The use of ceramics in biological environments and biomedical applications is of increasing importance, as is the understanding of how biology works with minerals to develop strong materials. These proceedings contain papers that discuss the interface between biology and materials, presented at the Proceedings of the 30th International Conference on Advanced Ceramics and Composites, January 22 27, 2006, Cocoa Beach, Florida. Organized and sponsored by The American Ceramic Society and The American Ceramic Society s Engineering Ceramics Division in conjunction with the Nuclear and Environmental Technology Division.…mehr
The use of ceramics in biological environments and biomedical applications is of increasing importance, as is the understanding of how biology works with minerals to develop strong materials. These proceedings contain papers that discuss the interface between biology and materials, presented at the Proceedings of the 30th International Conference on Advanced Ceramics and Composites, January 22 27, 2006, Cocoa Beach, Florida. Organized and sponsored by The American Ceramic Society and The American Ceramic Society s Engineering Ceramics Division in conjunction with the Nuclear and Environmental Technology Division.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Andrew A. Wereszczak received his Ph.D. in Materials Science & Engineering from the University of Delaware in 1992, and while his research is varied, the study and interpretation of the relationship between mechanical properties and microstructure (of monolithic ceramics, structural materials, and electronic materials) are common denominators. Micromechanical characterization of structural and armor ceramics using instrumented static and dynamic indentation (e.g., Hertzian) with acoustic emission analysis, and adapting those measured performances and damage mechanism analyses to strength, rolling contact fatigue, wear, machining, and ballistic performances is a primary objective. Additionally, ceramic strength and fatigue testing, ceramic fractographical and flaw population analyses, Weibull analysis strength-size-scaling, and probabilistic life prediction and design of structural ceramic components constitutive another primary research objective. In support of all these efforts, both conventional and microstructural-level finite element stress analyses and microstructure characterization are performed. He is the author or co-author of over 100 technical publications and has given over 80 presentations, and is the co-developer of µ-FEA software. Edgar Lara-Curzio is a Distinguished Research Staff Member and the leader of the Mechanical Properties and Mechanics Group at Oak Ridge National Laboratory. Since 1999 he has been serving as leader of the Mechanical Characterization and Analysis User Center in ORNL's High Temperature Materials Laboratory. Lara-Curzio received a B.Sc. degree in Engineering Physics from the Metropolitan University in Mexico City in 1986 and a Ph.D. in Materials Engineering from Rensselaer Polytechnic Institute, Troy NY, in 1992. His research work has been focused on studying the mechanical behavior, durability and reliability of structural and functional materials, on understanding the relationships among their processing, microstructure and properties, studying the effect of service environment on their properties and on developing models to describe their behavior and to predict their service life. Dr. Lara-Curzio has co-edited 6 books and has authored 4 book chapters and more than 140 publications in refereed journals and conference proceedings.
Inhaltsangabe
