14 research outputs found
Computational methodology to determine fluid related parameters on non regular three-dimensional scaffolds
The application of three-dimensional (3D) biomaterials
to facilitate the adhesion, proliferation, and differentiation
of cells has been widely studied for tissue engineering
purposes. The fabrication methods used to improve the
mechanical response of the scaffold produce complex and
non regular structures. Apart from the mechanical aspect, the
fluid behavior in the inner part of the scaffold should also be
considered. Parameters such as permeability (k) or wall shear
stress (WSS) are important aspects in the provision of
nutrients, the removal of metabolic waste products or the
mechanically-induced differentiation of cells attached in the
trabecular network of the scaffolds. Experimental measurements
of these parameters are not available in all labs.
However, fluid parameters should be known prior to other
types of experiments. The present work compares an
experimental study with a computational fluid dynamics
(CFD) methodology to determine the related fluid parameters
(k and WSS) of complex non regular poly(L-lactic acid)
scaffolds based only on the treatment of microphotographic
images obtained with a microCT (lCT). The CFD analysis
shows similar tendencies and results with low relative
difference compared to those of the experimental study, for
high flow rates. For low flow rates the accuracy of this
prediction reduces. The correlation between the computational
and experimental results validates the robustness of the
proposed methodology.The authors gratefully acknowledge research support from the Spanish Ministry of Science and Innovation through research project DPI2010-20399-C04-01. The Instituto de Salud Carlos III (ISCIII) through the CIBER initiative and the Platform for Biological Tissue Characterization of the Centro de Investigacion Biomedica en Red en Bioingenieria, Biomateriales y Nanomedicina (CIBER-BBN) are also gratefully acknowledged.Acosta SantamarĂa, VA.; MalvĂ©, M.; Duizabo, A.; Mena Tobar, A.; Gallego Ferrer, G.; GarcĂa Aznar, J.; Doblare Castellano, M.... (2013). Computational methodology to determine fluid related parameters on non regular three-dimensional scaffolds. Annals of Biomedical Engineering. 41(11):2367-2380. https://doi.org/10.1007/s10439-013-0849-8S236723804111Acosta SantamarĂa, V., H. Deplaine, D. MariggiĂł, A. R. Villanueva-Molines, J. M. GarcĂa-Aznar, J. L. GĂłmez Ribelles, M. DoblarĂ©, G. Gallego Ferrer, and I. Ochoa. 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Modulating gradients in regulatory signals within mesenchymal stem cell seeded hydrogels: a novel strategy to engineer zonal articular cartilage.
This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.Engineering organs and tissues with the spatial composition and organisation of their native equivalents remains a major challenge. One approach to engineer such spatial complexity is to recapitulate the gradients in regulatory signals that during development and maturation are believed to drive spatial changes in stem cell differentiation. Mesenchymal stem cell (MSC) differentiation is known to be influenced by both soluble factors and mechanical cues present in the local microenvironment. The objective of this study was to engineer a cartilaginous tissue with a native zonal composition by modulating both the oxygen tension and mechanical environment thorough the depth of MSC seeded hydrogels. To this end, constructs were radially confined to half their thickness and subjected to dynamic compression (DC). Confinement reduced oxygen levels in the bottom of the construct and with the application of DC, increased strains across the top of the construct. These spatial changes correlated with increased glycosaminoglycan accumulation in the bottom of constructs, increased collagen accumulation in the top of constructs, and a suppression of hypertrophy and calcification throughout the construct. Matrix accumulation increased for higher hydrogel cell seeding densities; with DC further enhancing both glycosaminoglycan accumulation and construct stiffness. The combination of spatial confinement and DC was also found to increase proteoglycan-4 (lubricin) deposition toward the top surface of these tissues. In conclusion, by modulating the environment through the depth of developing constructs, it is possible to suppress MSC endochondral progression and to engineer tissues with zonal gradients mimicking certain aspects of articular cartilage.Funding was provided by Science Foundation Ireland (President of Ireland Young Researcher Award: 08/Y15/B1336) and the European Research Council (StemRepair – Project number 258463)