FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels

FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels

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The objective of this computational study was to propose a rapid procedure in obtaining an estimation of elastic moduli of solid phases of porous natural-polymeric biomaterials used for bone tissue engineering. This procedure was based on the comparison of experimental results to finite element (FE)...

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Main Authors: L. Siad, J. Jing, J. Braux, M. Dubus, F. Velard, D. Laurent-Maquin, S. C. Gangloff, H. Kerdjoudj, R. Rahouadj, J. -F. Schmidt, J. -F. Ganghoffer
Format: Article
Language:English
Published: D. G. Pylarinos 2015-12-01
Series:Engineering, Technology & Applied Science Research
Subjects:
Porous biomaterials
finite elements
microtomography
elasticity.
Online Access:https://etasr.com/index.php/ETASR/article/view/606
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spelling doaj-9f640de44e8c4cb4b0666398f0ef42622020-12-02T17:25:27ZengD. G. PylarinosEngineering, Technology & Applied Science Research2241-44871792-80362015-12-0156FEA Based on 3D Micro-CT Images of Mesoporous Engineered HydrogelsL. Siad0J. Jing1J. Braux2M. Dubus3F. Velard4D. Laurent-Maquin5S. C. Gangloff6H. Kerdjoudj7R. Rahouadj8J. -F. Schmidt9J. -F. Ganghoffer10University of Champagne, FranceUniversity of Champagne, FranceUniversity of Champagne, FranceUniversity of Champagne, FranceUniversity of Champagne, FranceUniversity of Champagne, FranceUniversity of Champagne, FranceUniversity of Champagne, FranceUniversity of Lorraine, FranceUniversity of Lorraine, FranceUniversity of Lorraine, FranceThe objective of this computational study was to propose a rapid procedure in obtaining an estimation of elastic moduli of solid phases of porous natural-polymeric biomaterials used for bone tissue engineering. This procedure was based on the comparison of experimental results to finite element (FE) responses of parallelepiped so-called representative volume elements (rev) of the material at hand. To address this issue a series of quasi-static unconfined compression tests were designed and performed on three prepared cylindrical biopolymer samples. Subsequently, a computed tomography scan was performed on fabricated specimens and two 3D images were reconstructed. Various parallelepiped revs of different sizes and located at distinct places within both constructs were isolated and then analyzed under unconfined compressive loads using FE modelling. In this preliminary study, for the sake of simplicity, the dried biopolymer solid is assumed to be linear elastic. https://etasr.com/index.php/ETASR/article/view/606Porous biomaterialsfinite elementsmicrotomographyelasticity.
collection DOAJ
language English
format Article
sources DOAJ
author L. Siad
J. Jing
J. Braux
M. Dubus
F. Velard
D. Laurent-Maquin
S. C. Gangloff
H. Kerdjoudj
R. Rahouadj
J. -F. Schmidt
J. -F. Ganghoffer
spellingShingle L. Siad
J. Jing
J. Braux
M. Dubus
F. Velard
D. Laurent-Maquin
S. C. Gangloff
H. Kerdjoudj
R. Rahouadj
J. -F. Schmidt
J. -F. Ganghoffer
FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels
Engineering, Technology & Applied Science Research
Porous biomaterials
finite elements
microtomography
elasticity.
author_facet L. Siad
J. Jing
J. Braux
M. Dubus
F. Velard
D. Laurent-Maquin
S. C. Gangloff
H. Kerdjoudj
R. Rahouadj
J. -F. Schmidt
J. -F. Ganghoffer
author_sort L. Siad
title FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels
title_short FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels
title_full FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels
title_fullStr FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels
title_full_unstemmed FEA Based on 3D Micro-CT Images of Mesoporous Engineered Hydrogels
title_sort fea based on 3d micro-ct images of mesoporous engineered hydrogels
publisher D. G. Pylarinos
series Engineering, Technology & Applied Science Research
issn 2241-4487
1792-8036
publishDate 2015-12-01
description The objective of this computational study was to propose a rapid procedure in obtaining an estimation of elastic moduli of solid phases of porous natural-polymeric biomaterials used for bone tissue engineering. This procedure was based on the comparison of experimental results to finite element (FE) responses of parallelepiped so-called representative volume elements (rev) of the material at hand. To address this issue a series of quasi-static unconfined compression tests were designed and performed on three prepared cylindrical biopolymer samples. Subsequently, a computed tomography scan was performed on fabricated specimens and two 3D images were reconstructed. Various parallelepiped revs of different sizes and located at distinct places within both constructs were isolated and then analyzed under unconfined compressive loads using FE modelling. In this preliminary study, for the sake of simplicity, the dried biopolymer solid is assumed to be linear elastic.
topic Porous biomaterials
finite elements
microtomography
elasticity.
url https://etasr.com/index.php/ETASR/article/view/606
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