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Biomechanical Biofeedback Systems and Applications (Human–Computer Interaction Series)

This book deals with the topic of biomechanical biofeedback systems and applications that are primarily aimed at motor learning in sports and rehabilitation. It gives a comprehensive tutorial of the concepts, architectures, operation, and exemplary applications of biomechanical biofeedback systems. A special section is dedicated to various constraints in designing biomechanical biofeedback systems. The book also describes the technologies needed for the adequate operation of biofeedback systems, such as motion tracking, communication, processing, and sensor technologies. In regard to technologies, the emphasis is on the assurance of the requirements of the real-time system operation. The application focus is on the usage in sport and rehabilitation, particularly in the field of accelerated motor learning and injury prevention. We include several examples of operational (real-time) biofeedback applications in golf, skiing, and swimming. The book is in the first place intended for the professional audience, researchers, and scientists in the fields connected to the topics of this book.

Biomechanical Microsystems: Design, Processing and Applications (Lecture Notes in Computational Vision and Biomechanics #24)

This book presents the most important aspects of analysis of dynamical processes taking place on the human body surface. It provides an overview of the major devices that act as a prevention measure to boost a person‘s motivation for physical activity. A short overview of the most popular MEMS sensors for biomedical applications is given. The development and validation of a multi-level computational model that combines mathematical models of an accelerometer and reduced human body surface tissue is presented. Subsequently, results of finite element analysis are used together with experimental data to evaluate rheological properties of not only human skin but skeletal joints as well. Methodology of development of MOEMS displacement-pressure sensor and adaptation for real-time biological information monitoring, namely “ex vivo” and “in vitro” blood pulse type analysis, is described. Fundamental and conciliatory investigations, achieved knowledge and scientific experience about biologically adaptive multifunctional nanocomposite materials, their properties and synthesis compatibility, periodical microstructures, which may be used in various optical components for modern, productive sensors‘ formation technologies and their application in medicine, pharmacy industries and environmental monitoring, are presented and analyzed. This book also is aimed at research and development of vibrational energy harvester, which would convert ambient kinetic energy into electrical energy by means of the impact-type piezoelectric transducer. The book proposes possible prototypes of devices for non-invasive real-time artery pulse measurements and micro energy harvesting.

Biomechanical Modelling and Simulation on Musculoskeletal System

The book involves the basic principles, methods, anatomy and other knowledge for modelling and simulation of the musculoskeletal system. In addition, abundant examples are presented in detail to help readers easily learn the principles and methods of modelling and simulation. These examples include the impact injury and clinical application of the modelling of bone and muscle. In terms of impact injury, the book introduces the biomechanical simulation of impact injury in head, spine, ankle, knee, eyeball and many other parts. With regard to clinical application, it explores the optimization of orthopaedic surgery and design of orthopaedic implants. Readers will find this is a highly informative and carefully presented book, introducing not only the biomechanical principles in the musculoskeletal system, but also the application abilities of modelling and simulation on the musculoskeletal system.

Biomechanical Modelling at the Molecular, Cellular and Tissue Levels (CISM International Centre for Mechanical Sciences #508)

Biomechanical Principles and Applications in Sports

This book provides an overview of biomedical applications in sports, including reviews of the current state-of-the art methodologies and research areas. Basic principles with specific case studies from different types of sports as well as suggested student activities and homework problems are included. Equipment design and manufacturing, quantitative evaluation methods, and sports medicine are given special focus. Biomechanical Principles and Applications in Sports can be used as a textbook in a sports technology or sports engineering program, and is also ideal for graduate students and researchers in biomedical engineering, physics, and sports physiology. It can also serve as a useful reference for professional athletes and coaches interested in gaining a deeper understanding of biomechanics and exercise physiology to improve athletic performance.

Biomechanical Principles on Force Generation and Control of Skeletal Muscle and their Applications in Robotic Exoskeleton (Advances in Systems Science and Engineering (ASSE))

This book systematically introduces the bionic nature of force sensing and control, the biomechanical principle on mechanism of force generation and control of skeletal muscle, and related applications in robotic exoskeleton. The book focuses on three main aspects: muscle force generation principle and biomechanical model, exoskeleton robot technology based on skeletal muscle biomechanical model, and SMA-based bionic skeletal muscle technology. This comprehensive and in-depth book presents the author's research experience and achievements of many years to readers in an effort to promote academic exchanges in this field. About the Author Yuehong Yin received his B.E. , M.S. and Ph.D. degrees from Nanjing University of Aeronautics and Astronautics, Nanjing, in 1990, 1995 and 1997, respectively, all in mechanical engineering. From December 1997 to December 1999, he was a Postdoctoral Fellow with Zhejiang University, Hangzhou, China, where he became an Associate Professor in July 1999. Since December 1999, he has been with the Robotics Institute, Shanghai Jiao Tong University, Shanghai, China, where he became a Professor and a Tenure Professor in December 2005 and January 2016, respectively. His research interests include robotics, force control, exoskeleton robot, molecular motor, artificial limb, robotic assembly, reconfigurable assembly system, and augmented reality. Dr. Yin is a fellow of the International Academy of Production Engineering (CIRP).

