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PEEK biomaterials are currently used in hundreds of thousands of spinal fusion patients around the world every year. Durability, biocompatibility, and excellent resistance to aggressive sterilization procedures make PEEK a polymer of choice, replacing metal in orthopedic implants, from spinal implants and knee replacements to finger joints and dental implants. The new edition of this authoritative work sees the book expand from 17 chapters to 26 chapters to match the expansion in applications in PEEK-from spinal cages to spinal rods and disc replacements; hip and knee joint replacement; dental; trauma; and sports medicine. New PEEK formulations have been developed incorporating hydroxyapatite, additives to combat infection, and surface grafted polymers to improve lubrication. The book also covers additive manufacturing, which has made significant inroads with PEEK in the past 5 years as well by introducing the prospect of patient-specific implants. Like the 1st edition, the updated Handbook brings together experts in many different facets related to PEEK clinical performance as well as in the areas of materials science, tribology, and biology to provide a complete reference for specialists in the field of plastics, biomaterials, medical device design, and surgical applications. Useful for materials scientists and biomedical engineers, both in industry and academia, the book is a one-stop shop for information on PEEK as a biomaterial-including in-depth coverage of materials properties-while also providing cutting-edge information on applications and combinations of the material.
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Dislocation Based Crystal Plasticity: Theory and Computation at Micron and Submicron Scale provides a comprehensive introduction to the continuum and discreteness dislocation mechanism-based theories and computational methods of crystal plasticity at the micron and submicron scale. Sections cover the fundamental concept of conventional crystal plasticity theory at the macro-scale without size effect, strain gradient crystal plasticity theory based on Taylar law dislocation, mechanism at the mesoscale, phase-field theory of crystal plasticity, computation at the submicron scale, including single crystal plasticity theory, and the discrete-continuous model of crystal plasticity with three-dimensional discrete dislocation dynamics coupling finite element method (DDD-FEM). Three kinds of plastic deformation mechanisms for submicron pillars are systematically presented. Further sections discuss dislocation nucleation and starvation at high strain rate and temperature effect for dislocation annihilation mechanism. Covers dislocation mechanism-based crystal plasticity theory and computation at the micron and submicron scale. Presents crystal plasticity theory without size effectDeals with the 3D discrete-continuous (3D DCM) theoretic and computational model of crystal plasticity with 3D discrete dislocation dynamics (3D DDD) coupling finite element method (FEM)Includes discrete dislocation mechanism-based theory and computation at the submicron scale with single arm source, coating micropillar, lower cyclic loading pillars, and dislocation starvation at the submicron scale
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Biochemistry for Materials Science: Catalysis, Complexes and Proteins unlocks recent developments in the field of biochemistry through a series of case studies, enabling materials scientists to harness these advances for innovation in their own field, from the design of bio-inspired materials, to the use of new classes of catalyst. The book is broken up into six independent parts that include an introduction to seven recent discoveries, a discussion of the fundamental knowledge and techniques of biochemistry, a look at a number of biochemical materials, and an exploration of the areas of life science, organic chemistry and inorganic-related materials. The book concludes with a discussion of cosmochemistry.
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High-Entropy Alloys, Second Edition provides a complete review of the current state of the field of high entropy alloys (HEA). Building upon the first edition, this fully updated release includes new theoretical understandings of these materials, highlighting recent developments on modeling and new classes of HEAs, such as Eutectic HEAs and Dual phase HEAs. Due to their unique properties, high entropy alloys have attracted considerable attention from both academics and technologists. This book presents the fundamental knowledge, the spectrum of various alloy systems and their characteristics, key focus areas, and the future scope of the field in terms of research and technological applications.
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Metals for Biomedical Devices, Second Edition, has been fully updated and builds upon the success of its first edition, discussing the latest techniques in metal processing methods and the behavior of this important material. Initial chapters review the current status and selection of metals for biomedical devices. Subsequent chapters cover mechanical behavior, degradation and testing, corrosion, wear testing and biocompatibility, the processing of metals for biomedical applications, including topics such as forging metals and alloys, surface treatment, coatings and sterilization. Chapters in the final section discuss the clinical applications of metals, such as cardiovascular, orthopedic and new generation biomaterials. With its distinguished editor and team of expert contributors, this book is a standard reference for materials scientists, researchers and engineers working in the medical devices industry and academia.
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Advanced Nanomaterials for Catalysis and Energy: Synthesis, Characterization and Applications outlines new approaches to the synthesis of nanomaterials (synthesis in flow conditions, laser electrodispersion of single metals or alloys on carbon or oxide supports, mechanochemistry, sol-gel routes, etc.) to provide systems with a narrow particle size distribution, controlled metal-support interaction and nanocomposites with uniform spatial distribution of domains of different phases, even in dense sintered materials. Methods for characterization of real structure and surface properties of nanomaterials are discussed, including synchrotron radiation diffraction and X-ray photoelectron spectroscopy studies, neutronography, transmission/scanning electron microscopy with elemental analysis, and more. The book covers the effect of nanosystems' composition, bulk and surface properties, metal-support interaction, particle size and morphology, deposition density, etc. on their functional properties (transport features, catalytic activity and reaction mechanism). Finally, it includes examples of various developed nanostructured solid electrolytes and mixed ionic-electronic conductors as materials in solid oxide fuel cells and asymmetric supported membranes for oxygen and hydrogen separation.
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Nano-inspired Biosensors for Protein Assay with Clinical Applications introduces the latest developments in nano-inspired biosensing, helping readers understand both the fundamentals and frontiers in this rapidly advancing field. In recent decades, there has been increased interest in nano-inspired biosensors for clinical application. Proteins, e.g. antigen-antibody, tumor markers and enzymes are the most important target in disease diagnosis, and a variety of biosensing techniques and strategies have been developed for protein assay. This book brings together all the current literature on the most recent advances of protein analysis and new methodologies in designing new kinds of biosensors for clinical diagnostic use.
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