Leachable-Free Fabrication of Hydrogel Foams Enabling Homogeneous Viability of Encapsulated Cells in Large-Volume Constructs
authors Salvador, T; Oliveira, MB; Mano, JF
nationality International
journal ADVANCED HEALTHCARE MATERIALS
author keywords 3D hydrogels; air bubbles; cell encapsulation; hydrogel foams
keywords CHITOSAN SCAFFOLDS; STEM-CELLS; TISSUE; POROSITY; DEXAMETHASONE; SIZE
abstract The popularity of cell-laden injectable hydrogels has steeply increased due to their compatibility with minimally invasive surgical procedures. However, the diffusion of indispensable molecules for cell survival through bulk hydrogel structures, particularly oxygen, is often limited to micrometric distances, often hampering cell viability or uniform tissue formation in constructs with clinically relevant sizes. The introduction of micropores in hydrogels or the use of oxygen-generating materials has enabled combining advantages of porous 3D scaffolds with the injectability properties of in situ-solidifying hydrogels. Here, cell-laden injectable gelatin methacryloyl (GelMA) foams are fabricated using a single polymer formulation. Air bubbles are introduced into GelMA solutions using a simple-to-implement method based on pulling/pushing the solution through a syringe. Human mesenchymal stem cells derived from the adipose tissue (hASCs) cultured in bulk hydrogels (diameter c.a. 5 mm) show low permanence in the core of the materials and stain for factors associated to hypoxia (hypoxia-inducible factor-1 alpha (HIF-1 alpha)) after 7 days of culture. In opposition, cells cultured in optimized foams do not stain for HIF-1 alpha, show high permanence, homogeneous viability, and consistent phenotype in the whole depth of the biomaterials, while secreting increased amounts of regenerative growth factors to the surrounding medium.
publisher WILEY
issn 2192-2640
isbn 2192-2659
year published 2020
volume 9
issue 20
digital object identifier (doi) 10.1002/adhm.202000543
web of science category Engineering, Biomedical; Nanoscience & Nanotechnology; Materials Science, Biomaterials
subject category Engineering; Science & Technology - Other Topics; Materials Science
unique article identifier WOS:000567459400001
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journal analysis (jcr 2019):
journal impact factor 7.367
5 year journal impact factor 6.964
category normalized journal impact factor percentile 87.158
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