Magnesium Biomaterials provides a succinct up-to-date overview of Magnesium biomaterial development, critically examines the types of in vitro experiments that may be performed, and investigates the numerous variables that affect Magnesium biodegradation when undertaking these experiments. This work also discusses the direction in which current Magnesium biomaterial development is heading and the necessary steps for future development of this field. Information is drawn from numerous multi-disciplinary sources to provide a coherent and critical overview. Magnesium Biomaterials is ideal for researchers in the area of bio-Mg, companies interested in exploring their own alloys, and for researchers working with other biodegradable materials who are seeking a cross-platform understanding of material performance.

Magnesium Alloys as Degradable Biomaterials provides a comprehensive review of the biomedical applications of biodegradable magnesium and its alloys. Magnesium has seen increasing use in orthopedic and cardiovascular applications over the last decade, particularly for coronary stents and bone implants.The book discusses the basic concepts of biodeg

Magnesium alloys have enormous potential for use in biomedical implants. Magnesium Alloys for Biomedical Applications delves into recent advances and prospects for implementation and provides scientific insights into current issues posed by Mg alloy materials. It provides an overview of research on their mechanical and tribological characteristics, corrosion tendencies, and biological characteristics, with a particular emphasis on biomedical implants. Details the fundamentals of Mg alloys as well as necessary surface modifications of Mg alloys for biomedical use. Discusses emerging Mg alloys and their composites. Covers mechanical, tribological, and chemical properties, as well as fatigue and corrosion. Highlights emerging manufacturing methods and advancements in new alloy design, composite manufacturing, unique structure design, surface modification, and recyclability. Helps readers identify appropriate Mg-based materials for their applications and select optimal improvement methods. Summarizes current challenges and suggests a roadmap for future research. Aimed at researchers in materials and biomedical engineering, this book explores the many breakthroughs achieved with these materials and where the field should concentrate to ensure the development of safe and reliable Mg alloy-based implants.

Surface modification of magnesium and its alloys for biomedical applications: Biological interactions, mechanical properties and testing, the first of two volumes, is an essential guide on the use of magnesium as a degradable implant material. Due to their excellent biocompatibility and biodegradability, magnesium based degradable implants provide a viable option for the permanent metallic implants. This volume focuses on the fundamental concepts of surface modification of magnesium, its biological interactions, mechanical properties and, in vitro and in vivo testing. The contents of volume 1 is organized and presented in three parts. Part 1 reviews the fundamental aspects of surface modification of magnesium, including surface design, opportunities, challenges and its role in revolutionizing biodegradable biomaterials. Part 2 addresses the biological and mechanical properties covering an in vivo approach to the bioabsorbable behavior of magnesium alloys, mechanical integrity and, the effects of amino acids and proteins on the performance of surface modified magnesium. Part 3 delves in to testing and characterization, exploring the biocompatibility and effects on fatigue life alongside the primary characteristics of surface modified magnesium. All chapters are written by experts, this two volume series provides systematic and thorough coverage of all major modification technologies and coating types of magnesium and its alloys for biomedical applications. - Expert analysis of the fundamentals in surface modification of magnesium and its alloys for biomedical applications - Includes biological interactions and mechanical properties - Focuses on testing and characterisation, as well as biocompatibility

Introductory Biomaterials enables undergraduate students in Biomedical, Chemical, Materials and other relevant Engineering disciplines to become familiar with the key concepts of Biomaterials principles: biocompatibility, structure-property-applications relationships, mechanical response of natural tissues, and cellular pathways for tissue-material ingrowth. Written in a clear, concise manner that weds theory with applications, this book helps students to understand the often intricate relationships between materials the implant devices that are made from them, and how the human body reacts to them. The book includes such concepts as requirements for metals, alloys, and ceramic materials to be used in load bearing implants (corrosion concepts, stress shielding, mechanical properties, composition), what properties of polymers impact their use in medicine (leaching and swelling, creep and stress relaxation); the tissue response to biomaterials, concepts related to drug delivery applications (polymer degradation, encapsulation), and tissue engineering (scaffold porosity, diffusion of nutrients, mechanical properties). - Begins with structure-properties, followed immediately by their impact on actual biomaterials classes and devices, thus directly relating theory to applications (e.g. polymers to polymeric stents; metals to fracture fixation devices) - Explains concepts in a clear, progressive manner, with numerous examples and figures to enhance student learning - Covers all key biomaterials classes: metallic, ceramic, polymeric, composite and biological - Includes a timely chapter on medical device regulation

The book presents the characterization and classification of metallic biomaterials; with focus on titanium-based alloys, cobalt-based alloys, stainless steels and biodegradable alloys. Emphasis is placed on the synthesis, assessment of properties and medical applications such as multifunctional implants. The book references 423 original resources and includes their direct web link for in-depth reading. Keywords: Biomaterials, Classification, Titanium Alloys, Cobalt Alloys, Stainless Steels, Biodegradable Alloys, Medical Applications, Optimization of Metallic Biomaterials, Multifunctional Implants, Tissue Reactions, Toxicity of Metals, Inflammatory Reactions, Immunological Reactions, Sensibility, Allergy, Carcinogenic Effects, Ceramic Coatings, Ionic Implantation in Plasma, Biocompatibility.