Formation of bioactive ceramic foams by polymer pyrolysis and self-blowing

Journal of the Korean Ceramic Society

Volumn 48, Issue 5, 2011, Pages 412-417

  Kwak, Dae Hyun ^a   Kim, Jin Ho ^a   Lee, Eun Ju ^a   Kim, Deug Joong ^a  

^a Sungkyunkwan University   (South Korea)

Author keywords

Bioceramic; Ceramic foams; Hydroxyapatite; Polymer pyrolysis

Indexed keywords

BIOCERAMICS; CALCIUM; CERAMIC MATERIALS; CHARACTERIZATION; FILLERS; HYDROXYAPATITE; MECHANICAL PROPERTIES; POLYMERS; PYROLYSIS; SOLID STATE REACTIONS;

BIOACTIVE CERAMIC; BIPHASIC MATERIALS; CALCIUM HYDROGEN PHOSPHATE DIHYDRATE; HIGH MECHANICAL STRENGTH; MICROSTRUCTURE AND MECHANICAL PROPERTIES; POLYMER PYROLYSIS; POLYMETHYLSILOXANES; POROUS HYDROXYAPATITE;

CERAMIC FOAMS;

EID: 80055089471     PISSN: 12297801     EISSN: None     Source Type: Journal    
DOI: 10.4191/kcers.2011.48.5.412     Document Type: Article

References (13)

1. A. Balamurugan, S. Kannan, and S. Rajeswari, "Bioactive Sol-Gel Hydroxyapatite Surface for Biomedical Application In-Vitro Study," Trends Biomater. Artif. Organs, 16 [1] 18-20 (2002).
2. P. Layroll, A. Ito, and T. Tateishi, "Sol-Gel Synthesis of Amorphous Calcium Phosphate and Sintering into Microporous Hydroxyapatite Bioceramics," J. Am. Ceram. Soc., 81 [6] 1421-28 (1998). (Pubitemid 128577120)
3. D. Shi, G. Jaing, X. Wen, in: K. Khor, et al. (Eds.), "In Vitro Behavior of Hydroxyapatite Prepared by a Thermal Deposition Method, Processing and Fabrication of Advanced Materials VIII," pp. 117, World Scientific, Singapore, 2001.
4. W. Suchanek and M. Yoshimura, "Processing and Properties Hydroxyapatite Based Biomaterials for Use as Hard Tissue Replacement Implants," J. Mater. Res., 13 94-117 (1998). (Pubitemid 128567343)
5. Leony Leon C. A., "New Perspectives in Mercury Porosimetry," Adv Colloid Interface Sci., 76-77 341-72 (1998).
6. I. M. Kwon, I. H. Song, Y. J. Park, J. W. Lee, H. S. Yun, and H. D. Kim "The Synthesis and Pore Property of Hydrogen Membranes Derived from Polysilazane as Inorganic Polymer," J. Kor. Cream. Soc., 46 [5] 462-66 (2009).
7. S. J. Hong, H. C. Ahn, and D. J. Kim, "Reaction Bonded Si3N4 from Si-Polysilazane Mixture," J. Kor. Cream. Soc., 47 [6] 572-77 (2010)
8. T. Gambayan-Roisman, M. Scheffler, P. Buhler, and P. Greil, "Processing of Ceramic Foam by Pyrolysis of Filler Containing Phenylmethyl Polysiloxane Precusor," Ceram. Trans., 108 121-30 (2000).
9. T. Gembaryan-Roisman, M. Scheffler, T. Takahashi, P. Buhler, and P. Greil, "Formation and Properties of Poly(siloxane) Derived Ceramic Foam," pp.247-51 in Euromat 99, Vol. 12, Ceramics Processing, Reliability, Tribology and Wear. Edited by G. Muller, DGM, Frankfurt, 2000.
10. J. Zeschky, T. Hofner, C. Arnold, R. Weibmann, D. Bahloul-Hourlier, M. Scheffler, and P. Greil, "Polysilsesquioxane Derived Ceramic Foams with Gradient Porosity," Acta Materialia, 53 927-37 (2005). (Pubitemid 40114250)
11. P. N. De Aza, F. Guitian, and S. De Aza, "Bioactivity of Wollastonite Ceramics: In Vitro Evaluation," Scripta Metall. Mater., 31 1001-1005 (1994).
12. P. Siriphannon, Y. Kameshima, A. Yasumori, K. Okada, and S. Hayashi, "Formation of Hydroxyapatite on CaSiO3 Powders in Simulated Body Fluid," J. Eur. Ceram. Soc., 22 511-20 (2002). (Pubitemid 34122622)
13. K. Lin, W. Zhai, S. Ni, J. Chang, Y. Zeng, and W. Qian, "Study of the Mechanical Property and In Vitro Biocompatibility of CaSiO3 Ceramics," Ceramics International, 31 323-26 (2005).