Historical folklore indicates that Asklepios (circa 900 BC), the fir~t western doctor of ancient Greece, treated many patients with rheumatic diseases of 1 joints ,2. Later, Hippocrates (circa 400 BC), who claimed to have learned from Asklepios, used the term arthritis in reference to joint diseases: "When the disease of arthritis strikes, acute inflammation and pain attacks the joints of the body ... ". Indeed, arthritic joint disease dates much farther back into antiquity than Asklepios. Many modern anthropologists have noted degenerative joint disease in the fossils of Neanderthal man (archanthropus europeus petraloniensis) and even in those of dinosaurs. More recent scientific studies on joints date back to the work of the great English anatomist Hunter who wrote "The Structure and Diseases of Articular Cartilage" in the Philosophical Transactions of London in 1743. The notion that osteoarthritis results from the wearing away of cartilage was copiously documented by the histological observations of the German physician Ecker in 1843. This idea was further supported by Pommer (1927) who felt that mechanical stresses played important roles in the initiation and propagation of cartilage lesions leading to osteoarthritis. This same conclusion was reached by the assembled distinguished experts at a National Institutes of Health Workshop 3 held in 1986 .
This book summarizes the theoretical and experimental studies confirming the concept of the liquid-crystalline nature of boundary lubrication in synovial joints. It is shown that cholesteric liquid crystals in the synovial liquid play a significant role in the mechanism of intra-articular friction reduction. The results of structural, rheological and tribological research of the creation of artificial synovial liquids containing cholesteric liquid crystals in natural synovial liquids are described. These liquid crystals reproduce the lubrication properties of natural synovia and provide a high chondroprotective efficiency. They were tested in osteoarthritis models and in clinical practice.
Biomechanics is concerned with the response of living matter to forces, and its study has taken long strides in recent years. In the past two decades, biomechanics has brought improved understanding of normal and patho physiology of organisms at molecular, cellular, and organ levels; it has helped developing medical diagnostic and treatment procedures; it has guided the design and manufacturing of prosthesis and instruments; it has suggested the means for improving human performance in the workplace, sports, and space; it has made us understand trauma in war and in peace. Looking toward the future, we see many more areas of possible development such as: reduction in heart diseases and atherosclerosis improved vascular assist and replacement devices, including a permanent artifical heart enhanced oxygen transport in the lung understanding and control of growth and changes mechanics of neuromuscular control and robotics prevention of joint degeneration permanent total joint replacements prevention of low back pain workplace designs to enhance productivity ambulation systems for the handicapped fully implantable hearing aids improved understanding of the mechanisms for permanent disability injuries identification of factors such as alcohol use and disease influence on impact tolerance improved cellular bioreactor designs mechanics of DNA and its application in biotechnology. * Obviously, the attainment of these prospects will greatly improve the quality of human life and reduce the costs of living. * This list is from a report by the U. S. National Committee on Biomechanics, April, 1985.
Contains papers presented at the Third International Symposium on Computer Methods in Biomechanics and Biomedical Engineering (1997), which provide evidence that computer-based models, and in particular numerical methods, are becoming essential tools for the solution of many problems encountered in the field of biomedical engineering. The range of subject areas presented include the modeling of hip and knee joint replacements, assessment of fatigue damage in cemented hip prostheses, nonlinear analysis of hard and soft tissue, methods for the simulation of bone adaptation, bone reconstruction using implants, and computational techniques to model human impact. Computer Methods in Biomechanics and Biomedical Engineering also details the application of numerical techniques applied to orthodontic treatment together with introducing new methods for modeling and assessing the behavior of dental implants, adhesives, and restorations. For more information, visit the "http://www.uwcm.ac.uk/biorome/international symposium on Computer Methods in Biomechanics and Biomedical Engineering/home page, or "http://www.gbhap.com/Computer_Methods_Biomechanic s_Biome dical_Engineering/" the home page for the journal.
Extensively revised from a successful first edition, this book features a wealth of clear illustrations, numerous worked examples, and many problem sets. It provides the quantitative perspective missing from more descriptive texts, without requiring an advanced background in mathematics, and as such will be welcomed for use in courses such as biomechanics and orthopedics, rehabilitation and industrial engineering, and occupational or sports medicine.