Biomechanical Principles on Force Generation and Control of Skeletal Muscle and their Applications in Robotic Exoskeleton (Advances in Systems Science and Engineering (ASSE))

This book systematically introduces the bionic nature of force sensing and control, the biomechanical principle on mechanism of force generation and control of skeletal muscle, and related applications in robotic exoskeleton. The book focuses on three main aspects: muscle force generation principle and biomechanical model, exoskeleton robot technology based on skeletal muscle biomechanical model, and SMA-based bionic skeletal muscle technology. This comprehensive and in-depth book presents the author's research experience and achievements of many years to readers in an effort to promote academic exchanges in this field. About the Author Yuehong Yin received his B.E. , M.S. and Ph.D. degrees from Nanjing University of Aeronautics and Astronautics, Nanjing, in 1990, 1995 and 1997, respectively, all in mechanical engineering. From December 1997 to December 1999, he was a Postdoctoral Fellow with Zhejiang University, Hangzhou, China, where he became an Associate Professor in July 1999. Since December 1999, he has been with the Robotics Institute, Shanghai Jiao Tong University, Shanghai, China, where he became a Professor and a Tenure Professor in December 2005 and January 2016, respectively. His research interests include robotics, force control, exoskeleton robot, molecular motor, artificial limb, robotic assembly, reconfigurable assembly system, and augmented reality. Dr. Yin is a fellow of the International Academy of Production Engineering (CIRP).

Biomechanical Transport Processes (Nato Science Series A: #193)

Proceedings of a NATO ARW held in Cargese, France, October 9-13, 1989

Biomechanics: Selected Proceedings of the Fifth Meeting of the European Society of Biomechanics, September 8–10, 1986, Berlin, F.R.G. (Developments in Biomechanics #3)

By definition Biomechanics is the application of engineering methods to study the mechanical aspects of living beings. Mostly the life scientists have the questions but lack of the specialized methods. The engineers on the other hand can handle very specialized equipment and methods, but lack in the biological thinking. If both sides are able to adapt to each other, Biomechanics is a classical field of interdis­ ciplinary cooperation. In the beginning, most biomechanical research was done in the field of orthopaedics. But other areas like cardiovascular research, dentistry, sports and many others gain increasing importance. This situation is clearly reflected in this book, which contains a selected number of papers which were presented at the Fifth Meeting of the European Society of Biomechanics, held in September 1986 in Berlin. Meanwhile these meetings have become a well accepted forum and a place of interdis­ ciplinary discussion for scientists in Biomechanics on the one side and surgeons and other peoples interested in biome­ chanical solutions on the other. It is the third time that the proceedings are published as a book and the editors are sure that this volume will help to establish this series "Developement in Biomechanics" as a valuable tool for all people involved in Biomechanics. The Fifth Meeting of the ESB also marks the tenth anniversary in the short history of the European Society of Biomechanics.

Biomechanics: Proceeding of the First Rock Island Arsenal Biomechanics Symposium April 5–6, 1967 (pdf)

Biomechanics: Mechanical Properties of Living Tissues

The motivation for writing aseries ofbooks on biomechanics is to bring this rapidly developing subject to students of bioengineering, physiology, and mechanics. In the last decade biomechanics has become a recognized disci­ pline offered in virtually all universities. Yet there is no adequate textbook for instruction; neither is there a treatise with sufficiently broad coverage. A few books bearing the title of biomechanics are too elementary, others are too specialized. I have long feIt a need for a set of books that will inform students of the physiological and medical applications of biomechanics, and at the same time develop their training in mechanics. We cannot assume that all students come to biomechanics already fully trained in fluid and solid mechanics; their knowledge in these subjects has to be developed as the course proceeds. The scheme adopted in the present series is as follows. First, some basic training in mechanics, to a level about equivalent to the first seven chapters of the author's A First Course in Continuum Mechanics (Prentice-Hall,lnc. 1977), is assumed. We then present some essential parts of biomechanics from the point of view of bioengineering, physiology, and medical applications. In the meantime, mechanics is developed through a sequence of problems and examples. The main text reads like physiology, while the exercises are planned like a mechanics textbook. The instructor may fil1 a dual role: teaching an essential branch of life science, and gradually developing the student's knowledge in mechanics.

