This is the only single authored text on biological polymers available for bioengineering and biomedical engineering students. The book describes the structure of polymers and how these molecules are put together to make the tissues of the body and also their role in surgical implants and in structural diseases. It provides essential reading for biomedical engineers, biologists, physicians, health care professionals and other biomedical researchers who are interested in understanding how physical forces affect the biology, physiology and pathophysiology of humans. The author is an expert on the effect of mechanical forces on extracellular matrix.

This text for students and researchers, takes an interdisciplinary approach to describing the chemistry and physics of materials, their biocompatibility, and the consequences of implantation of devices made of these materials into the human body. The reader is introduced to the principles of polymer science and the study of metals, ceramics and composites, and also to the basic biology required to understand the nature of the host-transplant interface. Topics covered in this book include the macromolecular components of cells and tissues, self-assembly processes, biological cascade systems, microscopic structure of cells and tissues, immunology, transplantation biology, and the pathobiology of wound healing. Topics covered in the materials science chapters include the structures and properties of polymers, metals, ceramics and composites, and the processes for forming materials as well as the pathobiology of devices. The final two chapters deal with tissue engineering and the relations between the biology of cells and tissue transplantation, and the engineering of tissue replacements using passaged cells.

This is the only single authored text on biological polymers available for bioengineering and biomedical engineering students. The book describes the structure of polymers and how these molecules are put together to make the tissues of the body and also their role in surgical implants and in structural diseases. It provides essential reading for biomedical engineers, biologists, physicians, health care professionals and other biomedical researchers who are interested in understanding how physical forces affect the biology, physiology and pathophysiology of humans. The author is an expert on the effect of mechanical forces on extracellular matrix.

Adopting an interdisciplinary approach to the chemistry and physics of materials, their biocompatibility, and the consequences of implantation of such devices into the human body, this text introduces readers to the principles of polymer science and the study of metals, ceramics and composites, and also to the basic biology required to understand the nature of the host-transplant interface. Topics covered include the macromolecular components of cells and tissues, self-assembly processes, biological cascade systems, microscopic structure of cells and tissues, immunology, transplantation biology, and the pathobiology of wound healing. The materials science section includes the structures and properties of polymers, metals, ceramics and composites, and the processes for forming materials as well as the pathobiology of devices. The final two chapters deal with tissue engineering and the relations between the biology of cells and tissue transplantation, and the engineering of tissue replacements using passaged cells.

Robert Owen was one of the most extraordinary Englishmen who ever lived and a great man. In a way his history is the history of the establishment of modern industrial Britain, reflected in the mind and activities of a very intelligent, capable and responsible industrialist, alive to the best social thought of his time. The organisation of industrial labour, factory legislation, education, trade unionism, co-operation, rationalism: he was passionately and ably engaged in all of them. His community at New Lanark was the nearest thing to an industrial heaven in the Britain of dark satanic mills; he tried to found a rational co-operative community in the USA. In everything he contemplated, he saw education as a key. This selection of his writings on education illustrates his rationalist concept of the formation of character and its implications for education and society; also his growing utopian concern with social reorganisation; and third, his impact on social movements. Silver's introduction shows Owen's relationship to particular educational traditions and activities and his long-term influence on attitudes to education.

UV and X-ray spectroscopy of astrophysical and laboratory plasmas draws interest from many disciplines. Contributions from international specialists are collected together in this book from a timely recent conference. In astrophysics, the Hubble Space Telescope, Astro 1 and ROSAT observatories are now providing UV and X-ray spectra and images of cosmic sources in unprecedented detail, while the Yohkoh mission recently collected superb data on the solar corona. In the laboratory, the development of ion-trap facilities and novel laser experiments are providing vital new data on high temperature plasmas. Recent innovations in the technology of spectroscopic instrumentation are discussed. These papers constitute an excellent up-to-date review of developments in short-wave length spectroscopy and offer a solid introduction to its theoretical and experimental foundations.

Modern science and engineering relies heavily on understanding computer hardware and software in order to make effective use of these tools in the laboratory and industrial environments. The authors of Modern Instrumentation: A Computer Approach have succeeded in producing a highly readable source that will serve both newcomers to the field as well as experienced professionals.
Including both fundamentals and applications, the book first describes the role of the computer in instrument systems and provides numerous practical examples. The second part of the book explores specific software packages and their capabilities for applications such as, instrument design and simulation, data acquisition, data processing, and the potential of artificial intelligence in instrument design.
Because of the full integration of theory with practical applications of leading software packages, this book is an extremely useful reference for those who use computer-based instrument technology for data acquisition and who are involved with hardware or software development for laboratory and process control.