Joyce Y. Wong – författare

For medical devices that must be placed inside the body, the right choice of material is the most important aspect of design. To ensure such devices are safe, reliable, economical, and biologically and physiologically compatible, the modern biomedical engineer must have a broad knowledge of currently available materials and the properties that affect their in-service performance.In chapters drawn from the third edition of the best-selling Biomedical Engineering Handbook, Biomaterials surveys the wide variety of biomaterials in present use as well as materials resulting from novel micro- and nanoscale technologies. The book includes a general overview of bioinert, bioactive or surface reactive ceramics, and biodegradable or re-absorbable bioceramics. It reviews basic chemical and physical properties of the synthetic polymers, covers the sterilization of the polymeric biomaterials, discusses the importance of the surface treatment for improving biocompatibility, and examines the application of the chemogradient surface for the study on cell polymer interactions. The book also provides an overview of the chemistry design, fabrication, and application of biodegradable hydrogels for drug delivery and tissue engineering. It explores current issues involved in probing cell-biomaterials interactions on the molecular level and their implications for tissue engineering research and examines advances in biodegradable polymeric materials, soft and hard tissue replacements, and applications in tissue engineering.Taking a focuses look at the latest advances in biomaterials, the book discusses metallic, ceramic, polymeric, and composite biomaterials. With more than 100 figures and tables, as well as contributions from a panel of international experts, the book gives you familiarity with the uses of biomaterials in medicine and dentistry

For medical devices that must be placed inside the body, the right choice of material is the most important aspect of design. To ensure such devices are safe, reliable, economical, and biologically and physiologically compatible, the modern biomedical engineer must have a broad knowledge of currently available materials and the properties that affe

For medical devices that must be placed inside the body, the right choice of material is the most important aspect of design. To ensure such devices are safe, reliable, economical, and biologically and physiologically compatible, the modern biomedical engineer must have a broad knowledge of currently available materials and the properties that affe

Most current applications of biomaterials involve structural functions, even in those organs and systems that are not primarily structural in their nature, or very simple chemical or electrical functions. Complex chemical functions, such as those of the liver, and complex electrical or electrochemical functions, such as those of the brain and sense

Most current applications of biomaterials involve structural functions, even in those organs and systems that are not primarily structural in their nature, or very simple chemical or electrical functions. Complex chemical functions, such as those of the liver, and complex electrical or electrochemical functions, such as those of the brain and sense organs, cannot be carried out by biomaterials at this time. With these basic concepts in mind, Biomaterials: Principles and Practices focuses on biomaterials consisting of different materials such as metallic, ceramic, polymeric, and composite. It highlights the impact of recent advances in the area of nano- and microtechnology on biomaterial design. Discusses the biocompatibility of metallic implants and corrosion in an in vivo environmentProvides a general overview of the relatively bioinert, bioactive or surface-reactive ceramics, and biodegradable or resorbable bioceramicsReviews the basic chemical and physical properties of synthetic polymers, the sterilization of the polymeric biomaterials, the importance of the surface treatment for improving biocompatibility, and the application of the chemogradient surface for the study on cell-to-polymer interactionsCovers the fundamentals of composite materials and their applications in biomaterialsHighlights commercially significant and successful biomedical biodegradable polymersExamines failure modes of different types of implants based on material, location, and function in the bodyThe book discusses the role of biomaterials as governed by the interaction between the material and the body, specifically, the effect of the body environment on the material and the effect of the material on the body.

Most current applications of biomaterials involve structural functions, even in those organs and systems that are not primarily structural in their nature, or very simple chemical or electrical functions. Complex chemical functions, such as those of the liver, and complex electrical or electrochemical functions, such as those of the brain and sense

This book covers up-to-date knowledge of how designs found in nature use tissue hierarchies to achieve optimal functions, and how these principles are applied in bioengineering. The hierarchy-based multiscale approach has the potential to drive novel biomaterial designs, advance tissue engineering and regeneration, assist in tissue-function integration, improve high-fidelity computational modeling aided by machine learning, and enhance the development of innovative characterization tools and methodologies. This book presents the latest high-impact research achievements in bioengineered and natural hierarchical systems within a clinical context. Our aim is two-fold: (i) to emphasize the importance of integrating and bridging bioengineering designs at various tissue hierarchical levels and (ii) to foster dialogue and collaboration among bioengineers, biomechanists, and clinicians.

This book covers up-to-date knowledge of how designs found in nature use tissue hierarchies to achieve optimal functions, and how these principles are applied in bioengineering. The hierarchy-based multiscale approach has the potential to drive novel biomaterial designs, advance tissue engineering and regeneration, assist in tissue-function integration, improve high-fidelity computational modeling aided by machine learning, and enhance the development of innovative characterization tools and methodologies. This book presents the latest high-impact research achievements in bioengineered and natural hierarchical systems within a clinical context. Our aim is two-fold: (i) to emphasize the importance of integrating and bridging bioengineering designs at various tissue hierarchical levels and (ii) to foster dialogue and collaboration among bioengineers, biomechanists, and clinicians.