The modeling, fabrication, cell loading, and mechanical and in vitro biological testing of biomimetic, interlockable, laser-made, concentric 3D scaffolds are presented. The scaffolds are made by multiphoton polymerization of an organic-inorganic zirconium silicate. Their mechanical properties are theoretically modeled using finite elements analysis and experimentally measured using a Microsquisher(®). They are subsequently loaded with preosteoblastic cells, which remain live after 24 and 72 h. The interlockable scaffolds have maintained their ability to fuse with tissue spheroids. This work represents a novel technological platform, enabling the rapid, laser-based, in situ 3D tissue biofabrication.
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| http://dx.doi.org/10.1116/1.4922646 | DOI Listing |
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Burr-like, laser-made 3D microscaffolds for tissue spheroid encagement.
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June 2015
IESL-FORTH, N. Plastira 100, 70013 Heraklion, Greece; Three-Dimensional Technologies Division, Renato Archer Center for Information Technology, Campinas, São Paulo 13069-901, Brazil; and DIMAV, INMETRO, Xerem 25250-020, Rio de Janeiro, Brazil.
The modeling, fabrication, cell loading, and mechanical and in vitro biological testing of biomimetic, interlockable, laser-made, concentric 3D scaffolds are presented. The scaffolds are made by multiphoton polymerization of an organic-inorganic zirconium silicate. Their mechanical properties are theoretically modeled using finite elements analysis and experimentally measured using a Microsquisher(®).
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