Antioxidant and antibacterial hydroxyapatite-based biocomposite for orthopedic applications

https://doi.org/10.1016/j.msec.2018.02.014Get rights and content

Highlights

  • Exploiting antioxidant property of ceria in hydroxyapatite (HA).

  • A novel aspect of introducing oxidative stress via incorporation of ZnO in HA.

  • Enhanced cell-growth (i.e. ~6.7 times!) via synergistic CeO2 and Ag reinforcements.

  • Expected rapid-healing post-implantation.

  • Added antibacterial functionality via Ag-reinforcement in HA-based composites.

Abstract

Post-implantation, vicinity acquired oxidative stress and bacterial infections lead to apoptosis with eventual bone-resorption and implant failure, respectively. Thus, in order to combat aforementioned complications, present research aims in utilizing antioxidant ceria (CeO2) and antibacterial silver (Ag) reinforced hydroxyapatite (HA) composite with enhanced mechanical and cytocompatible properties. Highly dense (>90%) spark plasma sintered HA-based composites elicits enhanced elastic modulus (121–133 GPa) in comparison to that of HA. The antioxidant activity is quantified using ceria alone, wherein HA-ceria and HA-ceria-Ag pellets exhibits ~36 and 30% antioxidant activity, respectively, accrediting ceria as a scavenger of reactive oxygen species, which was corroborated with the % Ce3+ change quantified by X-ray photoelectron spectroscopy. The HA-Ag pellet shows antibacterial efficacy of ~61% for E. coli and ~53% for S. aureus, while a reduction of ~59% for E. coli and ~50% for S. aureus is observed for HA-ceria-2.5Ag pellet, affirming Ag reinforcement as an established bactericidal agent. The enhanced hydrophobicity on all the HA-based composites affords a high protein adsorption (24 h incubation). Further, elevated hFOB cell count (~6.7 times for HA-ceria-Ag on day 7) with filopodial extensions (60–150 μm) and matrix-like deposition reflect cell-substrate intimacy. Thus, synergistic antioxidant ceria and antibacterial Ag reinforcement with enhanced mechanical integrity can potentially serve as cytocompatible porous bone scaffolds or bioactive coatings on femoral stems.

Keywords

Hydroxyapatite
Osteoblasts
Antibacterial
Antioxidant
Cytocompatible

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