In vitro Vasculogenesis Models Revisited - Measurement of VEGF Diffusion in Matrigel

T. Miura; R. Tanaka

Mathematical Modelling of Natural Phenomena (2009)

  • Volume: 4, Issue: 4, page 118-130
  • ISSN: 0973-5348

Abstract

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The circulatory system is one of the first to function during development. The earliest event in the system's development is vasculogenesis, whereby vascular progeniter cells form clusters called blood islands, which later fuse to form capillary networks. There exists a very good in vitro system that mimics this process. When HUVECs (Human Umbilical Vein Endothelial Cells) are cultured on Matrigel, they spontaneously form a capillary network structure. Two theoretical models have been proposed to explain the pattern formation of this in vitro system. Both models utilize chemotaxis to generate spatial instability, and one model specifies VEGF as the chemoattractant. However, there are several unknown factors concerning the experimental model. First, the pattern formation process occurs at the interface between the liquid medium and Matrigel, and it is unclear whether diffusion in the liquid or gel is critical. Second, the diffusion coefficient of VEGF, which determines the spatial scale of the capillary structure, has not been properly measured. In the present study, we modified the experimental system to clarify the effect of diffusion in Matrigel, and experimentally measured the diffusion coefficient of VEGF in this system. The relationship with the spatial scale of the pattern generated is discussed.

How to cite

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Miura, T., and Tanaka, R.. "In vitro Vasculogenesis Models Revisited - Measurement of VEGF Diffusion in Matrigel." Mathematical Modelling of Natural Phenomena 4.4 (2009): 118-130. <http://eudml.org/doc/222359>.

@article{Miura2009,
abstract = { The circulatory system is one of the first to function during development. The earliest event in the system's development is vasculogenesis, whereby vascular progeniter cells form clusters called blood islands, which later fuse to form capillary networks. There exists a very good in vitro system that mimics this process. When HUVECs (Human Umbilical Vein Endothelial Cells) are cultured on Matrigel, they spontaneously form a capillary network structure. Two theoretical models have been proposed to explain the pattern formation of this in vitro system. Both models utilize chemotaxis to generate spatial instability, and one model specifies VEGF as the chemoattractant. However, there are several unknown factors concerning the experimental model. First, the pattern formation process occurs at the interface between the liquid medium and Matrigel, and it is unclear whether diffusion in the liquid or gel is critical. Second, the diffusion coefficient of VEGF, which determines the spatial scale of the capillary structure, has not been properly measured. In the present study, we modified the experimental system to clarify the effect of diffusion in Matrigel, and experimentally measured the diffusion coefficient of VEGF in this system. The relationship with the spatial scale of the pattern generated is discussed. },
author = {Miura, T., Tanaka, R.},
journal = {Mathematical Modelling of Natural Phenomena},
keywords = {pattern formation; HUVEC; vascular endothelial growth factor (VEGF); diffusion; Matrigel},
language = {eng},
month = {7},
number = {4},
pages = {118-130},
publisher = {EDP Sciences},
title = {In vitro Vasculogenesis Models Revisited - Measurement of VEGF Diffusion in Matrigel},
url = {http://eudml.org/doc/222359},
volume = {4},
year = {2009},
}

TY - JOUR
AU - Miura, T.
AU - Tanaka, R.
TI - In vitro Vasculogenesis Models Revisited - Measurement of VEGF Diffusion in Matrigel
JO - Mathematical Modelling of Natural Phenomena
DA - 2009/7//
PB - EDP Sciences
VL - 4
IS - 4
SP - 118
EP - 130
AB - The circulatory system is one of the first to function during development. The earliest event in the system's development is vasculogenesis, whereby vascular progeniter cells form clusters called blood islands, which later fuse to form capillary networks. There exists a very good in vitro system that mimics this process. When HUVECs (Human Umbilical Vein Endothelial Cells) are cultured on Matrigel, they spontaneously form a capillary network structure. Two theoretical models have been proposed to explain the pattern formation of this in vitro system. Both models utilize chemotaxis to generate spatial instability, and one model specifies VEGF as the chemoattractant. However, there are several unknown factors concerning the experimental model. First, the pattern formation process occurs at the interface between the liquid medium and Matrigel, and it is unclear whether diffusion in the liquid or gel is critical. Second, the diffusion coefficient of VEGF, which determines the spatial scale of the capillary structure, has not been properly measured. In the present study, we modified the experimental system to clarify the effect of diffusion in Matrigel, and experimentally measured the diffusion coefficient of VEGF in this system. The relationship with the spatial scale of the pattern generated is discussed.
LA - eng
KW - pattern formation; HUVEC; vascular endothelial growth factor (VEGF); diffusion; Matrigel
UR - http://eudml.org/doc/222359
ER -

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