Biomechanics: Mechanical Properties of Living Tissues

The objective of this book remains the same as that stated in the first edition: to present a comprehensive perspective of biomechanics from the stand point of bioengineering, physiology, and medical science, and to develop mechanics through a sequence of problems and examples. My three-volume set of Bio­ mechanics has been completed. They are entitled: Biomechanics: Mechanical Properties of Living Tissues; Biodynamics: Circulation; and Biomechanics: Motion, Flow, Stress, and Growth; and this is the first volume. The mechanics prerequisite for all three volumes remains at the level of my book A First Course in Continuum Mechanics (3rd edition, Prentice-Hall, Inc. , 1993). In the decade of the 1980s the field of Biomechanics expanded tremen­ dously. New advances have been made in all fronts. Those that affect the basic understanding of the mechanical properties of living tissues are described in detail in this revision. The references are brought up to date.

Biomechanics: Functional Adaption and Remodeling

"Function dictates structure" is a classic paradigm reaffirmed in Wolff's law of the skeletal system. A major question being addressed by current research in biomechanics is whether this doctrine also holds true for the cardiovascular system and connective tissues. Taking a multidisciplinary approach to this question has produced new insights into the sensors, signals, and activators that produce remodeling and functional adaptation in cardiac muscle, blood vessels, and bone, including important new findings on the response of vascular endothelial cells to shear stress. Other work focuses on the extent of remodeling and adaptation processes in tendons, ligaments, and intervertebral discs. Together with two companion volumes, Computational Biomechanics and the Data Book on Mechanical Properties of Living Cells, Tissues, and Organs, this monograph will prove invaluable to those working in fields ranging from medical science and clinical medicine to biomedical engineering and applied mechanics.

Biomechanics: Trends in Modeling and Simulation (Studies in Mechanobiology, Tissue Engineering and Biomaterials #20)

The book presents a state-of-the-art overview of biomechanical and mechanobiological modeling and simulation of soft biological tissues. Seven well-known scientists working in that particular field discuss topics such as biomolecules, networks and cells as well as failure, multi-scale, agent-based, bio-chemo-mechanical and finite element models appropriate for computational analysis. Applications include arteries, the heart, vascular stents and valve implants as well as adipose, brain, collagenous and engineered tissues.The mechanics of the whole cell and sub-cellular components as well as the extracellular matrix structure and mechanotransduction are described. In particular, the formation and remodeling of stress fibers, cytoskeletal contractility, cell adhesion and the mechanical regulation of fibroblast migration in healing myocardial infarcts are discussed. The essential ingredients of continuum mechanics are provided. Constitutive models of fiber-reinforced materials with an emphasis on arterial walls and the myocardium are discussed and the important influence of residual stresses on material response emphasized. The mechanics and function of the heart, the brain and adipose tissues are discussed as well. Particular attention is focused on microstructural and multi-scale modeling, finite element implementation and simulation of cells and tissues.

Biomechanics: Selected Proceedings of the 3rd General Meeting of the European Society of Biomechanics Nijmegen, The Netherlands, 21–23 January 1982 (Developments in Biomechanics #1)

Biomechanics as a scientific activity is not new. Already involved (or so it is said) in its practice were Aristotle (384-327 BC) and Leonardo da Vinci (1452-1519). Recently, however, it has become fashionable as a separate field, as witnessed by the existence of a Journal of Biomechanics (1968), an Interna­ tional (1973), a European (1976) and an American (1977) Society of Biomechanics, and an amount of (usually recently erected) Biomechanics Laboratories at Uni­ versities or other institutions throughout the world. If one or~anises a Con­ ference on Biomechanics, a relatively large number of scientists leave their cubicles or workshops to visit the place of worship. It becomes quickly evident, however, that such a forum for scientific communication is far from being homo­ geneous. All are not of the same believe, and the variety in professional inte­ rests almost parallels the number of attendants. "Biomechanics, the science of applying methods and principles of Mechanics to biological tissues and medical problems" is a definition which, in one form or another, has found wide acceptance among biomecanicians. Nevertheless, Bio­ mechanics is interwoven and thus often confused with other scientific endeavors. It is colored differently by its many fields of application (e. g. Orthopaedic and Cardio-Vascular Surgery, Dentistry, Rehabilitation, Physical Medicine, Injury Prevention, Sports and others), and the backgrounds of its disciplina­ ries. It partly overlaps sciences as Biomaterials, Medical Physics and Biophy­ sics, Physiology, and Functional Anatomy.

