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This book enables the reader to make an informed choice in the selection of biomaterials, aiding the creation of safe and long-lasting surgical devices. Looking at metals, ceramics and polymers with craniofacial, cardiovascular, spinal, dentistry and orthopaedic applications, the book is an essential guide to tribology in biomaterials.
Tribo-Behaviors of Biomaterials and Their Applications enables the reader to make an informed choice in the selection of biomaterials that aid the creation of safe and long-lasting surgical devices. Looking at metals, ceramics, and polymers with craniofacial, cardiovascular, spinal, dentistry, and orthopedic applications, this book is an essential guide to tribology in biomaterials. Handling wear within biodevices is a pressing issue due to the continuous friction and corrosion within the body. It is further complicated by the involvement of body fluids, which can lead to revision surgery to relieve pain. In order to lessen this, engineers can choose a biomaterial better suited to the application. Including detailed discussion of the properties of each biomaterial, this book covers the behaviors of implants, along with the methods and standards applied to devices. It has chapters on metals, ceramics, and polymers. It also covers body fluid lubrication and the physiological effects they have on implants, along with their tribo-corrosion behaviors. This book will be of interest to engineers and researchers in the field of biomechanical engineering, biomedical engineering, materials science, and manufacturing engineering, alongside all those researching tribology and nanocomposites.
Mechanical Behaviour of Biomaterials focuses on the interface between engineering and medicine, where new insights into engineering aspects will prove to be extremely useful in their relation to the biomedical sciences and their applications. The book's main objective focuses on the mechanical behavior of biomaterials, covering key aspects, such as mechanical properties, characterization and performance. Particular emphasis is given to fatigue, creep and wear, fracture, and stress and strain relationships in biomaterials. Chapters look at both experimental and theoretical results. Readers will find this to be an essential reference for academics, biomechanical researchers, medical doctors, biologists, chemists, physicists, mechanical, biomedical and materials engineers and industrial professionals. - Presents contributions from international experts - Provides insights at the interface of disciplines, such as engineering and the medical and dental sciences - Presents a comprehensive understanding on the mechanical properties of biomaterials - Covers surface and bulk properties
Tribocorrosion: Fundamentals, Methods, and Materials provides a balanced coverage of recent advancements in both experimental and computational areas of tribocorrosion, covering the basic concepts of tribology and electrochemistry, as well as testing set-ups, protocols, electrochemical methods, and more. It outlines experimental methods, demonstrating the different effects of material loss due to mechanical and electrochemical actions and looks at their effects in applied automotive, aerospace and biomedical settings. Standard testing protocols, tribocorrosion mechanisms in sliding contacts, and modeling and simulation techniques are all covered at length, as is bio-tribocorrosion and the best ways to prevent it. - Provides a complete overview of tribocorrosion testing, experimentation and modeling methods that in turn empower safer, environmentally-friendlier and cost-saving applications - Balances experimental and computational methods, thus encouraging readers to define and develop experimental and investigative techniques specific to their tribo-system of interest - Covers tribocorrosion behavior in passive and non-passive metals and alloys, coatings, modified surfaces, metal matrix composites, and more
This book provides a comprehensive overview of metal matrix composite manufacturing, including fabrication methods, characterization techniques, and manufacturing applications. 10 chapters cover fundamental and applied topics on matrix metal composites. The book is a resource for all readers seeking to gain an in-depth understanding of metal matrix composites with its relevance to the modern industry. Key Features - Includes fully referenced contributions by experts in materials science - Provides an introduction to the subject, and a future prospective for a broad range of readers - Reviews current knowledge on fabrication techniques and structure property relationships of metal matrix composites - Includes dedicated chapters for reinforced composites (carbon fiber, carbon nanotubes, aluminium) - Includes guidance on material wear and tear and - Provides an investigation for process optimization for EDM for newly developed composites It is designed to be an essential resource for students and professionals in the field of materials science and engineering, as well as researchers and engineers working on metal matrix composite in manufacturing industries.
