Deposition of Hydroxyapatite on Silica Made from Rice Husk Ash to Produce the Powder Component of Calcium Phosphate Cement
Tri Windarti(1*), Widjijono Widjijono(2), Nuryono Nuryono(3)
(1) Department of Chemistry, Faculty of Science and Mathematics, Universitas Diponegoro, Jl. Prof. Soedharto SH, Tembalang, Semarang 50275, Indonesia
(2) Department of Dental Biomaterials, Faculty of Dentistry, Universitas Gadjah Mada, Jl. Denta 1, Sekip Utara, Yogyakarta 55281, Indonesia
(3) Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Gadjah Mada, Sekip Utara, Yogyakarta 55281, Indonesia
(*) Corresponding Author
Abstract
Hydroxyapatite (HA) has been deposited on silica (SiO2) particles to produce HA-SiO2 composite that will be used as the powder component of calcium phosphate cement. HA was expected to be on the composite surface to maintain its bioactivity. SiO2 was made by the sol-gel method, in which silicate solution was extracted from rice husk ash with NaOH solution. Deposition of HA on SiO2 was carried out by wet chemical deposition method at various Ca/Si molar ratio (in a range of 5–25) followed by calcination at 600 °C for 2 h. Results showed that HA was successfully deposited on SiO2 particles. The cell parameters of the HA crystals were slightly distorted by the presence of SiO2 and HA in the composite had a bigger cell volume than pure HA. The crystallite size of HA in the composites increased with the increase of the Ca/Si ratio but the values were smaller than pure HA. SiO2 acted as a morphology directing agent. At low Ca/Si ratio, the HA-SiO2 particles were in a form of short rod-like particles with sizes of < 50 nm, while at high Ca/Si ratio, a mixture of short and long rod-like particles with the size of < 100 nm was obtained. The zeta potential of composites was almost similar to pure HA. These properties indicated that HA-SiO2 composites support the bioactivity of injectable calcium phosphate cement.
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[1] Larsson, S., Stadelmann, V.A., Arnoldi, J., Behrens, M., Hess, B., Procter, P., Murphy, M., and Pioletti, D.P., 2012, Injectable calcium phosphate cement for augmentation around cancellous bone screws. In vivo biomechanical studies, J. Biomech., 45 (7), 1156–1160.
[2] Apelt, D., Theiss, F., El-Warrak, A.O., Zlinszky, K., Bettschart-Wolfisberger, R., Bohner, M., Matter, S., Auer, J.A., and von Rechenberg, B., 2004, In vivo behavior of three different injectable hydraulic calcium phosphate cements, Biomaterials, 25 (7-8), 1439–1451.
[3] Heinemann, S., Rössler, S., Lemm, M., Ruhnow, M., and Nies, B., 2013, Properties of injectable ready-to-use calcium phosphate cement based on water-immiscible liquid, Acta Biomater., 9 (4), 6199–6207.
[4] Motisuke, M., Mestres, G., Renó, C.O., Carrodeguas, R.G., Zavaglia, C.A.C., and Ginebra, M.P., 2017, Influence of Si substitution on the reactivity of α-tricalcium phosphate, Mater. Sci. Eng., C, 75, 816–821.
[5] Zhou, S., Ma, J., Shen, Y., Haapasalo, M., Ruse, N.D., Yang, Q., and Troczynski, T., 2013, In vitro studies of calcium phosphate silicate bone cements, J. Mater. Sci. Mater. Med., 24 (2), 355–364.
[6] Sowjanya, J.A., Singh, J., Mohita, T., Sarvanan, S., Moorthi, A., Srinivasan, N., and Selvamurugan, N., 2013, Biocomposite scaffolds containing chitosan/alginate/nano-silica for bone tissue engineering, Colloids Surf., B, 109, 294–300.
[7] Sopcak, T., Medvecky, L., Giretova, M., Stulajterova, R., Durisin, J., Girman, V., and Faberova, M., 2016, Effect of phase composition of calcium silicate phosphate component on properties of brushite based composite cements, Mater. Charact., 117, 17–29.
[8] Heinemann, S., Heinemann, C., Wenisch, S., Alt, V., Worch, H., and Hanke, T., 2013, Calcium phosphate phases integrated in silica/collagen nanocomposite xerogels enhance the bioactivity and ultimately manipulate the osteoblast/osteoclast ratio in a human co-culture model, Acta Biomater., 9 (1), 4878–4888.
[9] Szurkowska, K., and Kolmas, J., 2017, Hydroxyapatites enriched in silicon–Bioceramic materials for biomedical and pharmaceutical applications, Prog. Nat. Sci., 27 (4), 401–409.
[10] Motisuke, M., Santos, V.R., Bazanini, N.C., and Bertran, C.A., 2014, Apatite bone cement reinforced with calcium silicate fibers, J. Mater. Sci. Mater. Med., 25 (10), 2357–2363.
[11] Geffers, M., Barralet, J.E., Groll, J., and Gbureck, U., 2015, Dual-setting brushite-silica gel cements, Acta Biomater., 11, 467–476.
[12] Ahn, G., Lee, J.Y., Seol, D.W., Pyo, S.G., and Lee, D., 2013, The effect of calcium phosphate cement-silica composite materials on proliferation and differentiation of pre-osteoblast cells, Mater. Lett., 109, 302–305.
