A comparative study of oxygen diffusion in tissue engineering scaffolds

Fiedler, T.; Belova, I. V.; Murch, G. E.; Poologasundarampillai, G.; Jones, J. R.; Roether, J. A.; Boccaccini, A. R.

Title: A comparative study of oxygen diffusion in tissue engineering scaffolds
Creator: Fiedler, T.; Belova, I. V.; Murch, G. E.; Poologasundarampillai, G.; Jones, J. R.; Roether, J. A.; Boccaccini, A. R.
Relation: Journal of Materials Science: Materials in Medicine Vol. 25, Issue 11, p. 2573-2578
Publisher Link: http://dx.doi.org/10.1007/s10856-014-5264-7
Publisher: Springer New York
Resource Type: journal article
Date: 2014
Description: Tissue engineering scaffolds are designed to support tissue self-healing within physiological environments by promoting the attachment, growth and differentiation of relevant cells. Newly formed tissue must be supplied with sufficient levels of oxygen to prevent necrosis. Oxygen diffusion is the major transport mechanism before vascularization is completed and oxygen is predominantly supplied via blood vessels. The present study compares different designs for scaffolds in the context of their oxygen diffusion ability. In all cases, oxygen diffusion is confined to the scaffold pores that are assumed to be completely occupied by newly formed tissue. The solid phase of the scaffolds acts as diffusion barrier that locally inhibits oxygen diffusion, i.e. no oxygen passes through the scaffold material. As a result, the oxygen diffusivity is determined by the scaffold porosity and pore architecture. Lattice Monte Carlo simulations are performed to compare the normalized oxygen diffusivities in scaffolds obtained by the foam replication (FR) method, robocasting and sol–gel foaming. Scaffolds made by the FR method were found to have the highest oxygen diffusivity due to their high porosity and interconnected pores. These structures enable the best oxygen supply for newly formed tissue among the scaffold types considered according to the present numerical predictions.
Subject: bioactive glass scaffold; oxygen barrier; colloidal crystal; lung tissue; thermal conductivity; tissue phase; cartilage tissue engineering; scaffold degredation; strut thickness; oxygen permeability; foam scaffold; foam replication titanium scaffold; scaffold wall; compressive strength
Identifier: http://hdl.handle.net/1959.13/1066253
Identifier: uon:18060
Identifier: ISSN:0957-4530
Language: eng
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