Biomechanics: Selected proceedings of the Fourth Meeting of the European Society of Biomechanics in collaboration with the European Society of Biomaterials, September 24–26, 1984, Davos, Switzerland (Developments in Biomechanics #2)

The papers presented at the Fourth 'Meeting of the European Society of Biomechanics, held in collaboration with the European Society for Biomaterials in late September 1984 in Davos, Switzerland, are published herewith. The main idea of the meeting was to gather together the many disciplines of researchers and clinicians active and interested in promoting biomechanical knowledge in one interdisciplinary society: the European Society of Biomechanics. We feel that the dialog across the disciplines is one of the important goals of the society, a goal which can be furthered by meetings like the one in Davos. A surgeon, whether a general, trauma or orthopaedic surgeon, is normally brought up without relevant exposure to spe­ cific technical problems. It therefore is not surprising that he speaks a different language with respect to mechanical problems than an engineer. Although a surgeon often has a feeling for what the solution to a particular problem might be, a fruitful inter­ disciplinary collaboration is made difficult by this scientific language barrier. On the other hand, a physicist, chemist, engi­ neer and metallurgist, to name a few, would do well with a realistic perception of the possibilities and limitations of surgery and of the relevance of a solution found to the initial question. Similar problems exist in other areas, e. g. in the field of sports biomechanics in the dialogue betweeen coach and researcher. Interdisciplinary misunderstandings have led to quite some unaeces£ary frustration in the past.

Biomechanics: Principles and Practices

Presents Current Principles and ApplicationsBiomedical engineering is considered to be the most expansive of all the engineering sciences. Its function involves the direct combination of core engineering sciences as well as knowledge of nonengineering disciplines such as biology and medicine. Drawing on material from the biomechanics section of The

Biomechanics: Principles and Applications, Second Edition

Traditionally, applications of biomechanics will model system-level aspects of the human body. As a result, the majority of technological progress to date appears in system-level device development. More recently, biomechanical initiatives are investigating biological sub-systems such as tissues, cells, and molecules. Fueled by advances in experime

Biomechanics and Biomaterials in Orthopedics

With the constant evolution of implant technology, and improvement in the production of allograft and bone substitutes, the armamentarium of the orthopaedic surgeon has significantly expanded. In particular, the recent involvement of nanotechnologies opens up the possibilities of new approaches in the interactive interfaces of implants. With many important developments occurring since the first edition of this well-received book, this updated resource informs orthopaedic practitioners on a wide range of biomechanical advances in one complete reference guide.Biomechanics and Biomaterials in Orthopedics, 2nd edition compiles the most prominent work in the discipline to offer newly-qualified orthopedic surgeons a summary of the fundamental skills that they will need to apply in their day-to-day work, while also updating the knowledge of experienced surgeons. This book covers both basic concepts concerning biomaterials and biomechanics as well as their clinical application and the experience from everyday practical use. This book will be of great value to specialists in orthopedics and traumatology, while also providing an important basis for graduate and postgraduate learning.

Biomechanics and Biomaterials in Orthopedics

Current clinical orthopedic practice requires practitioners to have extensive knowledge of a wide range of disciplines from molecular biology to bioengineering and from the application of new methods to the evaluation of outcome. The biomechanics of and biomaterials used in orthopedics have become increasingly important as the possibilities have increased to treat patients with foreign material introduced both as optimized osteosynthesis after trauma and as arthroplasties for joint diseases, sequelae of trauma or for tumor treatment. Furthermore, biomaterial substitutes are constantly being developed to replace missing tissue. Biomechanics and Biomaterials in Orthopedics provides an important update within this highly important field. Professor Dominique Poitout has collected a series of high-quality chapters by globally renowned researchers and clinicians. Under the auspices of the International Society of Orthopaedic Surgery and Traumatology (SICOT) and International Society of Orthopaedic and Traumatology Research (SIROT), this book now provides permanent and specific access to the considerable international knowledge in the field of locomotor system trauma and disease treatment using the novel bioengineering solutions. This book covers both basic concepts concerning biomaterials and biomechanics as well as their clinical application and the experience from everyday practical use. This book will be of great value to specialists in orthopedics and traumatology, while also provide an important basis for graduate and postgraduate learning.