A trustworthy clinical companion, the textbook offers best practice and management strategies for these common joint diseases. Formerly published as Osteoarthritis, the extensively revised third edition of the Oxford Textbook of Osteoarthritis and Crystal Arthropathy provides up-to-date and evidence-based guidance on how to assess, diagnose, and manage patients. A prestigious and international author team ensure information is expert and relevant-this is a practical tool for clinicians managing people with osteoarthritis, gout, and other crystal-associated arthritis. Confidently consider and chose the right blend of treatment for your patient, whether physical, pharmacological, surgical, or supportive. The Oxford Textbook of Osteoarthritis and Crystal Arthropathy provides full coverage of joint failure, and includes detailed sections on epidemiology, risk factors, clinical assessment, and investigations. This edition also now includes new sections on gout and other crystal arthropathies. Clinically relevant and easily understandable overviews of basic science, including pathology and pain physiology, along with critical appraisal of current guidelines, make this a highly valuable resource. Significant coverage is also given to patient education and the involvement of the patient in management planning. Also highly illustrated, the textbook is a strong reference tool with summary boxes and key points at the end of chapters making it easy to find information quickly and help you deliver the optimum patient outcome. The textbook equips rheumatologists and musculoskeletal health professionals with the knowledge to provide best possible patient care.
Biomechanics applies the principles and rigor of engineering to the mechanical properties of living systems. This book integrates the classic fields of mechanics--statics, dynamics, and strength of materials--using examples from biology and medicine. Fundamentals of Biomechanics is excellent for teaching either undergraduates in biomedical engineering programs or health care professionals studying biomechanics at the graduate level. Extensively revised from a successful first edition, the book features a wealth of clear illustrations, numerous worked examples, and many problem sets. The book provides the quantitative perspective missing from more descriptive texts, without requiring an advanced background in mathematics. It will be welcomed for use in courses such as biomechanics and orthopedics, rehabilitation and industrial engineering, and occupational or sports medicine.
Richly illustrated and presented in clear, concise language, Biomechanics of Skeletal Muscles is an essential resource for those seeking advanced knowledge of muscle biomechanics. Written by leading experts Vladimir Zatsiorsky and Boris Prilutsky, the text is one of the few to look at muscle biomechanics in its entirety—from muscle fibers to muscle coordination—making it a unique contribution to the field. Using a blend of experimental evidence and mechanical models, Biomechanics of Skeletal Muscles provides an explanation of whole muscle biomechanics at work in the body in motion. The book first addresses the mechanical behavior of single muscles—from the sarcomere level up to the entire muscle. The architecture of human muscle, the mechanical properties of tendons and passive muscles, the biomechanics of active muscles, and the force transmission and shock absorption aspects of muscle are explored in detail. Next, the various issues of muscle functioning during human motion are addressed. The transformation from muscle force to joint movements, two-joint muscle function, eccentric muscle action, and muscle coordination are analyzed. This advanced text assumes some knowledge of algebra and calculus; however, the emphasis is on understanding physical concepts. Higher-level computational descriptions are placed in special sections in the later chapters of the book, allowing those with a strong mathematical background to explore this material in more detail. Readers who choose to skip over these sections will find that the book still provides a strong conceptual understanding of advanced topics. Biomechanics of Skeletal Muscles also contains numerous special features that facilitate readers’ comprehension of the topics presented. More than 300 illustrations and accompanying explanations provide an extensive visual representation of muscle biomechanics. Refresher sidebars offer brief reminders of mathematical and biomechanical concepts, and From the Literature sidebars present practical examples that illustrate the concepts under discussion. Chapter summaries and review questions provide an opportunity for reflection and self-testing, and reference lists at the end of each chapter provide a starting point for further study. Biomechanics of Skeletal Muscles offers a thorough explanation of whole muscle biomechanics, bridging the gap between foundational biomechanics texts and scientific literature. With the information found in this text, readers can prepare themselves to better understand the latest in cutting-edge research. Biomechanics of Skeletal Muscles is the third volume in the Biomechanics of Human Motion series. Advanced readers in human movement science gain a comprehensive understanding of the biomechanics of human motion as presented by one of the world’s foremost researchers on the subject, Dr. Vladimir Zatsiorsky. The series begins with Kinematics of Human Motion, which details human body positioning and movement in three dimensions; continues with Kinetics of Human Motion, which examines the forces that create body motion and their effects; and concludes with Biomechanics of Skeletal Muscles, which explains the action of the biological motors that exert force and produce mechanical work during human movement.
