Progress in the application of graphene and its derivatives to osteogenesis

“…As frequently reported in the literature, 52–55 the improvement in the cell behaviour observed for GL-coated scaffolds should be ascribed to the synergistic contribution of the surface chemistry, surface topography and roughness.…”

An integrated design strategy coupling additive manufacturing and matrix-assisted pulsed laser evaporation (MAPLE) towards the development of a new concept 3D scaffold with improved properties for tissue regeneration

“…As frequently reported in the literature, 52–55 the improvement in the cell behaviour observed for GL-coated scaffolds should be ascribed to the synergistic contribution of the surface chemistry, surface topography and roughness.…”

An integrated design strategy coupling additive manufacturing and matrix-assisted pulsed laser evaporation (MAPLE) towards the development of a new concept 3D scaffold with improved properties for tissue regeneration

“…Notably, graphene oxide exhibits considerable potential in biomedical applications, attributed to its nanoscale dimensions, expansive specific surface area, exceptional mechanical strength, significant biocompatibility, elevated electrical conductivity, and antimicrobial capabilities [40,41]. Guo et al investigated the interaction of graphene and its derivatives with stem cells in different materials, demonstrating that graphene oxide accelerates the osteogenic differentiation of mesenchymal stem cells from the bone marrow [42]. Wu et al produced graphene oxide-modified β-tricalcium phosphate bioceramics, with studies indicating that an optimal amount of graphene enhances piezoelectric properties and stimulates bone formation in vivo [38].…”

Microstructure and Biocompatibility of Graphene Oxide/BCZT Composite Ceramics via Fast Hot-Pressed Sintering

Development of an active agar aerogel with dual antioxidant and UV-blocking activities using chlorine-doped graphene quantum dots