Additive manufacturing of photo-crosslinked gelatin scaffolds for adipose tissue engineering

[Display omitted] There exists a clear clinical need for adipose tissue reconstruction strategies to repair soft tissue defects which outperform the currently available approaches. In this respect, additive manufacturing has shown to be a promising alternative for the development of larger construct...

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Bibliographic Details
Published in:Acta biomaterialia 2019-08, Vol.94, p.340-350
Main Authors: Tytgat, Liesbeth, Van Damme, Lana, Van Hoorick, Jasper, Declercq, Heidi, Thienpont, Hugo, Ottevaere, Heidi, Blondeel, Phillip, Dubruel, Peter, Van Vlierberghe, Sandra
Format: Article
Language:English
Subjects:
Additive manufacturing
Adipose tissue
Adipose tissue engineering
Biodegradability
Biodegradation
Cell differentiation
Crosslinking
Extrusion
Extrusion-based 3D printing
Gelatin
Hydrogels
Macromolecules
Manufacturing
Methacrylamide
Organic chemistry
Phase separation
Scaffolds
Soft tissues
Stem cells
Thiol-ene photo-click chemistry
Tissue engineering
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Summary:[Display omitted] There exists a clear clinical need for adipose tissue reconstruction strategies to repair soft tissue defects which outperform the currently available approaches. In this respect, additive manufacturing has shown to be a promising alternative for the development of larger constructs able to support adipose tissue engineering. In the present work, a thiol-ene photo-click crosslinkable gelatin hydrogel was developed which allowed extrusion-based additive manufacturing into porous scaffolds. To this end, norbornene-functionalized gelatin (Gel-NB) was combined with thiolated gelatin (Gel-SH). The application of a macromolecular gelatin-based thiolated crosslinker holds several advantages over conventional crosslinkers including cell-interactivity, less chance at phase separation between scaffold material and crosslinker and the formation of a more homogeneous network. Throughout the paper, these photo-click scaffolds were benchmarked to the conventional methacrylamide-modified gelatin (Gel-MA). The results indicated that stable scaffolds could be realized which were further characterized physico-chemically by performing swelling, mechanical and in vitro biodegradability assays. Furthermore, the seeded adipose tissue-derived stem cells (ASCs) remained viable (>90%) up to 14 days and were able to proliferate. In addition, the cells could be differentiated into the adipogenic lineage on the photo-click crosslinked scaffolds, thereby performing better than the cells supported by the frequently reported Gel-MA scaffolds. As a result, the developed photo-click crosslinked scaffolds can be considered a promising candidate towards adipose tissue engineering and a valuable alternative for the omnipresent Gel-MA. The field of adipose tissue engineering has emerged as a promising strategy to repair soft tissue defects. Herein, Gel-NB/Gel-SH gelatin-based hydrogel scaffolds were produced using extrusion-based additive manufacturing. Using a cell-interactive, thiolated gelatin crosslinker, a homogeneous network was formed and the risk of phase separation between norbornene-modified gelatin and macromolecular crosslinkers was reduced. UV-induced crosslinking of these materials is based on step growth polymerization which requires less free radicals to enable polymerization. Our results demonstrated the potential of the developed scaffolds, due to their favourable physico-chemical characteristics as well as their adipogenic differentiation potential when be
ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2019.05.062