Herein, we report the cartilage tissue engineering application
of nanographene oxide (NGO)-reinforced gelatin hydrogel fabricated
by utilizing a microplasma-assisted cross-linking method. NGO sheets
with surface functionalities were introduced to enhance the mechanical
and biomedical properties of gelatin-based hydrogels. Highly energetic
reactive radicals were generated from the nonthermal plasma (NTP),
which is used to facilitate the cross-linking and polymerization during
the polymeric hydrogel fabrication. The NTP treatment substantially
reinforced a small amount (1 wt %) of NGO into the gelatin hydrogel.
Systematic material characterization thus shows that the fabricated
hydrogel possessed unique properties such as moderate surface roughness
and adhesiveness, suitable pores sizes, temperature-dependent viscoelasticity,
and controllable degradability. In vitro studies demonstrated that
the as-fabricated hydrogel exhibited excellent cell–material
interactions with SW 1353 cells, bone marrow-derived mesenchymal stem
cells, and a rat chondrocyte cell line, thereby exhibiting appropriate
cytocompatibility for cartilage tissue engineering applications. Furthermore,
an in vivo study indicated that the formation of a healthy hyaline
cartilage after the microfracture was enhanced by the fabricated hydrogel
implant, offering a potential biocompatible platform for microfracture-based
cartilage reconstructive surgery.
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