Preparing Biomedical CaCO3/HA Composite with Oyster Shell

Ziyang LIU; Zhen GENG; Zhaoyang LI

doi:10.15541/jim20190144

[1] S MEHDI S, T KHORASANI M, K EHSAN D et al. Synthesis methods for nanosized hydroxyapatite with diverse structures. Acta Biomater., 9, 7591-7621(2013).

[2] Y BASHA R, S SAMPATH K T, M DOBLE. Design of biocomposite materials for bone tissue regeneration. Mater. Sci. Eng. C,, 57, 452-463(2015).

[3] S FACCA, D LAHIRI, F FIORETTI et al. In vivo osseointegration of nanodesigned composite coatings on titanium implants. ACS Nano, 5, 4790-4799(2011).

[4] H RHAITI, A LAGHZIZIL, A SAOIABI et al. Surface properties of porous hydroxyapatite derived from natural phosphate. Mater. Chem. Phys., 136, 1022-1026(2012).

[5] Y ZHANG C, Y ZHANG S, P LIU X et al. Degradation behavior of MgF₂/HA composite coating on magnesium alloy in vitro. The Chinese Journal of Nonferrous Metals, 28, 766-773(2018).

[6] F LEMOS A, G ROCHA J H, F FERREIRA J M et al. Hydroxyapatite nano-powders produced hydrothermally from nacreous material. Journal of the European Ceramic Society, 26, 3639-3646(2006).

[7] S VECCCHIO K, X ZHANG, B MASSIE J et al. Conversion of bulk seashells to biocompatible hydroxyapatite for bone implants. Acta Biomaterials, 3, 910-918(2007).

[8] E LANDI, G CELOTTI, G LOGROSCINO et al. Carbonated hydroxyapatite as bone substitute. Journal of the European Ceramic Society, 23, 2931-2937(2003).

[9] L LI, J ZHU Y, W CAO S et al. Preparation and drug release properties of nanostructured CaCO₃ porous hollow microspheres. Journal of Inorganic Materials, 24, 166-170(2009).

[10] K GUAN J, Y XU Z, B CHEN et al. Preparation and properties of nanometer calcium carbonate/poly (L-lactide) composite materials. Journal of Clinical Rehabilitative Tissue Engineering Research, 12, 1889-1891(2008).

[11] H ZHAO, Y CHEN, M LI Z et al. Preparation of nanoribbon hydroxyapatite from discarded shells. Gansu Science and Technology, 32, 50-52(2016).

[12] H XUE Q, Z XING Y, Q ZHANG Q. Preparation technology of oyster hydroxyapatite porous material for bone repair. Int. J. Biomed. Eng., 41, 291-295(2018).

[13] L YANG S, Q GAO, T WANG H. Theoretical prediction of ring strain energies of several carbon-monocyclic and carbon-dicyclic compounds. Journal of Natural Science of Heilongjiang University, 27, 495-499(2010).

[14] S RUJITANAPANICH, P KUMPAPAN, P WANJANOI et al. Synthesis of hydroxyapatite from oyster shell via precipitation method. Energy Proc., 112-117(2014).

[15] M AKRAM, R AHMED, I SHAKIR et al. Extracting hydroxyapatite and its precursors from natural resources. J. Mater. Sci., 49, 1461-1475(2014).

[16] S NAYAR, A GUHA. Waste utilization for the controlled synthesis of nanosized hydroxyapatite. Mater. Sci. Eng., 29, 1326-1329(2009).

[17] E LANDI, S SPRIO, M SANDRI et al. Development of Sr and CO₃ co-substituted hydroxyapatites for biomedical applications. Acta Biomaterialia, 4, 656-663(2008).

[18] S MEEJOO, W MANEEPRAKORN, P WINOTAI. Phase and thermal stability of nanocrystalline hydroxyapatite prepared via microwave heating. Thermochimica Acta, 447, 115-120(2006).

[19] GF HU, LW XIAO, H FU et al. Study on injectable and degradable cement of calcium sulphate and calcium phosphate for bone repair. Journal of Materials Science: Materials in Medicine, 21, 627-634(2010).

[20] X QI, J YE, Y WANG. Improved injectability and in vitro degradation of a calcium phosphate cement containing poly (lactide-co- glycolide) microspheres. Acta Biomaterialia, 4, 1837-1845(2008).

[21] PALAKURTHY SRINATH, K VENU GOPAL REDDY, SAMUDRALA RAJ KUMAR et al. In vitro bioactivity and degradation behaviour of β-wollastonite derived from natural waste. Materials Science & Engineering, 98, 109-117(2019).