Lattice and continuum modelling of a bioactive porous tissue scaffold.

IF 0.8 4区 数学 Q4 BIOLOGY Mathematical Medicine and Biology-A Journal of the Ima Pub Date : 2019-09-02 DOI:10.1093/imammb/dqy012
Andrew L Krause, Dmitry Beliaev, Robert A Van Gorder, Sarah L Waters
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引用次数: 5

Abstract

A contemporary procedure to grow artificial tissue is to seed cells onto a porous biomaterial scaffold and culture it within a perfusion bioreactor to facilitate the transport of nutrients to growing cells. Typical models of cell growth for tissue engineering applications make use of spatially homogeneous or spatially continuous equations to model cell growth, flow of culture medium, nutrient transport and their interactions. The network structure of the physical porous scaffold is often incorporated through parameters in these models, either phenomenologically or through techniques like mathematical homogenization. We derive a model on a square grid lattice to demonstrate the importance of explicitly modelling the network structure of the porous scaffold and compare results from this model with those from a modified continuum model from the literature. We capture two-way coupling between cell growth and fluid flow by allowing cells to block pores, and by allowing the shear stress of the fluid to affect cell growth and death. We explore a range of parameters for both models and demonstrate quantitative and qualitative differences between predictions from each of these approaches, including spatial pattern formation and local oscillations in cell density present only in the lattice model. These differences suggest that for some parameter regimes, corresponding to specific cell types and scaffold geometries, the lattice model gives qualitatively different model predictions than typical continuum models. Our results inform model selection for bioactive porous tissue scaffolds, aiding in the development of successful tissue engineering experiments and eventually clinically successful technologies.

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生物活性多孔组织支架的晶格和连续体建模。
当代培育人工组织的一种方法是将细胞植入多孔生物材料支架,并在灌注生物反应器中培养,以促进营养物质向生长细胞的运输。组织工程应用的典型细胞生长模型利用空间均匀或空间连续方程来模拟细胞生长、培养基流动、营养物质运输及其相互作用。物理多孔支架的网络结构通常通过这些模型中的参数被纳入,无论是现象学上的还是通过数学均匀化等技术。我们在方形网格上推导了一个模型,以证明明确模拟多孔支架网络结构的重要性,并将该模型的结果与文献中修改的连续体模型的结果进行了比较。我们捕获了细胞生长和流体流动之间的双向耦合,通过允许细胞阻塞毛孔,并通过允许流体的剪切应力影响细胞的生长和死亡。我们探索了这两种模型的一系列参数,并展示了每种方法预测之间的定量和定性差异,包括空间模式形成和仅在晶格模型中存在的细胞密度的局部振荡。这些差异表明,对于某些参数制度,对应于特定的细胞类型和支架几何形状,晶格模型给出的模型预测在质量上不同于典型的连续体模型。我们的研究结果为生物活性多孔组织支架的模型选择提供了信息,有助于成功的组织工程实验和最终临床成功技术的发展。
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来源期刊
CiteScore
2.20
自引率
0.00%
发文量
15
审稿时长
>12 weeks
期刊介绍: Formerly the IMA Journal of Mathematics Applied in Medicine and Biology. Mathematical Medicine and Biology publishes original articles with a significant mathematical content addressing topics in medicine and biology. Papers exploiting modern developments in applied mathematics are particularly welcome. The biomedical relevance of mathematical models should be demonstrated clearly and validation by comparison against experiment is strongly encouraged. The journal welcomes contributions relevant to any area of the life sciences including: -biomechanics- biophysics- cell biology- developmental biology- ecology and the environment- epidemiology- immunology- infectious diseases- neuroscience- pharmacology- physiology- population biology
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