Design criteria for a printed tissue engineering construct: A mathematical homogenization approach

R. J. Shipley, G. W. Jones, R. J. Dyson, B. G. Sengers, C. L. Bailey, C. J. Catt, C. P. Please, J. Malda

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    Abstract

    Cartilage tissue repair procedures currently under development aim to create a construct in which patient-derived cells are seeded and expanded ex vivo before implantation back into the body. The key challenge is producing physiologically realistic constructs that mimic real tissue structure and function. One option with vast potential is to print strands of material in a 3D structure called a scaffold that imitates the real tissue structure; the strands are composed of gel seeded with cells and so provide a template for cartilaginous tissue growth. The scaffold is placed in the construct and pumped with nutrient-rich culture medium to supply nutrients to the cells and remove waste products, thus promoting tissue growth. In this paper we use asymptotic homogenization to determine the effective flow and transport properties of such a printed scaffold system. These properties are used to predict the distribution of nutrient/waste products through the construct, and to specify design criteria for the scaffold that will optimize the growth of functional tissue. © 2009 Elsevier Ltd. All rights reserved.
    Original languageEnglish
    Pages (from-to)489-502
    Number of pages13
    JournalJournal of Theoretical Biology
    Volume259
    Issue number3
    DOIs
    Publication statusPublished - 7 Aug 2009

    Keywords

    • Averaging
    • Cartilage
    • Construct
    • Mathematical modelling
    • Perfusion
    • Scaffold
    • Species transport

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