Extracellular matrix density regulates the rate of neovessel growth and branching in sprouting angiogenesis

Angiogenesis is regulated by the local microenvironment, including the mechanical interactions between neovessel sprouts and the extracellular matrix (ECM). However, the mechanisms controlling the relationship of mechanical and biophysical properties of the ECM to neovessel growth during sprouting a...

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Veröffentlicht in:	PloS one 2014-01, Vol.9 (1), p.e85178
Hauptverfasser:	Edgar, Lowell T, Underwood, Clayton J, Guilkey, James E, Hoying, James B, Weiss, Jeffrey A
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Analysis Angiogenesis Animals Bioengineering Biology Boundary conditions Cell adhesion & migration Collagen Collagen - metabolism Collagen - physiology Computation Computer applications Computer Science Computer Simulation Coronary vessels Culture Deformation mechanisms Density Endothelial Cells - drug effects Endothelial Cells - physiology Engineering Extracellular matrix Extracellular Matrix - metabolism Extracellular Matrix - physiology Gels Growth Growth models Growth rate Male Mathematical models Mechanical properties Mechanical stimuli Medicine Microscopy, Confocal Microscopy, Phase-Contrast Microvasculature Microvessels - cytology Microvessels - drug effects Microvessels - growth & development Models, Biological Morphogenesis Neovascularization, Physiologic - drug effects Neovascularization, Physiologic - physiology Network formation Organ culture Organ Culture Techniques - methods Rats Rats, Sprague-Dawley Scaling Stem cells Stiffness Studies Three dimensional models Time Factors Topology Vascular Endothelial Growth Factor A - pharmacology
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description	Angiogenesis is regulated by the local microenvironment, including the mechanical interactions between neovessel sprouts and the extracellular matrix (ECM). However, the mechanisms controlling the relationship of mechanical and biophysical properties of the ECM to neovessel growth during sprouting angiogenesis are just beginning to be understood. In this research, we characterized the relationship between matrix density and microvascular topology in an in vitro 3D organ culture model of sprouting angiogenesis. We used these results to design and calibrate a computational growth model to demonstrate how changes in individual neovessel behavior produce the changes in vascular topology that were observed experimentally. Vascularized gels with higher collagen densities produced neovasculatures with shorter vessel lengths, less branch points, and reduced network interconnectivity. The computational model was able to predict these experimental results by scaling the rates of neovessel growth and branching according to local matrix density. As a final demonstration of utility of the modeling framework, we used our growth model to predict several scenarios of practical interest that could not be investigated experimentally using the organ culture model. Increasing the density of the ECM significantly reduced angiogenesis and network formation within a 3D organ culture model of angiogenesis. Increasing the density of the matrix increases the stiffness of the ECM, changing how neovessels are able to deform and remodel their surroundings. The computational framework outlined in this study was capable of predicting this observed experimental behavior by adjusting neovessel growth rate and branching probability according to local ECM density, demonstrating that altering the stiffness of the ECM via increasing matrix density affects neovessel behavior, thereby regulated vascular topology during angiogenesis.
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However, the mechanisms controlling the relationship of mechanical and biophysical properties of the ECM to neovessel growth during sprouting angiogenesis are just beginning to be understood. In this research, we characterized the relationship between matrix density and microvascular topology in an in vitro 3D organ culture model of sprouting angiogenesis. We used these results to design and calibrate a computational growth model to demonstrate how changes in individual neovessel behavior produce the changes in vascular topology that were observed experimentally. Vascularized gels with higher collagen densities produced neovasculatures with shorter vessel lengths, less branch points, and reduced network interconnectivity. The computational model was able to predict these experimental results by scaling the rates of neovessel growth and branching according to local matrix density. As a final demonstration of utility of the modeling framework, we used our growth model to predict several scenarios of practical interest that could not be investigated experimentally using the organ culture model. Increasing the density of the ECM significantly reduced angiogenesis and network formation within a 3D organ culture model of angiogenesis. Increasing the density of the matrix increases the stiffness of the ECM, changing how neovessels are able to deform and remodel their surroundings. The computational framework outlined in this study was capable of predicting this observed experimental behavior by adjusting neovessel growth rate and branching probability according to local ECM density, demonstrating that altering the stiffness of the ECM via increasing matrix density affects neovessel behavior, thereby regulated vascular topology during angiogenesis.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>24465500</pmid><doi>10.1371/journal.pone.0085178</doi><tpages>e85178</tpages><oa>free_for_read</oa></addata></record>
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subjects	Algorithms Analysis Angiogenesis Animals Bioengineering Biology Boundary conditions Cell adhesion & migration Collagen Collagen - metabolism Collagen - physiology Computation Computer applications Computer Science Computer Simulation Coronary vessels Culture Deformation mechanisms Density Endothelial Cells - drug effects Endothelial Cells - physiology Engineering Extracellular matrix Extracellular Matrix - metabolism Extracellular Matrix - physiology Gels Growth Growth models Growth rate Male Mathematical models Mechanical properties Mechanical stimuli Medicine Microscopy, Confocal Microscopy, Phase-Contrast Microvasculature Microvessels - cytology Microvessels - drug effects Microvessels - growth & development Models, Biological Morphogenesis Neovascularization, Physiologic - drug effects Neovascularization, Physiologic - physiology Network formation Organ culture Organ Culture Techniques - methods Rats Rats, Sprague-Dawley Scaling Stem cells Stiffness Studies Three dimensional models Time Factors Topology Vascular Endothelial Growth Factor A - pharmacology
title	Extracellular matrix density regulates the rate of neovessel growth and branching in sprouting angiogenesis
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