A numerical model of heterogeneous surface strains in polymer scaffolds.

In vitro bone tissue growth inside porous scaffolds can be enhanced by macroscopic cyclic compression of the construct, but the heterogeneous strain generated inside the construct must be investigated to determine appropriate levels of compression. For this purpose a linear micro-finite element (muFE) technique based on micro-computed tomography (muCT) was verified for the calculation of local displacements inside polymer scaffolds, from which local strains may be estimated. Local displacements in the axial direction at the surface of microstructures inside the scaffold in 60 locations were calculated with the muFE model, based on compression simulation of a muCT reconstruction of the scaffold. These displacements were compared with accurately measured displacements in the axial direction in the same polymer scaffold at the same 60 locations, using a micro-compression chamber and muCT reconstructions of the scaffold under two fixed levels of compression (5% and 0%). The correlation between the calculated and the measured displacements, after correction for the dependence of the axial displacement on the axial position, was r=0.786 (r2=0.617). From this we conclude that the linear muFE model is suitable to estimate local surface strains inside polymer scaffolds for tissue engineering applications. This technique can not only be used to determine appropriate parameters such as the level of macroscopic compression in experimental design, but also to investigate the cellular response to local surface strains generated inside three-dimensional scaffolds.

[1]  Ying Yang,et al.  Using dihydropyridine-release strategies to enhance load effects in engineered human bone constructs. , 2006, Tissue engineering.

[2]  A. E. El Haj,et al.  Calcium‐channel activation and matrix protein upregulation in bone cells in response to mechanical strain , 2000, Journal of cellular biochemistry.

[3]  M. Mullender,et al.  Mechanotransduction of bone cellsin vitro: Mechanobiology of bone tissue , 2006, Medical and Biological Engineering and Computing.

[4]  I Naert,et al.  Individualised, micro CT-based finite element modelling as a tool for biomechanical analysis related to tissue engineering of bone. , 2004, Biomaterials.

[5]  L Ryd,et al.  Accurate accuracy assessment: review of basic principles. , 1999, Acta orthopaedica Scandinavica.

[6]  M. Ashby,et al.  Cellular solids: Structure & properties , 1988 .

[7]  Josep A Planell,et al.  Micro-finite element models of bone tissue-engineering scaffolds. , 2006, Biomaterials.

[8]  P Rüegsegger,et al.  Tissue stresses and strain in trabeculae of a canine proximal femur can be quantified from computer reconstructions. , 1999, Journal of biomechanics.

[9]  C Krettek,et al.  Effects of cyclic longitudinal mechanical strain and dexamethasone on osteogenic differentiation of human bone marrow stromal cells. , 2004, European cells & materials.

[10]  Christian G'Sell,et al.  Deformation and damage upon stretching of degradable polymers (PLA and PCL) , 2005 .

[11]  Ying Yang,et al.  Development of a 'mechano-active' scaffold for tissue engineering. , 2002, Biomaterials.

[12]  L. Lanyon,et al.  Cellular responses to mechanical loading in vitro , 1990, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[13]  Jack H. U. Brown Technology in Health Care , 1973 .

[14]  W C Hayes,et al.  Micro-compression: a novel technique for the nondestructive assessment of local bone failure. , 1998, Technology and health care : official journal of the European Society for Engineering and Medicine.

[15]  B. van Rietbergen,et al.  COMPUTATIONAL STRATEGIES FOR ITERATIVE SOLUTIONS OF LARGE FEM APPLICATIONS EMPLOYING VOXEL DATA , 1996 .