Cardiac Mechano-Electric Coupling and Arrhythmias offers a thoroughly reviewed compendium written by leading experts in the field on the mechanism and consequences of cardiac mechano-electrical coupling. Its coverage ranges from stretch-activated ion channels to mechanically induced arrhythmias and mechanical interventions for heart rhythm correction. Information is grouped into logical sections, from molecular mechanisms, to cell, tissue and whole organ responses, right through to patient-based observations and insight emerging from clinical trials. The information provided carefully highlights both consensus insight and current shortcomings in our understanding of cardiac mechano-electric coupling. The book has been thoroughly revised and expanded since publication of the first edition in 2005, extensively updated to reflect recent developments in the field, and now offers a more balanced view of mechano-electrical interactions in the heart and develops a more clinical focus. Written with the practising cardiologist and junior doctor in mind, it offers interesting new insight for the established physician with an interest in cardiac arrhythmogenesis and heart rhythm management.
Kohl (Cardio Mechano-Electric Feedback Lab, Oxford University) documents the role of mechano-electric feedback (MEF) in electrical and mechanical pathological remodeling of cardiac function. Sections cover sub-cellular mechanisms of cardiac MEF, effects of MEF on cardiac cellular electrophysiology, experimental manifestations of MEF in the heart, cardiac MEF in normal physiology, cardiac MEF as a pathogenic mechanism, MEF as a mechanism involved in therapeutic interventions, and the outlook for the future. B&w and color photos and medical images are included. Annotation: 2005 Book News, Inc., Portland, OR (booknews.com).
This book presents the latest findings in the field of cardiac mechanobiology in health and disease. Cardiac mechanobiology provides knowledge of all aspects of mechanobiology of the heart. Cardiomyogenesis is discussed as well as the mechanobiology of cardiac remodeling and regeneration. The molecular mechanisms of mechanoperception and mechanotransduction in cardiomyocytes are explained, as well as stretch induced differentiation of cardiomyocytes derived from induced pluripotent stem cells. This volume of the series Cardiac and Vascular Biology complements the volume Vascular Mechanobiology in Physiology and Disease (volume 8) published in this series. The book is aimed at clinicians as well as researchers in cardiovascular biology, bioengineering and biophysics, and also represents an educational resource for young researchers and students in these fields.
Cardiac Electrophysiology: From Cell to Bedside defines the entire state of current scientific and clinical knowledge in this subspecialty. In response to the many major recent developments in the field, Drs. Zipes and Jalife have completely updated this modern classic, making the 5th Edition the most significant revision yet. From our latest understanding of ion channels, molecular genetics, and cardiac electrical activity through newly recognized syndromes, unique needs of special patient populations, and new diagnostic and therapeutic options, you'll find all the state-of-the-art guidance you need to make informed, effective clinical decisions. What's more, a significantly restructured organization, a new full-color layout, and full-text online access make reference easier than ever. Integrates the latest scientific understanding of arrhythmias with the newest clinical applications, giving you an informed basis for choosing the right treatment and management options for each patient. Synthesizes the knowledge of preeminent authorities in cardiology, physiology, pharmacology, pediatrics, biophysics, pathology, cardiothoracic surgery, and biomedical engineering from around the world, giving you a well-rounded, expert grasp of every issue that affects your patient management. Contains 24 new chapters (listed below) as well as exhaustive updates throughout, to keep you current with new scientific knowledge, newly discovered arrhythmia syndromes, and new diagnostic and therapeutic techniques. Developmental Regulation of Cardiac Ion Channels Neural Mechanisms of Initiating and Maintaining Arrhythmias Single Nucleotide Polymorphisms and Acquired Cardiac Arrhythmias Inheritable Sodium Channel Diseases Inheritable Potassium Channel Diseases Inheritable Diseases of Intracellular Calcium Regulation Morphological Correlates of Atrial Arrhythmias Andersen-Tawil Syndrome Timothy Syndrome Progressive Cardiac Conduction Disease Sudden Infant Death Syndrome Arrhythmias in Patients with Neurologic Disorders Autonomic Testing Cardiac Resynchronization Therapy Energy Sources for Catheter Ablation Linear Lesions to Ablate Atrial Fibrillation Catheter Ablation of Ventricular Arrhythmias in Patients with Structural Heart Disease Catheter Ablation of Ventricular Arrhythmias in Patients without Structural Heart Disease Catheter Ablation in Patients with Congenital Heart Disease Features a completely new section on "Arrhythmias in Special Populations" that explores arrhythmias in athletes ... gender differences in arrhythmias ... arrhythmias in pediatric patients ... and sleep-disordered breathing and arrhythmias. Offers an attractive new full-color design featuring color photos, tables, flow charts, ECGs, and more, making clinically actionable information easy to find and absorb at a glance. Includes full-text online access via Expert Consult, making reference easier for busy practitioners.
This book presents a multidisciplinary approach to cardiac mechanotransduction. The chapters depict the many faces of the topic, from membrane and ion channel level to mechanics, biochemical signaling and regulation via hormone systems. Cardiac Mechanotransduction is of interest to basic life sciences, like physiology, biochemistry and pharmacology, but also to clinicians working with heart-related problems, such as cardiologists and internists.
Pathological heart rhythms are a major health issue. In this book experts from various fields provide an important context for understanding the complicated molecular and cellular mechanisms that underlie normal and pathophysiological cardiac rhythms. Individual chapters cover a full range of topics, including the ionic basis of pacemaking, the role of specific channels and transporters in sinoatrial node pacemaking, altered intracellular Ca2+ handling in response to disease, computer modeling of the action potentials of pacemaker and working cardiomyocytes, genetic and molecular basis of inherited arrhythmias and a review of established and novel antiarrhythmic agents. Due to the key importance of the specialized pacemaker cells and tissue (sinoatrial and atrioventricular nodes) in maintaining heart rate and rhythm, special emphasis is placed on the peculiar electrophysiology of these cells.
This completely updated and expanded 2nd Edition provides all the information needed in order to understand the complex molecular, cellular and genetic mechanisms that underlie normal and abnormal cardiac rhythms. Its goal is to help physiologists and clinicians alike develop better preventive and treatment strategies. The respective chapters cover a broad range of topics, including the role of specific ion channels and transporters, gap junctions, intracellular Ca2+ handling in pacemaker activity, impulse conduction, and the activity of atrial and ventricular myocardium. Special emphasis is placed on the unique electrophysiology of specialized pacemaking cells and conducting fibers. In turn, several types of inherited and acquired ventricular arrhythmias are presented in detail. Clinicians will especially appreciate the updated information on even common disorders like atrial fibrillation and their impacts on human physiology. In closing, the book goes “one step further” and considers future prospects, e.g. novel antiarrhythmic agents and new concepts like optogenetics, in the context of heart rate regulation. Accordingly, it offers readers a solid reference guide to everything they need to know about human heart rate and rhythm.
This introduction to the role of sodium-calcium exchange in calcium homeostasis contains a series of articles written by leading scientists which cover such topics as sodium-calcium exchange in intact cells, in photoreceptors and in sodium transporting epithelia.
Electrical Disease of the Heart, 2nd Edition, volume 1, provides a valuable insight to the latest developments in the field of cardiac electrophysiology and clinical electrocardiology. Each chapter includes up-to-date results of studies aimed at providing an understanding of the electrical function of the heart in health and disease, established and evidence-based knowledge of clinical outcomes, areas of controversy, and future trends. This book is highly relevant to a broad audience, ranging from medical and graduate students, to clinicians and scientists.