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.

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Bioceramics and their clinical applications is written by leading academics from around the world and it provides an authoritative review of this highly active area of research. This book will be a useful resource for biomaterials scientists and engineers, as well as for clinicians and the academic community.

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Discover how to take full advantage of nanoscale materials in the design and fabrication of leading-edge biomedical devices. The authors introduce you to a variety of possible clinical applications such as drug delivery, diagnostics, and cancer therapy.

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Volume 1 of the multi-volume reference, BioMEMS and Biomedical Nanotechnology, focuses on synthetic nanodevices and the synthesis of nanomaterials and the generation of nanoscale features. The nanomaterials include polymeric microspheres and nanostructures, carbon nanotubes, silicon, silicon dioxide, and iron oxide. There is also a chapter on the characterization of critical nanostructures for bio applications such as nanochannels and nanopores. The second part involves hybrid synthetic-biomolecular nanodevices that utilize the self assembly properties of both biomolecules and synthetic materials. There is a chapter discussing the structure-function relations between biomolecular (protein) and inorganic interfaces. The third part gives the theoretical underpinning of bio nanodevices covering computation methods, informatics, and mechanics. These fundamentals are critical in designing the next generation nanodevices and also understanding the interaction between nanodevices and biological systems to enable more efficient in vitro and in vivo bio applications.

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Bioresorbable materials are extensively used for a wide range of biomedical applications from drug delivery to fracture fixation, and may remain in the body for weeks, months or even years. Accurately predicting and evaluating the degradation rate of these materials is critical to their performance and the controlled release of bioactive agents. Degradation rate of bioresorbable materials: prediction and evaluation provides a comprehensive review of the most important techniques in safely predicting and evaluating the degradation rate of polymer, ceramic and composite based biomaterials.

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The Handbook of Materials for Medical Devices provides an in-depth review of the properties, processing, and selection of materials used in the environment of the human body-an environment that is surprisingly hostile and aggressive. Among the application areas described are orthopedics (hips, knees, and spinal and fracture fixation), cardiology (stents, heart valves, pacemakers), surgical instruments, and restorative dentistry. Materials discussed include metals and alloys, ceramics, glasses, and glass-ceramics, polymeric materials, composites, coatings, and adhesives and cements.

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Joint replacement has been one of the major successes of modern medicine. Its continued success depends on effective collaboration between clinicians and researchers across many different areas in science and medicine. This important book brings together the wide range of research in this area and its implications for clinical practice.

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Materials Research Innovations covers all areas of materials research including metals, polymers, ceramics, composites, electronic materials and biomaterials. As the field of materials research evolves, different emphases, including those that become funding ‘mantras’, take the spotlight. The Editors (many of them involved in the formation of the materials research field) attempt to balance the more permanent themes of science and engineering with such areas of research activity.

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Nanobiotechnology of Biomimetic Membranes describes the current state of research and development in biomimetic membranes for nanobiotechnology applications. The application areas in nanobiotechnology range from novel nanosensors, to novel methods for sorting and delivering bio-active moleculres, to novel drug-delivery systems. The success of these applications relies on a good understanding of the interaction and incorporation of macromoleculres in membranes and the fundamental properties of the membrane itself.

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Polymers from natural sources are particularly useful as biomaterials and in regenerative medicine, given their similarity to the extracellular matrix and other polymers in the human body. This important book reviews the wealth of research on both tried and promising new natural-based biomedical polymers, together with their applications as implantable biomaterials, controlled-release carriers or scaffolds for tissue engineering.

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The intention of this book was to provide the Reader, primarily graduate students and young researchers in materials engineering, bio(chem)physics, medical physics and biophysics, with a set of articles reviewing state-of-the art research and recent advancements in the field of photon-matter interaction for micro/nanomaterials synthesis and manipulation of properties of biological and inorganic materials at the atomic level. Photon-based nanoscience and related technologies have created exciting opportunities for the fabrication and characterization of nano(bio)material devices and systems, and it is expected to significantly contribute to the development of Nanobiophotonics and Nanomedicine.

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Recent advances not only in the creation of new polymers but also in their processing and production have ushered in huge strides in a variety of biomedical and clinical areas. Orthopedics and dentistry are two such areas that benefit immensely from developments in polymer science and technology. Polymers for Dental and Orthopedic Applications examines the most current topics in this expanding field with an emphasis on technological evolution and clinical impacts.

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