dorsal/arxiv
View SchemaAnalyzing the Dynamic Relationship between Tumor Growth and Angiogenesis in a Two Dimensional Finite Element Model
| Authors | Eun Bo Shim, Yoo Seok Kim, Thomas S. Deisboeck |
|---|---|
| Categories | |
| ArXiv ID | q-bio/0703015 |
| URL | https://arxiv.org/abs/q-bio/0703015 |
Abstract
Employing a novel two-dimensional computational model we have simulated the feedback between angiogenesis and tumor growth dynamics. Analyzing vessel formation and elongation towards the concentration gradient of the tumor-derived angiogenetic basic fibroblast growth factor, bFGF, we assumed that prior to the blood vessels reaching the tumor surface, the resulting pattern of tumor growth is symmetric, circular with a common center point. However, after the vessels reach the tumor surface, we assumed that the growth rate of that particular cancer region is accelerated compared to the tumor surface section that lacks neo-vascularization. Therefore, the resulting asymmetric tumor growth pattern is biased towards the site of the nourishing vessels. The simulation results show over time an increase in vessel density, a decrease in vessel branching length, and an increase in fracticality of the vascular branching architecture. Interestingly, over time the fractal dimension displayed a sigmoidal pattern with a reduced rate increase at earlier and later tumor growth stages due to distinct characteristics in vessel length and density. The finding that, at later stages, higher vascular fracticality resulted in a marked increase of tumor slice volume provides further in silico evidence for a functional impact of vascular patterns on cancer growth.
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"abstract": "Employing a novel two-dimensional computational model we have simulated the\nfeedback between angiogenesis and tumor growth dynamics. Analyzing vessel\nformation and elongation towards the concentration gradient of the\ntumor-derived angiogenetic basic fibroblast growth factor, bFGF, we assumed\nthat prior to the blood vessels reaching the tumor surface, the resulting\npattern of tumor growth is symmetric, circular with a common center point.\nHowever, after the vessels reach the tumor surface, we assumed that the growth\nrate of that particular cancer region is accelerated compared to the tumor\nsurface section that lacks neo-vascularization. Therefore, the resulting\nasymmetric tumor growth pattern is biased towards the site of the nourishing\nvessels. The simulation results show over time an increase in vessel density, a\ndecrease in vessel branching length, and an increase in fracticality of the\nvascular branching architecture. Interestingly, over time the fractal dimension\ndisplayed a sigmoidal pattern with a reduced rate increase at earlier and later\ntumor growth stages due to distinct characteristics in vessel length and\ndensity. The finding that, at later stages, higher vascular fracticality\nresulted in a marked increase of tumor slice volume provides further in silico\nevidence for a functional impact of vascular patterns on cancer growth.",
"arxiv_id": "q-bio/0703015",
"authors": [
"Eun Bo Shim",
"Yoo Seok Kim",
"Thomas S. Deisboeck"
],
"categories": [
"q-bio.TO"
],
"title": "Analyzing the Dynamic Relationship between Tumor Growth and Angiogenesis in a Two Dimensional Finite Element Model",
"url": "https://arxiv.org/abs/q-bio/0703015"
},
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