The continual growth and increasing sophistication of biomaterials industries has been driven in large part by advances in the basic sciences of the materials involved. Indeed, advances in understanding biological systems at the molecular level have quickly been exploited by materials scientists to develop more sophisticated approaches to therapeutics and diagnostics. The interdisciplinarity and breadth of the biomaterials field necessitates the close co-operation of scientists in many different fields, including materials science, chemistry, biology, engineering and medicine. This book, first published in 1999, brings together researchers in many of these converging fields to report on advances and to stimulate further discussion and research in these vital areas of discovery and development. Topics include: polymeric drugs and delivery; musculoskeletal tissue engineering; scaffolds and cell seeding - fabrication and characterization techniques; biological cues and organic/inorganic hybrids; novel materials, porous structure and tissue engineering; and orthopaedic bearing surfaces and novel coatings.

Biointegration is essential for the successful performance of implanted materials and devices within the human body. With an increasing number and wide range of implant procedures being performed, it is critical that materials scientists and engineers effectively design implant materials which will create a positive biological and mechanical response with the host tissue.Biointegration of medical implant materials provides a unique and comprehensive review of recent techniques and research into material and tissue interaction and integration. Part one discusses soft tissue biointegration with chapters on the biocompatibility of engineered stem cells, corneal tissue engineering and vascular grafts. Part two then reviews particular techniques in drug delivery including inorganic nanoparticles for targeted drug delivery and alginate based drug delivery devices. Part three covers design considerations with coverage of themes such as biocompatibility of materials and its relevance to drug delivery and tissue engineering, mechanisms of failure of medical implants during long term use and rapid prototyping in biomedical engineering.With its distinguished editor and team of international contributors, Biointegration of medical implant materials: science and design is a standard reference for medical materials scientists and engineers in industry and the academic sector. - Provides a unique and comprehensive review of recent techniques and research into material and tissue interaction and integration - Discusses soft tissue biointegration with chapters on the biocompatibility of engineered stem cells, corneal tissue engineering, vascular grafts and replacement materials for facial reconstruction - Reviews particular techniques in drug delivery featuring inorganic nanoparticles and functionalized nanoparticles for targeted drug delivery

The MRS Symposium Proceeding series is an internationally recognised reference suitable for researchers and practitioners.

"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 biomedical engineering. ...[presents an] Interesting and innovative review from a patient focus perspective—the book emphasizes the importance of the patients, which is not often covered in other biomedical material’s books." —Fanny Raisin-Dadre, BioInteractions Ltd., Berkshire, England Going far beyond the coverage in most standard books on the subject, Biomaterials Science: An Integrated Clinical and Engineering Approach offers a solid overview of the use of biomaterials in medical devices, drug delivery, and tissue engineering. Combining discussion of materials science and engineering perspectives with clinical aspects, this book emphasizes integration of clinical and engineering approaches. In particular, it explores various applications of biomaterials in fields including tissue engineering, neurosurgery, hemocompatibility, BioMEMS, nanoparticle-based drug delivery, dental implants, and obstetrics/gynecology. The book engages those engineers and physicians who are applying biomaterials at various levels to: Increase the rate of successful deployment of biomaterials in humans Lower the side-effects of such a deployment in humans Accumulate knowledge and experience for improving current methodologies Incorporate information and understanding relevant to future challenges, such as permanent artificial organ transplants Using a variety of contributors from both the clinical and engineering sides of the fields mentioned above, this book stands apart by emphasizing a need for the often lacking approach that integrates these two equally important aspects.

Biointegration of Medical Implant Materials, Second Edition, provides a unique and comprehensive review of recent techniques and research into material and tissue interaction and integration. New sections discuss soft tissue integration, with chapters on the biocompatibility of engineered stem cells, corneal tissue engineering, and vascular grafts. Other sections review tissue regeneration, inorganic nanoparticles for targeted drug delivery, alginate based drug delivery devices, and design considerations, with coverage of the biocompatibility of materials and their relevance to drug delivery and tissue engineering. With its distinguished editor and team of international contributors, this book is ideal for medical materials scientists and engineers in industry and academia. Provides a unique and comprehensive review of recent techniques and research into material and tissue interaction and integration Discusses soft tissue biointegration, with chapters on the biocompatibility of engineered stem cells, corneal tissue engineering, vascular grafts and replacement materials for facial reconstruction Includes new information on a variety of tissue regeneration techniques and applications

This volume focuses on a variety of production and processing aspects of the latest biomaterials. It discusses how scaffolds are used in tissue engineering and describes common implant materials, such as hard tissue, blood contacting, and soft tissue. The book also examines the important role nanotechnology plays in the preparation of drugs, protein delivery, tissue engineering, cardiovascular biomaterials, hard tissue replacements, biosensors, and bio-MEMS. With contributions from renowned international experts and extensive reference lists in each chapter, this book provides detailed, practical information to produce biomaterials and employ them in biomedicine.

Active implants are actually drug or protein-eluting implants that induce healing effects, in addition to their regular task, such as support. This effect is achieved by controlled release of the active agent to the surrounding tissue. This book will give a broad overview of biomaterial platforms used as basic elements of drug-eluting implants. It will include mainly coatings for vascular stents with controlled release of antiproliferative agents, wound dressings with controlled release of antibacterial agents, drug-eluting vascular grafts, protein-eluting scaffolds for tissue regeneration, drug-eluting platforms for dental and other applications. Thus, both internal and external implants are described. The drug-eluting implants will be described in terms of matrix formats and polymers, incorporated drugs and their release profiles from the implants, as well as implant functioning. Smart polymeric systems, such as crosslinked poly-lactones, thermo and pH-sensitive hydrogels and poly(amido-amines), as well as novel basic structural elements, such as composite fibers and films, and nanostructures will be thoroughly described. The effect of the processing parameters on the microstructure and on the resulting drug release profiles, mechanical and physical properties, and other relevant properties, will be emphasized. The described new biomaterials approaches for active implants enhance the tools available for creating clinically important biomedical applications.