[13] Kao, C.T., Huang, T.H., Chen, Y.J., Hung, C.J., Lin, C.C., and Shie, M.Y., 2014, Using calcium silicate to regulate the physicochemical and biological properties when using β-tricalcium phosphate as bone cement, Mater. Sci. Eng., C, 43, 126–134.
[14] Tomoaia, G., Mocanu, A., Vida-Simiti, I., Jumate, N., Bobos, L.D., Soritau, O., and Tomoaia-Cotisel, M., 2014, Silicon effect on the composition and structure of nanocalcium phosphates: In vitro biocompatibility to human osteoblasts, Mater. Sci. Eng., C, 37, 37–47.
[15] Song, Z., Liu, Y., Shi, J., Ma, T., Zhang, Z., Ma, H., and Cao, S., 2018, Hydroxyapatite/mesoporous silica coated gold nanorods with improved degradability as a multi-responsive drug delivery platform, Mater. Sci. Eng., C, 83, 90–98.
[16] Grandfield, K., and Zhitomirsky, I., 2008, Electrophoretic deposition of composite hydroxyapatite-silica-chitosan coatings, Mater. Charact., 59 (1), 61–67.
[17] Jia, Z.Q., Guo, Z.X., Chen, F., Li, J.J., Zhao, L., and Zhang, L., 2018, Microstructure, phase compositions and in vitro evaluation of freeze casting hydroxyapatite-silica scaffolds, Ceram. Int., 44 (4), 3636–3643.
[18] Villacampa, A.I., and Garcı́a-Ruiz, J.M., 2000, Synthesis of a new hydroxyapatite-silica composite material, J. Cryst. Growth, 211 (1-4), 111–115.
[19] Karimi, R., Abbas, A., Nourbakhsh, N., Nourbakhsh, M., and Mackenzie, K.J.D., 2017, Phase formation, microstructure and setting time of MCM-48 mesoporous silica nanocomposites with hydroxyapatite for dental applications: Effect of the Ca/P ratio, Ceram. Int., 43 (15), 12857–12862.
[20] Yamada, S., Nishikawa, M., and Tagaya, M., 2018, Mesoporous silica formation on hydroxyapatite nanoparticles, Mater. Lett., 211, 220–224.
[21] Shen, Y., 2017, Rice husk silica derived nanomaterials for sustainable applications, Renewable Sustainable Energy Rev., 80, 453–466.
[22] Pode, R., 2016, Potential applications of rice husk ash waste from rice husk biomass power plant, Renewable Sustainable Energy Rev., 53, 1468–1485.
[23] Yousefpour, M., and Taherian, Z., 2013, The effects of ageing time on the microstructure and properties of mesoporous silica-hydroxyapatite nanocomposite, Superlattices Microstruct., 54, 78–86.
[24] Nayak, J., and Bera, J., 2009, A simple method for production of humidity indicating silica gel from rice husk ash, J. Met. Mater. Miner., 19 (2), 15–19.
[25] Pajchel, L., and Kolodziejski, W., 2018, Synthesis and characterization of MCM-48/hydroxyapatite composites for drug delivery: Ibuprofen incorporation, location and release studies, Mater. Sci. Eng., C, 91, 734–742.
[26] Fahami, A., Beall, G.W., and Betancourt, T., 2016, Synthesis, bioactivity and zeta potential investigations of chlorine and fluorine substituted hydroxyapatite, Mater. Sci. Eng., C, 59, 78–85.
[27] Malakauskaite-Petruleviciene, M., Stankeviciute, Z., Niaura, G., and Garskaite, E., 2016, Characterization of sol-gel processing of calcium phosphate thin films on silicon substrate by FTIR spectroscopy, Vib. Spectrosc., 85, 16–21.
[28] Nurlidar, F., and Kobayashi, M., 2019, Succinylated bacterial cellulose induce carbonated hydroxyapatite deposition in a solution mimicking body fluid, Indones. J. Chem., 19 (4), 858–864.
[29] Hamzah, S., Yatim, N.I., Alias, M., Ali, A., Rasit, N., and Abuhabib, A., 2019, Extraction of hydroxyapatite from fish scales and its integration with rice husk for ammonia removal in aquaculture wastewater, Indones. J. Chem., 19 (4), 1019–1030
[30] Shiba, K., Motozuka, S., Yamaguchi, T., Ogawa, N., Otsuka, Y., Ohnuma, K., Kataoka, T., and Tagaya, M., 2015, Effect of cationic surfactant micelles on hydroxyapatite nanocrystal formation: An investigation into the inorganic−organic interfacial interactions, Cryst. Growth Des., 16 (3), 1463–1471.
[31] Dorozhkin, S.V., 2017, "Calcium orthophosphate-based bioceramis and its clinical applications" in Clinical Applications of Biomaterials, Eds. Kaur, G., Springer International, Switzerland, 123–226.
[32] Durairaj, K., Senthilkumar, P., Velmurugan, P., Dhamodaran, K., Kadirvelu, K., and Kumaran, S., 2019, Sol-gel mediated synthesis of silica nanoparticle from Bambusa vulgaris leaves and its environmental applications: Kinetics and isotherms studies, J. Sol-Gel Sci. Technol., 90 (3), 653–664.
[33] Latifi, S.M., Fathi, M., Sharifnabi, A., and Varshosaz, J., 2017, In vitro characterisation of a sol–gel derived in situ silica-coated silicate and carbonate co-doped hydroxyapatite nanopowder for bone grafting, Mater. Sci. Eng., C, 75, 272–278.
DOI: https://doi.org/10.22146/ijc.57900
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