Preface. Introduction. In Vitro Evaluation. Initial In Vitro Interaction of Human Osteoblasts with Nanostructured Hydroxyapatite (NHA) (Xingyuan Guo, Julie Gough, Ping Xiao, Jing Liu, and Zhijian Shen). Osteoblast Response to Zinc-Doped Sintered p-Tricalcium Phosphate (Sahil Jalota, Sarit 8. Bhaduri, and A. Cuneyt Tas). Determination of the Spatial Resolution of Micro-Focus X-Ray CT System with a Standard Specimen (Mineo Mizuno, Yasutoshi Mizuta, Takeharu). Kato, and Yasushi lkeda Processing of Biomaterials. Hydroxyapatite Hybridized with Metal Oxides for Biomedical Applications ( Akiyoshi Osaka, Eiji Fujii, Koji Kawabata, Hideyuki Yoshirnatsu, Satoshi Hayakawa, Kanji Tsuru, Christian Bonhornrne, and Florence Babonneau). Preparation of Self-setting Cement-Based Micro- and Macroporous Granules of Carbonated Apatitic Calcium Phosphate (A. Cuneyt Tas). A Self-setting, Monetite (CaHPO,) Cement for Skeletal Repair (Tarang R. Desai, Sarit B. Bhaduri, and A. Cuneyt Tas). Chemically Bonded Ceramics Based on Ca-Aluminates as Biomaterials (L. Herrnansson and H. Engqvist). A Theoretical and Mathematical Basis Towards Dispersing Nanoparticles and Biological Agents in a Non Polar Solvent for Fabricating Porous Materials (Navin J. Manjooran and Gary R. Pickrell). Preparation of Hydroxyapatite and Calcium Phosphate Bioceramic Materials from the Aqueous Solution at Room Temperature (Jia-Hui Liao, Yu-Chen Chang, and Tzer-Shin Sheu). Hydroxyapatite Coatings Produced by Plasma Spraying of Organic Based Solution Precursor (E. Garcia, Z. B. Zhang, T. W. Coyle, L. Gan, and R. Pilliar). Visible-Light Photocatalytic Fibers for Inactivation of Pseudomonas Aeruginosa (P. G. Wu, R. C. Xie, J. Irnlay, and J. K. Shang). Precipitation Mechanisms of Hydroxyapatite Powder in the Different Aqueous Solutions (Yu-Chen Chang and Tzer-Shin Sheu). Conversion of Bioactive Silicate (45S5), Borate, and Borosilicate Glasses to Hydroxyapatite in Dilute Phosphate Solution (Wenhai Huang, Moharned N. Raharnan, and Delbert E. Day). Dental Ceramics. Variable Frequency Microwave (VFM) Processing: A New Tool to Crystallize Lithium Disilicate Glass (Morsi Mahmoud, Diane Folz, Carlos Suchicital, David Clark, and Zak Fathi). Author Index.
Preface. Introduction. In Vitro Evaluation. Initial In Vitro Interaction of Human Osteoblasts with Nanostructured Hydroxyapatite (NHA) (Xingyuan Guo, Julie Gough, Ping Xiao, Jing Liu, and Zhijian Shen). Osteoblast Response to Zinc-Doped Sintered p-Tricalcium Phosphate (Sahil Jalota, Sarit 8. Bhaduri, and A. Cuneyt Tas). Determination of the Spatial Resolution of Micro-Focus X-Ray CT System with a Standard Specimen (Mineo Mizuno, Yasutoshi Mizuta, Takeharu). Kato, and Yasushi lkeda Processing of Biomaterials. Hydroxyapatite Hybridized with Metal Oxides for Biomedical Applications ( Akiyoshi Osaka, Eiji Fujii, Koji Kawabata, Hideyuki Yoshirnatsu, Satoshi Hayakawa, Kanji Tsuru, Christian Bonhornrne, and Florence Babonneau). Preparation of Self-setting Cement-Based Micro- and Macroporous Granules of Carbonated Apatitic Calcium Phosphate (A. Cuneyt Tas). A Self-setting, Monetite (CaHPO,) Cement for Skeletal Repair (Tarang R. Desai, Sarit B. Bhaduri, and A. Cuneyt Tas). Chemically Bonded Ceramics Based on Ca-Aluminates as Biomaterials (L. Herrnansson and H. Engqvist). A Theoretical and Mathematical Basis Towards Dispersing Nanoparticles and Biological Agents in a Non Polar Solvent for Fabricating Porous Materials (Navin J. Manjooran and Gary R. Pickrell). Preparation of Hydroxyapatite and Calcium Phosphate Bioceramic Materials from the Aqueous Solution at Room Temperature (Jia-Hui Liao, Yu-Chen Chang, and Tzer-Shin Sheu). Hydroxyapatite Coatings Produced by Plasma Spraying of Organic Based Solution Precursor (E. Garcia, Z. B. Zhang, T. W. Coyle, L. Gan, and R. Pilliar). Visible-Light Photocatalytic Fibers for Inactivation of Pseudomonas Aeruginosa (P. G. Wu, R. C. Xie, J. Irnlay, and J. K. Shang). Precipitation Mechanisms of Hydroxyapatite Powder in the Different Aqueous Solutions (Yu-Chen Chang and Tzer-Shin Sheu). Conversion of Bioactive Silicate (45S5), Borate, and Borosilicate Glasses to Hydroxyapatite in Dilute Phosphate Solution (Wenhai Huang, Moharned N. Raharnan, and Delbert E. Day). Dental Ceramics. Variable Frequency Microwave (VFM) Processing: A New Tool to Crystallize Lithium Disilicate Glass (Morsi Mahmoud, Diane Folz, Carlos Suchicital, David Clark, and Zak Fathi). Author Index.
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