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Authoritative international experts comprehensively review many current state-of-the-art uses of polymers, metals, and ceramics in the human body. A veritable encyclopedia of valuable data and experience, this volume not only fully addresses the major issues of compatibility and functionality, but also provides a technical treatise on the design and evaluation of biomaterials for vascular application and on biomaterials as carriers for bioactive agents. A second volume, Biomaterials Engineering and Devices: Human Applications, Volume 2 is devoted to biomaterials for dental applications, bony biomaterials for grafting applications, and orthopedic fixtures and cements. Extensively illustrated and referenced, Biomaterials Engineering and Devices: Human Applications, Volume 1: Fundamentals and Vascular and Carrier Applications integrates for today's bioengineering professionals the basic science, engineering, and practical medical experience needed to meet the ever-growing demand for new and better biomaterials.
The medical device and drug industries standards in analytical methodology and are consistently among the strongest techno- quality control. logical performers. Materials are a key The users of Biomaterials Engineering ingredient in their dynamic growth. Devel- and Devices: Human Applications will r- opment of these materials is in a constant resent a broad base of backgrounds ranging state of activity, with the challenge of re- from the basic sciences (e. g. , polymer placing old materials that cannot withstand chemistry and biochemistry) to more the tests of time, and the new materials’ applied disciplines (e. g. , mechanical/ needs coming to the forefront in modern chemical engineering, orthopedics, and applications. This new reference text, pharmaceutics). To meet varied needs, each Biomaterials Engineering and Devices: chapter provides clear ancd fully detailed Human Applications, focuses on materials discussions. This in-depth, but practical, used in or on the human body—materials coverage should also assist recent indu- that define the world of “biomaterials. ” ees to the biomaterials circle. The editors Biomaterials Engineering and Devices: trust that this reference textbook conveys Human Applications focuses on mate- the intensity of this fast moving field in an rials development and characterization. enthusastic presentation. Chapters deal with issues in the selection of Donald L. Wise, PHD proper biomaterials from biocompatibility Debra J. Trantolo, PHD to biostability to structure/function relation- Kai-Uwe Lewandrowski, MD ships. Chapters also focus on the use of Joseph D. Gresser, PHD specific biomaterials based on their physio- Mario V.
Nineteen cutting-edge articles by leading practitioners review critical issues concerning biocompatible materials-polymers, metals, and other materials-used in or on the human body. Topics range from biopolymers used in controlled release drug delivery systems and synthetic burn-wound dressings to specific orthopedic devices. Each application-oriented article integrates basic science, engineering and medical experience with discussions of quality control. The contributors offer a wealth of valuable data and experience to materials scientists, research engineers, and academic physicians and surgeons. Their many examples provide rich insights into our experience today with a broad spectrum of modern biomaterials applications.
The success of any implant or medical device depends very much on the biomaterial used. Synthetic materials (such as metals, polymers and composites) have made significant contributions to many established medical devices. The aim of this book is to provide a basic understanding on the engineering and processing aspects of biomaterials used in medical applications. Of paramount importance is the tripartite relationship between material properties, processing methods and design. As the target audiences cover a wide interdisciplinary field, each chapter is written with a detailed background so that audience of another discipline will be able to understand. For the more knowledgeable reader, a detailed list of references is included.
Maintaining quality of life in an ageing population is one of the great challenges of the 21st Century. This book summarises how this challenge is being met by multi-disciplinary developments of specialty biomaterials, devices, artificial organs and in-vitro growth of human cells as tissue engineered constructs.Biomaterials, Artificial Organs and Tissue Engineering is intended for use as a textbook in a one semester course for upper level BS, MS and Meng students. The 25 chapters are organized in five parts: Part one provides an introduction to living and man-made materials for the non-specialist; Part two is an overview of clinical applications of various biomaterials and devices; Part three summarises the bioengineering principles, materials and designs used in artificial organs; Part four presents the concepts, cell techniques, scaffold materials and applications of tissue engineering; Part five provides an overview of the complex socio-economic factors involved in technology based healthcare, including regulatory controls, technology transfer processes and ethical issues. - Comprehensive introduction to living and man-made materials - Looks at clinical applications of various biomaterials and devices - Bioengineering principles, materials and designs used in artificial organs are summarised
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
"This book is essential when designing, developing and studying biomedical materials. provides an excellent review-from a patient, disease, and even genetic point of view-of materials engineering for the biomedical field. This well presented book strongly insists on how the materials can influence patients' needs, the ultimate drive for biomedic
A succinct introduction to the field of biomaterials engineering, packed with practical insights.
Structural Biomaterials: Properties, Characteristics, and Selection serves as a single point of reference to digest current research and develop a deeper understanding in the field of biomaterials engineering. This book uses a materials-focused approach, allowing the reader to quickly access specific, detailed information on biomaterials characterization and selection. Relevant to a range of readers, this book provides holistic coverage of the broad categories of structural biomaterials currently available and used in medical applications, highlighting the property requirements for structural biomaterials, their biocompatibility performance and their safety regulation in key categories such as metals, ceramics and polymers. The materials science perspective of this text ensures the content is accessible even to those without an extensive background in applied medicine, positioning this text not just for students, but as an overview and reference for researchers, scientists and engineers entering the field from related materials science disciplines. - Provides a unique, holistic approach, covering key biomaterials categories in one text, including metals, ceramics and polymers - Discusses advantages, disadvantages, biocompatibility performance and safety regulations, allowing for accurate materials selection in medical applications - Utilizes a materials science perspective, allowing those without an extensive applied medical background to learn about the field
This book presents a broad scope of the field of biomaterials science and technology, focusing on theory, advances and applications. It is written for those who would like to develop their interest and knowledge towards biomaterials or materials science and engineering. All aspects of biomaterials science are thoroughly addressed, from basic principles of biomaterials, organs and medical devices to advanced topics such as tissue engineering, surface engineering, sterilization techniques, 3D printing and drug delivery systems. Readers are also introduced to major concepts of surface modification techniques, and potential applications of different classes of biomaterials. Multiple-choice questions at the end of every chapter will be helpful for students to test their understanding of each topic, with answers provided at the end of the book.Ultimately, this book offers a one-stop source of information on the essentials of biomaterials and engineering. It is useful both as an introduction and advanced reference on recent advances in the biomaterials field. Suitable readers include undergraduate and graduate students, especially those in Materials Science, Biomedical Engineering and Bioengineering.