Oksuz, Kerim EmreSen, IkerErsan, Mehtap2025-05-042025-05-0420241388-07641572-896Xhttps://doi.org/10.1007/s11051-024-06179-whttps://hdl.handle.net/20.500.12418/35606In this experimental study, calcium phosphate Ca-3(PO4)(2) nanopowders, in the form of nano-hydroxyapatite (n-HA), were successfully synthesized from sea urchin shells (Diadema setosum, Leske, 1778) via a process involving precipitation and heat treatment method at various calcination temperatures (800 to 1200 degrees C). The optimal conditions for producing n-HA with maximum free CaO content were determined using response surface methodology (RSM) through a Box-Behnken Design. Key findings demonstrated that calcination temperature, calcination time, and ball-milling time significantly influenced the free CaO content. The study identified that a calcination temperature of 1100.73 degrees C for 2.78 h for CaO derived from sea urchin shells, combined with a ball-milling time of 66.37 h, resulted in the highest purity of n-HA. The biosynthesized n-HA exhibited desirable characteristics for bone and dental restoration applications, as confirmed by comprehensive analyses of functional group vibrations, chemical structure/composition, molecular interactions, surface morphology, and particle size distribution. These findings underscore the potential of using invasive sea urchin shells as a sustainable and effective source for n-HA production in biomedical applications.en10.1007/s11051-024-06179-winfo:eu-repo/semantics/closedAccessBiomaterialsBiomedical useCalcinationNano-hydroxyapatiteCa-3(PO4)(2) nano powdersCaOResponse surface methodologyArticle26112-s2.0-85209537528Q2WOS:001360161600002Q3