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Synergistic reinforcement of hydroxyapatite with graphene oxide for advanced bone regeneration
1  Department of Chemical, Biological, Pharmaceutical and Environmental Sciences, University of Messina, Messina, 98166, Italy
Academic Editor: Elisa Boanini

Abstract:

Introduction: Hydroxyapatite (HA) is a widely utilized bioactive ceramic in bone tissue engineering, valued for its exceptional biocompatibility and chemical resemblance to natural bone mineral. Despite these advantages, HA’s clinical application is often constrained by its intrinsic brittleness and poor mechanical performance. To overcome these drawbacks, graphene oxide (GO) is increasingly employed as a reinforcing agent. GO’s remarkable mechanical strength make it an ideal candidate to enhance the structural integrity of HA, leading to the development of HA/GO composite materials.

Methods: This study details a comprehensive synthesis protocol for HA/GO composites specifically designed to improve osteointegration. The materials were fabricated using a wet chemical precipitation method. During this process, HA nanoparticles were nucleated and grown directly in the presence of GO sheets. This approach was chosen to ensure a uniform distribution of the reinforcement phase and to promote strong interfacial bonding between the HA crystals and the GO functional groups.

Results: The synthesis protocol successfully produced a homogenous composite material. The integration of GO into the HA matrix addressed the primary limitation of ceramic brittleness, creating a more robust scaffold. Preliminary assessments indicate that the uniform dispersion of GO sheets facilitates a synergistic effect, where the mechanical properties of the graphene derivative complement the inherent bioactivity of the hydroxyapatite.

Conclusions: HA/GO composites represent a significant advancement in the development of biomaterials for bone regeneration. By combining mechanical robustness with a surface chemistry conducive to cell growth, these composites offer a promising solution for bone tissue applications. The results suggest that the HA/GO system provides a superior environment for effective osteointegration compared to pure HA scaffolds.

Keywords: Hydroxyapatite; Graphene Oxide; Bone Tissue Engineering; Osteointegration; Biomaterials.
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