Literature DB >> 20037774

Tissue differentiation in an in vivo bioreactor: in silico investigations of scaffold stiffness.

Hanifeh Khayyeri1, Sara Checa, Magnus Tägil, Fergal J O'Brien, Patrick J Prendergast.   

Abstract

Scaffold design remains a main challenge in tissue engineering due to the large number of requirements that need to be met in order to create functional tissues in vivo. Computer simulations of tissue differentiation within scaffolds could serve as a powerful tool in elucidating the design requirements for scaffolds in tissue engineering. In this study, a lattice-based model of a 3D porous scaffold construct derived from micro CT and a mechano-biological simulation of a bone chamber experiment were combined to investigate the effect of scaffold stiffness on tissue differentiation inside the chamber. The results indicate that higher scaffold stiffness, holding pore structure constant, enhances bone formation. This study demonstrates that a lattice approach is very suitable for modelling scaffolds in mechano-biological simulations, since it can accurately represent the micro-porous geometries of scaffolds in a 3D environment and reduce computational costs at the same time.

Mesh:

Year:  2010        PMID: 20037774     DOI: 10.1007/s10856-009-3973-0

Source DB:  PubMed          Journal:  J Mater Sci Mater Med        ISSN: 0957-4530            Impact factor:   3.896


  29 in total

Review 1.  Engineering principles of clinical cell-based tissue engineering.

Authors:  George F Muschler; Chizu Nakamoto; Linda G Griffith
Journal:  J Bone Joint Surg Am       Date:  2004-07       Impact factor: 5.284

2.  The effect of pore size on cell adhesion in collagen-GAG scaffolds.

Authors:  F J O'Brien; B A Harley; I V Yannas; L J Gibson
Journal:  Biomaterials       Date:  2005-02       Impact factor: 12.479

3.  Random-walk models of cell dispersal included in mechanobiological simulations of tissue differentiation.

Authors:  M A Pérez; P J Prendergast
Journal:  J Biomech       Date:  2006-12-14       Impact factor: 2.712

4.  Corroboration of mechanoregulatory algorithms for tissue differentiation during fracture healing: Comparison with in vivo results.

Authors:  Hanna Isaksson; Corrinus C van Donkelaar; Rik Huiskes; Keita Ito
Journal:  J Orthop Res       Date:  2006-05       Impact factor: 3.494

5.  Simulation of tissue differentiation in a scaffold as a function of porosity, Young's modulus and dissolution rate: application of mechanobiological models in tissue engineering.

Authors:  Damien P Byrne; Damien Lacroix; Josep A Planell; Daniel J Kelly; Patrick J Prendergast
Journal:  Biomaterials       Date:  2007-09-25       Impact factor: 12.479

6.  A finite element study of mechanical stimuli in scaffolds for bone tissue engineering.

Authors:  C Sandino; J A Planell; D Lacroix
Journal:  J Biomech       Date:  2008-02-05       Impact factor: 2.712

Review 7.  Computer-aided design and finite-element modelling of biomaterial scaffolds for bone tissue engineering.

Authors:  Damien Lacroix; Josep A Planell; Patrick J Prendergast
Journal:  Philos Trans A Math Phys Eng Sci       Date:  2009-05-28       Impact factor: 4.226

8.  Gene expression by marrow stromal cells in a porous collagen-glycosaminoglycan scaffold is affected by pore size and mechanical stimulation.

Authors:  Elaine M Byrne; Eric Farrell; Louise A McMahon; Matthew G Haugh; Fergal J O'Brien; Veronica A Campbell; Patrick J Prendergast; Brian C O'Connell
Journal:  J Mater Sci Mater Med       Date:  2008-06-27       Impact factor: 3.896

9.  A mechano-regulatory bone-healing model incorporating cell-phenotype specific activity.

Authors:  Hanna Isaksson; Corrinus C van Donkelaar; Rik Huiskes; Keita Ito
Journal:  J Theor Biol       Date:  2008-02-09       Impact factor: 2.691

10.  Correlations between mechanical stress history and tissue differentiation in initial fracture healing.

Authors:  D R Carter; P R Blenman; G S Beaupré
Journal:  J Orthop Res       Date:  1988       Impact factor: 3.494
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  5 in total

1.  Biophysical Stimuli: A Review of Electrical and Mechanical Stimulation in Hyaline Cartilage.

Authors:  Juan J Vaca-González; Johana M Guevara; Miguel A Moncayo; Hector Castro-Abril; Yoshie Hata; Diego A Garzón-Alvarado
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Review 2.  Finite element method (FEM), mechanobiology and biomimetic scaffolds in bone tissue engineering.

Authors:  A Boccaccio; A Ballini; C Pappalettere; D Tullo; S Cantore; A Desiate
Journal:  Int J Biol Sci       Date:  2011-01-26       Impact factor: 6.580

3.  Three dimensional printed polylactic acid-hydroxyapatite composite scaffolds for prefabricating vascularized tissue engineered bone: An in vivo bioreactor model.

Authors:  Haifeng Zhang; Xiyuan Mao; Danyang Zhao; Wenbo Jiang; Zijing Du; Qingfeng Li; Chaohua Jiang; Dong Han
Journal:  Sci Rep       Date:  2017-11-10       Impact factor: 4.379

Review 4.  Utilization of Finite Element Analysis for Articular Cartilage Tissue Engineering.

Authors:  Chaudhry R Hassan; Yi-Xian Qin; David E Komatsu; Sardar M Z Uddin
Journal:  Materials (Basel)       Date:  2019-10-12       Impact factor: 3.623

5.  Enhanced Piezoelectric Fibered Extracellular Matrix to Promote Cardiomyocyte Maturation and Tissue Formation: A 3D Computational Model.

Authors:  Pau Urdeitx; Mohamed H Doweidar
Journal:  Biology (Basel)       Date:  2021-02-09
  5 in total

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