is key to in silico replication of in vitro vasculogenesis and subsequent remodeling.

5. Computational modeling of morphogenesis regulated by mechanical feedback.

6. Invasion from a cell aggregate--the roles of active cell motion and mechanical equilibrium.

Review 7. Multicellular sprouting during vasculogenesis.

8. Theoretical study of Beloussov's hyper-restoration hypothesis for mechanical regulation of morphogenesis.

9. Geometric control of capillary architecture via cell-matrix mechanical interactions.

10. A cell-based model of extracellular-matrix-guided endothelial cell migration during angiogenesis.