Nanostructured Biomaterials for Cranio-maxillofacial and Oral Applications examines the combined impact of materials science, biomedical and chemical engineering, and biology to provide enhanced biomaterials for applications in maxillo-facial rehabilitation and implantology. With a strong focus on a variety of material classes, it examines material processing and characterization techniques to decrease mechanical and biological failure in the human body. After an introduction to the field, the most commonly used materials for cranio-facial applications, including ceramics, polymers and glass ceramics are presented. The book then looks at nanostructured surfaces, functionally graded biomaterials and the manufacturing of nanostructured materials via 3-D printing. This book is a valuable resource for scientists, researchers and clinicians wishing to broaden their knowledge in this important and developing field. - Explores the techniques used to apply nanotechnology to biomaterials for cranio-maxillofacial and oral applications - Bridges the gap between fundamental materials science and medicine - Shows how nanostructured biomaterials respond when implanted in the human body
During the last few years, tribocorrosion evaluation of artificial joints has become an attractive research area for biomedical scientists and medical professionals. This particular field of study deals with a complex artificial human joint system and many unknown parameters. In this chapter an attempt is made through the perspective of a clinician to bring some insights into this area of research. This chapter addresses the basic tribocorrosion aspects of artificial joints and their clinical implications, beginning with clinical problems, cell responses to the presence of metal particles and ions, and evidence of tribocorrosion from retrieved implants. Then comparisons are made between in vivo and in vitro test conditions, and the complex nature of in vivo joint conditions is discussed. Finally, novel case studies (influence of protein and environment, evidence of synergistic interactions between corrosion and wear) on the research of tribocorrosion of metal-on-metal (MoM) hip joints are also included.
This book describes available tribology technologies and introdces a comprehensive overview of tribology. General, up-to-date knowledge on how tribology is approached in various related areas of research, both experimental and computational is provided.
During their service life, most biomaterials and medical implants are vulnerable to tribological damage. In addition, the environments in which they are placed are often corrosive. The combination of triobology, corrosion and the biological environment has been named 'bio-tribocorrosion'. Understanding this complex phenomenon is critical to improving the design and service life of medical implants. This important book reviews recent key research in this area.After an introduction to the topography of bio-tribocorrosion, Part one discusses different types of tribocorrosion including fatigue-corrosion, fretting-corrosion, wear-corrosion and abrasion-corrosion. The book also discusses the prediction of wear in medical devices. Part two looks at biological effects on tribocorrosion processes, including how proteins interact with material surfaces and the evolution of surface changes due to bio-tribocorrosion resulting from biofilms and passive films. Part three reviews the issue of bio-tribocorrosion in clinical practice, including dental applications and joint replacement as well the use of coatings and test methods for bio-tribocorrosion.With its international team of contributors, Bio-tribocorrosion in biomaterials and medical implants is a standard reference for those researching and developing medical devices as well as clinicians in such areas as dentistry and orthopaedic surgery. - Reviews recent research in bio-tribocorrosion and its role in improving the design and service life of medical implants - Discusses types of bio-tribocorrosion including fatigue and wear corrosion - Examines biological effects on bio-tribocorrosion processes including interaction of proteins with metal surfaces
The history of use of dental materials and biomaterial dates back to the BC era, but the real advances in this field have occurred since the 19th century, due to the invention and understanding of new materials. These advances have been due to the continuous quest for new materials and new technologies used for the design and fabrication of new and novel materials, and, in particular, the understanding of new materials with innovative clinical applications. These have only been possible due to interdisciplinary research of a translational nature, where physicians, surgeons, dentists, and materials scientists work together for a common and targeted goal. It is important for clinicians to understand the needs of the patient, who translates those needs for the materials scientist to develop an implant to improve the quality of life for the patient. Once the chemical, physical, mechanical, and biological properties of the materials are well understood, then these materials can be tailored to provide specific clinical applications. Development in the field of tissue engineering and regenerative medicine has only been possible due to work from this partnership. This Special Issue will provide an excellent forum to bring together different communities and publish research of a high caliber, which will be beneficial to healthcare.