Biomechanics and Exercise Physiology: Quantitative Modeling

Whether you are a bioengineer designing prosthetics, an aerospace scientist involved in life support, a kinesiologist training athletes, or an occupational physician prescribing an exercise regimen, you need the latest edition of Biomechanics and Exercise Physiology: Quantitative Modeling. Using numerous worked examples to demonstrate what and when

Biomechanics and Mechanobiology of Aneurysms (Studies in Mechanobiology, Tissue Engineering and Biomaterials #7)

Cardiovascular disease is the leading cause of morbidity and premature death of modern era medicine. It is estimated that approximately 81 million people in the United States (US) currently have one or more of the many forms of cardiovascular disease, resulting in 1 in every 2.8 deaths, or 900,000 deaths per year. 40% of all deaths in Europe are a result of cardiovascular disease in people under the age of 75. Aneurysms form a significant portion of these cardiovascular related deaths and are defined as a permanent and irreversible localised dilation of a blood vessel greater than 50% of its normal diameter. Although aneurysms can form in any blood vessel, the more lethal aneurysms develop in the cranial arteries, and in the thoracic aorta and abdominal aorta. Frequently aneurysms are undetected and if left untreated may eventually expand until rupture with very high levels of morbidity and mortality. The biomechanics and mechanobiology of aneursymal diseases are not fully understood and this monograph aims to provide new insights into aneurysm aetiology and behavior based on the most recent biomechanics research related to this important topic. The contributors to this volume bring together a unique blend of expertise in experimental, computational and tissue biomechanics relating to aneurysm behavior and enable the reader to gain a fresh understanding of key factors influencing aneurysm behavior and treatment. Biological risk factors such as tobacco smoking, sex, age, hypertension, family history and mechanobiological risk factors such as aneurysm geometry and shape as well as mechanical properties of the diseased tissues are considered in detail as are many of the diagnostic and treatment options.

Biomechanics and Sports: Proceedings of the XI Winter Universiads 2003 (CISM International Centre for Mechanical Sciences #473)

On XXI Winter Universiads 2003, CISM offered its scientific contribution by hosting a conference on mechanics applied to sports and, in general, to human movement. The conference was conceived as a chance to overview experiences gained from several operators working on different aspects of biomechanics. The reader will face in these proceedings bioengineering aspects, control issues, techniques for the optimization of human performances as well as methods for the improvement of athletic equipments and devices. Biomechanical data and signal processing, biomaterials and robotics complete the proposed framework. Some works were consistent with the fact that 2003 was designated as European Year of Disabled People. Indeed, many innovations in sport and biomechanics could suggest interesting rehabilitative applications and a better prevention of some pathologies due to the exercise of some normal activities like professional cycling. Ž

Biomechanics for Instructors

This book comprises a series of lectures given by celebrated Soviet neurophysiologist Nikolai Alexandrovich Bernstein in Moscow in 1925 and first published in Russian in 1926. Bernstein’s groundbreaking work, which has had a significant influence on the development of neuroscience, movement studies, and other fields of study in Russia, Eastern Europe, and the West, was suppressed during Stalin’s regime. At the time of its publication, Biomechanics for Instructors was a significant resource for teachers, with its descriptions of the movement of joints and degrees of freedom, illustrations of how to calculate the work capacity of muscles with bones acting as levers, the role of the central nervous system in movement, and more. Though the terminologies and methods have changed and been updated as research and technologies have progressed, the book remains a valuable introduction for those interested in Bernstein’s work more generally, and to those involved in the study of biomechanics. This book is also of interest to historians and philosophers of neuroscience, as well as those involved in movement studies in both the scientific and artistic domains, and to physiotherapists and those involved in sports research and practice.

Biomechanics in Dentistry: Evaluation of Different Surgical Approaches to Treat Atrophic Maxilla Patients (SpringerBriefs in Applied Sciences and Technology)

This book shows computational finite element simulations to analyse the strength of implant anchorage for intrasinus and extramaxillary approaches under various occlusal loading locations and directions. Three-dimensional model of the craniofacial area surrounding the region of interest, soft tissue and framework are developed using computed tomography image datasets. The zygomatic and standard dental implants are modeled using a conventional computer-aided design software and placed at the appropriate location. Material properties are assigned appropriately for the cortical, cancellous bones and implants with Masseter forces applied at the zygomatic arch and occlusal loadings applied on the framework surface.