Download Free Muscle Biology Book in PDF and EPUB Free Download. You can read online Muscle Biology and write the review.

Muscle Biology: The Life History of a Muscle looks at the story of a muscle from its embryonic beginnings, through its growth and ability to adapt to changing functional circumstances during adult life, to its eventual decline in both structure and function as old age progresses. Injury occurs to muscle during normal activity, after trauma, and during the source of certain diseases. Chapters on both muscle regeneration and muscle diseases emphasize the possibilities and limitsations of the healing capacity of muscle fibers. Muscle Biology begins with a brief review about the structure and function of a normal mature muscle and then proceeds to follow the developmental history of a muscle from the embryo to old age in a manner that gives the reader a perspective about not only developmental controls but also how at any stage of development a muscle is able to adapt to its functional environment. The book discusses both normal and abnormal changes in the muscle, the mechanisms behind those changes and how to mitigate deleterious changes from disease, 'normal' aging, and disuse/lack of physical activity. This is a must-have reference for students, researchers and practitioners in need of a comprehensive overview of muscle biology. - Provides an overview of muscle biology over the course of one's entire lifespan - Explains the important elements of each aspect of muscle biology without drowning the reader in excessive detail - Contains over 300 illustrations and includes chapter summaries
Muscle: Fundamental Biology and Mechanisms of Disease will be the first reference covering cardiac, skeletal, and smooth muscle in fundamental, basic science, translational biology, disease mechanism, and therapeutics. Currently there are no publications covering the science behind the medicine, as the majority of books are 90% clinical and 10% science. Muscle: Fundamental Biology and Mechanisms of Disease will discuss myocyte biology, also known as muscle cell biology, providing information about the science behind clinical work and therapeutics with a 90% science and 10% clinical focus. A needed resource for researchers, clinical professionals, postdocs, and graduate students, this publication will further discuss basic biology development and physiology, how processes go awry in disease states, and how the defective pathways are targeted for therapy. This book will assist both the new and experienced clinician's and researcher's need for science translation of background research into clinical applications, bridging the gap between research and clinical knowledge.
Many of the difficulties that meat and animal scientists face when attempting to address specific problems-such as stress susceptibility and poor meat quality in swine-stem from a lack of understanding of the underlying biological mechanisms that drive muscle growth, metabolism, and its conversion to meat. This book provides current knowledge about
This title is directed primarily towards health care professionals outside of the United States. It starts with the origin of life and ends with the mechanisms that make muscles adapt to different forms of training. In between, it considers how evidence has been obtained about the extent of genetic influence on human capacities, how muscles and their fibres are studied for general properties and individual differences, and how molecular biological techniques have been combined with physiological ones to produce the new discipline of molecular exercise physiology. This is the first book on such topics written specifically for modules in exercise and sport science at final year Hons BSc and taught MSc levels.
The student of biolo,gical science in his final years as an undergraduate and his first years as a graduate is expected to gain some familiarity with current research at the frontiers of his discipline. New research work is published in a perplexing diversity of publications and is inevitably concerned with the minutiae of the subject. The sheer number of research journals and papers also causes confusion and difficulties of assimilation. Review articles usually presuppose a background knowledge of the field and are inevitably rather restricted in scope. There is thus a need for short but authoritative introductions to those areas of modern biological research which are either not dealt with in standard introductory textbooks or are not dealt with in sufficient detail to enable the student to go on from them to read scholarly reviews with profit. This series of books is designed to satisfy this need. The authors have been asked to produce a brief outline of their subject assuming that their readers will have read and remembered much of a standard introductory textbook of biology. This outline then sets out to provide by building on this basis, the conceptual framework within which modern research work is progressing and aims to give the reader an indication of the problems, both conceptual and practical, which must be overcome if progress is to be maintained.
The book addresses the development of muscle atrophy, which can be caused by denervation, disuse, excessive fasting, aging, and a variety of diseases including heart failure, chronic kidney diseases and cancers. Muscle atrophy reduces quality of life and increases morbidity and mortality worldwide. The book is divided into five parts, the first of which describes the general aspects of muscle atrophy including its characteristics, related economic and health burdens, and the current clinical therapy. Secondly, basic aspects of muscle atrophy including the composition, structure and function of skeletal muscle, muscle changes in response to atrophy, and experimental models are summarized. Thirdly, the book reviews the molecular mechanisms of muscle atrophy, including protein degradation and synthesis pathways, noncoding RNAs, inflammatory signaling, oxidative stress, mitochondria signaling, etc. Fourthly, it highlights the pathophysiological mechanisms of muscle atrophy in aging and disease. The book’s fifth and final part covers the diagnosis, treatment strategies, promising agents and future prospects of muscle atrophy. The book will appeal to a broad readership including scientists, undergraduate and graduate students in medicine and cell biology.
Since the middle of the last century we have progressively built up a comprehensive descriptive model of the allied mechanisms that maintain our muscles at a size and strength appropriate to the functional demands upon them and that rapidly repair damaged muscles. This volume is an assemblage of the collective experience from the pick of major research groups investigating these aspects of muscle cell biology. It provides up-to-date coverage and presents a broad range of topics.
Muscle contraction has been the focus of scientific investigation for more than two centuries, and major discoveries have changed the field over the years. Early in the twentieth century, Fenn (1924, 1923) showed that the total energy liberated during a contraction (heat + work) was increased when the muscle was allowed to shorten and perform work. The result implied that chemical reactions during contractions were load-dependent. The observation underlying the “Fenn effect” was taken to a greater extent when Hill (1938) published a pivotal study showing in details the relation between heat production and the amount of muscle shortening, providing investigators with the force-velocity relation for skeletal muscles. Subsequently, two papers paved the way for the current paradigm in the field of muscle contraction. Huxley and Niedergerke (1954), and Huxley and Hanson (1954) showed that the width of the A-bands did not change during muscle stretch or activation. Contraction, previously believed to be caused by shortening of muscle filaments, was associated with sliding of the thick and thin filaments. These studies were followed by the classic paper by Huxley (1957), in which he conceptualized for the first time the cross-bridge theory; filament sliding was driven by the cyclical interactions of myosin heads (cross-bridges) with actin. The original cross-bridge theory has been revised over the years but the basic features have remained mostly intact. It now influences studies performed with molecular motors responsible for tasks as diverse as muscle contraction, cell division and vesicle transport.