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Controlled in vitro three-dimensional cell expansion requires culture conditions that optimise the biophysical micro-environment of the cells during proliferation. In this study, we propose an individual cell-based modelling platform for simulating the mechanics of cell expansion on microcarriers. T...

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Bibliographic Details
Published in:Computer methods in biomechanics and biomedical engineering 2013-01, Vol.16 (10), p.1071-1084
Main Authors: Smeets, Bart, Odenthal, Tim, Tijskens, Engelbert, Ramon, Herman, Oosterwyck, Hans Van
Format: Article
Language:English
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Summary:Controlled in vitro three-dimensional cell expansion requires culture conditions that optimise the biophysical micro-environment of the cells during proliferation. In this study, we propose an individual cell-based modelling platform for simulating the mechanics of cell expansion on microcarriers. The lattice-free, particle-based method considers cells as individual interacting particles that deform and move over time. The model quantifies how the mechanical micro-environment of individual cells changes during the time of confluency. A sensitivity analysis is performed, which shows that changes in the cell-specific properties of cell-cell adhesion and cell stiffness cause the strongest change in the mechanical micro-environment of the cells. Furthermore, the influence of the mechanical properties of cells and microbead is characterised. The mechanical micro-environment is strongly influenced by the adhesive properties and the size of the microbead. Simulations show that even in the absence of strong biological heterogeneity, a large heterogeneity in mechanical stresses can be expected purely due to geometric properties of the culture system. Supplemental data for this article can be accessed online.
ISSN:1025-5842
1476-8259
DOI:10.1080/10255842.2013.829461