SPECIFIC ASPECTS IN USING SEASHELL POWDER (RAPANA THOMASIANA) IN ELABORATION OF COMPOSITES FOR MEDICAL PURPOSES
Abstract
Rapana Thomasiana (RT) seashell is an important source of natural calcium carbonate that can be used to produce composites dedicated to medical purposes. Cracking processes were detected during the sintering process, and/or low mechanical characteristics were measured for the composites based on calcium carbonate provided by the RT seashell. Remnant organic elements were supposed to cause the cracking and the low characteristics, due to specific resistance to the pressing process before sintering. Preheating of the powder, before the pressing in dye, was proposed to 300/400/500oC. The reason was to completely burn the organic materials remained from the mollusc. Improvement of the ceramic material’s behaviour has been recorded: an increasing of the hardness with values up to 15%, and an increasing of the maximum supported force during the compression test with values up to 25%.
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Andronescu E., Ciobanu C.S., Pall L., Costache M., Predoi D., Preliminary biocompatibility studies of hydroxyapatite coated iron oxide, Romanian Journal of Materials, 40(3), 242, 2010.
Ungureanu D.N., Angelescu N., Tsakiris V., Marinescu V., Investigations regarding chemical synthesis of calcium hydroxyapatite, Romanian journal of materials, 42(1), pp.52-60, 2012.
Correia R. N., Magalahaes M.C.F., Marques P.A.A.P., A.M.R. Senos, Wet synthesis and characterization of modified hydroxyapatite powders, Journal of Materials Science: Materials in Medicine, 7 (8), p.501, 1996.
Preda M., Melinescu A., Zaharescu M., Brăileanu A., Hydroxyapatite obtaining by hydrothermal route, Romanian Journal of Materials, 32 (4), p.250, 2002.
Preda M., Melinescu A., Teoreanu, I. Sintering behaviour of hydroxyapatite, Rom. Journal of Materials, 33 (3), p.200, 2003
Savu S.V., Tarnita D., Benga G.C., Dumitru I., Stefan I., Craciunoiu N., Olei A.B., Savu I.D., Microwave Technology Using Low Energy Concentrated Beam for Processing of Solid Waste Materials from Rapana thomasiana Seashells, Energies, pp. 6780, 2021
Savu I.D., Tarnita D., Savu S.V., Benga G.C., Cursaru L.M., Dragut D.V., Piticescu R.M., Tarnita D.N., Composite Polymer for Hybrid Activity Protective Panel in Microwave Generation of Composite Polytetrafluoroethylene ‐Rapana Thomasiana, Polymers, pp. 2432, 2021.
Boyjoo, Y.; Pareek, V.K.; Liu, J., Synthesis of Micro and Nano-Sized Calcium Carbonate Particles and Their Applications, Journal of Materials Chemistry A 2014, 1-46
Tihan, G.T.; Sereanu, V.; Meghea, A.; Voicu, G.; Albu, M.G.; Mitran, V.; Cimpean, A.; Zgarian, R.G., Innovative methodology for developing a bone grafting composite biomaterial starting from the seashell of Rapana thomasiana, Comptes Rendus Chimie, pp. 440-445, 2017.
Mangra G. I., Savu, S. V., Savu, I. D., Inductive Sensor with Sintered Magnetic Core to Evaluate the Performances of the Table Tennis Players, Materials Science Forum, pp. 105-108, 2011.
Savu I.D., Savu S.V., Benga G. C., Thermal Runaway of the BaCO3 + Fe2O3 homogenous mixture and mechanical alloys at the microwave heating, Advanced Materials Research, pp. 185-189, 2014.
Mocioiu, A.M., Tutuianu, R., et.al., 3D structures of hydroxyapatite obtained from Rapana venosa shells using hydrothermal synthesis followed by 3D printing, Journal of Materials Science, 54(22), pp. 13901-13913, 2019.
Kenneth S. Vecchio; Xing Zhang; Jennifer B. Massie; Mark Wang; Choll W. Kim , Conversion of bulk seashells to biocompatible hydroxyapatite for bone implants. 3(6), pp.910–918. 2007.
Shih-Ching Wu; Hsueh-Chuan Hsu; Yu-Ning Wu; Wen-Fu Ho, Hydroxyapatite synthesized from oyster shell powders by ball milling and heat treatment, 62(12), pp. 1180–1187, 2011.
Fu, L. H., Dong, Y. Y., et.al., Compare study CaCO3 crystals on the cellulose substrate by microwave-assisted method and ultrasound agitation method. Ultrasonics sonochemistry, 20(3), pp.839-845., 2013.
Tarnita, D., et. al., Properties and medical applications of shape memory alloys, Romanian Journal of Morphology and embryology, 50(1) , pp.15-22, 2009.
Tarnita, D., Tarnita, D.N., Popa D., Grecu, D., Niculescu, D., Numerical simulations of human tibia osteosynthesis using modular plates based on Nitinol staples, Romanian Journal of Morphology and Embryology, 51(1), pp. 145-150, 2010.
Tarnita, D., Berceanu, C., Tarnita, C., The three-dimensional printing – a modern technology used for biomedical prototypes, Materiale plastice, 47(3), pp. 328-334, 2010.
Tarnita, D., et. al., Modular adaptive bone plate for humerus bone osteosynthesis, Romanian Journal of Morphology and Embryology, 50(3), pp. 447-452, 2009.
Tarnita D., Tarnita D.N, Bolcu, D., Orthopedic modular implants based on shape memory alloys, chapter in Biomedical Engineering – From Theory to Applications, InTech, Viena, pp.431-468, 2011.
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