Synthesis and study of the cerium doped hydroxyapatite powders

Hydroxyapatite (HAp) is an attractive material for creating biocompatible implants owing to its osteoregenerative properties, elemental and phase similarity to bone tissue. The flexible structure of the material allows the introduction of ionic impurities to improve physicochemical and biological characteristics while maintaining the space symmetry group. Rare earth ions are a new step in improving compounds to create luminescent bioimaging agent for application in diagnostics imaging medicine. Nanosized powder of HAp doped with cerium ions (Ce-HAp) was obtained in order to study the impurity localization and its oxidizing state with conventional and pulsed electron paramagnetic resonance (EPR) at X-band. Undoped and doped HAp powders were synthesized via precipitation technique. It was revealed, that Ce-HAp powders after synthesis and heating exhibit luminescence in visible wavelength range (380 and 420 nm) that confirms the presence of Ce³⁺ in HAp structure. Heating of Ce-HAp in the air atmosphere results in formation of CeO₂ with low intensity of luminescence. EPR spectra of the doped sample confirms the Ce³⁺ incorporation into HAp structure. The powder-like EPR lineshape for the obtained powders can be simulated with g_∥ = 3.47 and g_⊥ = 0.51.

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