Bioactive compositions

Nakamura, T. Yamamuro, S. Higashi, T. Kokubo and S. Ito (1985) A New Glass-Ceramic for Bone Replacement Evaluation of its Bonding to Bone Tissue, J. Biomed. Maters Res. 19, 685-698. [Pg.357]

Kotani, Y. Fujita, T. Kitsugi, T. Nakamura, T. Yamamuro, C. Ohtsuki and T. Kokubo (1991) Bone Bonding Mechanisms of p-tricalcium Phosphate, /. Biomed. Maters. Res. 25, 1303-15. [Pg.357]

Yamamuro (1993) A/W Glass-Ceramic Clinical Applications, in Introduction to Bioceramics, eds L.L. Hench and J. Wilson, World Scientific Publishing Co., London, 1993, pp. 89-104. [Pg.357]

Phase Glass Glass Apatite Apatite Apatite Apatite Apatite Whitlockite [Pg.359]

Hench and E.C. Ethridge, Biomaterials, An Interfacial Approach, p. 137, Academic Press, New York, 1982. [Pg.360]

Andersson, K.H. Karlsson, K. Kangasniemi, and A. Yli-Urpo, Models for Physical Properties and Bioactivity of Phosphate Opal Glasses, [Pg.360]

Bromer, K. Deutscher, B. Blenke, E. Pfeil and V. Strunz, Properties of the Bioactive Implant Material Ccravital , in Science of Ceramics, Vol. 9, 1977, pp. 219-223. [Pg.360]

Kokubo, Mechanical Properties of a New Type of Glass-Ceramic for Prosthetic Applications, in Multiphase Biomedical Materials, T. Tsuruta and A. Nakajima, eds, VSP, Utrecht, Netherlands, 1989. [Pg.360]

Jones, S.M., Friberg, S.E. and Sjoblom, J. (1994) A bioactive composite-material produced by the sol-gel method. Journal of Materials Science, 29, 4075 1080. [Pg.397]

Silva, G. A., Costa, F. J., Coutinho, O. P, Radin, S., Ducheyne, R, Reis, R. L. (2004). Synthesis and evaluation of novel bioactive composite starch/bioactive glass microparticles. J. Biomed. Mater. Res. Part A., 70A 3), 442 49. [Pg.461]

Sousa, R. A., Mano, J. F., Reis, R. L., Cunha, A. M., Bevis, M. J. (2002). Mechanical performance of starch based bioactive composite biomaterials molded with preferred orientation for potential medical applications. Polym. Eng. Sci.,42(5), 1032-1045. [Pg.462]

Ban, S., Hasegawa, J., Maruno, S., (1999), Fabrication and properties of functionally graded bioactive composites comprising hydroxyapatite containing glass coated titanium , Mat. Sci. Forum., 308-311, 350-355. [Pg.592]

Roether, J.A., Boccaccini, A.R., Hench, L.L., Maquet, V., Gautier, S., and Jerome, R. (2002) Development and in vitro characterisation of novel bioresorbable and bioactive composite materials based on polylactide foams and bioglass for tissue engineering applications. Biomaterials, 18, 3871-3878. [Pg.246]

M. Ahmad, M.U. Wahit, M.R.A. Kadir, K.Z.M. Dahlan, Mechanical, iheological, and bioactivity properties of ultra high-molecular-weight polyethylene bioactive composites containing polyethylene glycol and hydroxyapatite. Sci. World J. 13, 474851 (2012)... [Pg.177]

M. Wang, Developing bioactive composite materials for tissue replacement. Biomaterials 24, 2133-2151 (2003)... [Pg.264]

Bioactive composites Bioactive composite bone cement Ca3Si05 with /3Ca3(P04)2, Ca(H2P04)2 H20 Bone Huan and Chang (2009), Zhao eta/. (2005)... [Pg.160]

Huan, Z. Chang, J. (2009) Novel bioactive composite bone cements based on the beta-tricalcium phosphate-monocalcium phosphate monohydrate composite cement system. Acta Biomater, 5, 1253-64. [Pg.174]

A pharmaceutically active or bioactive molecule can be entrapped in the hyaluronic acid derivative micelles to form a pharmaceutically active or a bioactive composition with a stable controlled released effect (28). [Pg.233]

Figure 6.4 The compositional dependence of bone bonding to bioactive glasses (region A) containing 6 weight % P2O5. Soft tissue bonding occurs for compositions with Ig values > 8 (see text). Region B non-bioactive compositions. Glasses in Region C are resorbable. (Based upon chapters 1 and 3 in ref. 1.)...

Wang M (2003) Developing bioactive composite materials for tissue replacement. [Pg.161]

Khabarov, V.N., Selyanin, M.A., Michailova, N.P., Zelenetsky, A.N. (2009) Bioactive compositions comprising hyaluronic acid modified in soUd-phase (in Russian). Vestnik Estetichskoi Mediciny, 8 (1), 49-53. XaOapoB, B.H., CejwHHH, MA., MnxaHJioBa, H.n., SejieneuKHH, A.H. (2009)... [Pg.140]

Using the technology of sohd-phase modification, the product line called Hyalrepair was created [41,42] to include 10 different bioactive compositions of densely cross-hnked Na, Cu and Ztf + salts of HA with chemically immobilized vitamins (ascorbic and folic... [Pg.163]

Volkov, V.P., Zelenetskii, A.N., Khabarov, V.N., Selyanin, M. A. (2008) The method of obtaining salts of modified hyaluronic acid cross-hnked with ascorbic acid and bioactive composition thereof. Russian Federation Patent No. 2382050, filed Jun. 05, 2008 and issued Feb. 20, 2010. [Pg.188]

Innocenzi P., Esposto M., Maddalena A. Mechanical properties of 3-glycidoxypropyltrimethoxy-silane based hybrid organic-inorganic materials. J. Sol-Gel Sci. Technol. 2001 20 293-301 Iwamoto T., Morita K., Mackenzie J.D. Liquid state Si NMR study on the sol-gel reaction mechanisms oformosils. J. Non-Cryst. Sohds 1993 159 65-72 Iwamoto T., Mackenzie J.D. Qrmosil coatings of high hardness. J. Mater. Sci. 1995 30 2566-2570 Jones S.M., Friberg S.E., Sjoblom J. A bioactive composite material produced by the sol-gel method. J. Mater. Sci. 1994 29 4075 080... [Pg.1733]

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