Cardiology Science and Technology comprehensively deals with the science and biomedical engineering formulations of cardiology. As a textbook, it addresses the teaching, research, and clinical aspects of cardiovascular medical engineering and computational cardiology. The books consists of two sections. The first section deals with left ventricular (LV) wall stress, cardiac contractility, ventricular remodeling, active wall stress and systolic pressure generation, and vector cardiogram characteristics, with applications in cardiology. The second section covers ECG signal analysis for arrhythmias detection, LV pumping (intra-LV, aortic and coronary flow) characteristics, and coronary bypass surgery design, with applications in cardiology and cardiac surgery. This book is like an exciting train ride through the heart and into blood flows within its chamber, the coronary tree, the aorta, and finally into coronary flow and bypass grafting. The train starts from the heart's central station and journeys through exciting places of heart wall stresses, cardiac contractility measures to characterize heart failure, and active stress generation to develop systolic heart pressure. We learn about cardiomyopathic heart remodeling and its surgical ventricular restoration, theory of ECG and vector cardiogram with medical applications, and heart rate variability signal processing to detect cardiac arrhythmias. In the heart chamber, we witness the amazing intricate intra-ventricular flow patterns. Then, we study pressure pulse wave propagation into the aorta, determination of pulse wave velocity and arterial elasticity as a measure of arteriosclerosis. We climb into the mountainous coronary terrain and look at the fascinating scenery of coronary flows and myocardial perfusion that governs cardiac contractility. Finally, we arrive at coronary bypass grafting and witness the new sequential anastomosis design for enhanced patency.

Der Band enthalt die Beitrage der Sektion D des zweiten Gauss-Symposiums vom 2. - 8. August 1993 in Munchen. Die Themen der Beitrage spannen den weiten Bogen von mathematischer Modellierung von biologisch und medizinisch wichtigen Prozessen uber Fragen der Medikamentierung bis hin zur Erforschung des menschlichen Bewusstseins.

Biomedical Engineering Modeling of Pancreatic, Respiratory, and Renal Regulatory Systems, and their Medical Assessments addresses the need for biomedical engineering to provide physiological analysis of organ systems and their medical applications to help enable quantitative formulation of physiological systems and defining their functions and dysfunctions, leading to precision diagnostics of diabetes, lung diseases, and kidney failure, often in the form of non-dimensional indices. The book chapters also deal with treatment systems, namely automated insulin infusion systems, hemodialysis, and peritoneal dialysis. The book is formulated to solve many physiological, bioengineering, and medical problems.

Coronary Artery Bypass Grafting (CABG) is performed to relieve angina and reduce the risk of death from coronary artery disease by improving coronary perfusion and myocardium supply. However, CABG has a limited long-term patency, mainly due to anastomotic intimal hyperplasia. It is well proven that hemodynamic factors are implicated in the initiation and progression of intimal hyperplasia. In order to further improve the hemodynamics at the downstream anastomosis and alleviate the drawbacks of the available CABG anastomosis designs so as to attain higher patency rates in bypass grafts, a novel coupled side-to-side and end-to-side sequential anastomoses configuration design is developed in this work. Extensive computational simulations and in vitro measurements (utilizing Particle Image Velocimetry) have verified beneficial hemodynamic and advantageous flow characteristics of this novel CABG configuration. This book can serve as a valuable resource guide for coronary bypass surgical procedures and a biomedical engineering course on myocardial revascularization, to cardiac surgeons and biomedical engineers.

Cardiovascular diseases (CVD) including heart diseases, peripheral vascular disease and heart failure, account for one-third of deaths throughout the world. CVD risk factors include systolic blood pressure, total cholesterol, high-density lipoprotein cholesterol, and diabetic status. Clinical trials have demonstrated that when modifiable risk factors are treated and corrected, the chances of CVD occurring can be reduced. This illustrates the importance of this book's elaborate coverage of cardiovascular physiology by the application of mathematical and computational methods.This book has literally transformed Cardiovascular Physiology into a STEM discipline, involving (i) quantitative formulations of heart anatomy and physiology, (ii) technologies for imaging the heart and blood vessels, (iii) coronary stenosis hemodynamics measure by means of fractional flow reserve and intervention by grafting and stenting, (iv) fluid mechanics and computational analysis of blood flow in the heart, aorta and coronary arteries, and (v) design of heart valves, percutaneous valve stents, and ventricular assist devices.So how is this mathematically and computationally configured landscape going to impact cardiology and even cardiac surgery? We are now entering a new era of mathematical formulations of anatomy and physiology, leading to technological formulations of medical and surgical procedures towards more precise medicine and surgery. This will entail reformatting of (i) the medical MD curriculum and courses, so as to educate and train a new generation of physicians who are conversant with medical technologies for applying into clinical care, as well as (ii) structuring of MD-PhD (Computational Medicine and Surgery) Program, to train competent medical and surgical specialists in precision medical care and patient-specific surgical care.This book provides a gateway for this new emerging scenario of (i) science and engineering based medical educational curriculum, and (ii) technologically oriented medical and surgical procedures. As such, this book can be usefully employed as a textbook for courses in (i) cardiovascular physiology in both the schools of engineering and medicine of universities, as well as (ii) cardiovascular engineering in biomedical engineering departments worldwide.

Cardiology Science and Technology comprehensively deals with the science and biomedical engineering formulations of cardiology. As a textbook, it addresses the teaching, research, and clinical aspects of cardiovascular medical engineering and computational cardiology. The books consists of two sections. The first section deals with left ventricular (LV) wall stress, cardiac contractility, ventricular remodeling, active wall stress and systolic pressure generation, and vector cardiogram characteristics, with applications in cardiology. The second section covers ECG signal analysis for arrhythmias detection, LV pumping (intra-LV, aortic and coronary flow) characteristics, and coronary bypass surgery design, with applications in cardiology and cardiac surgery. This book is like an exciting train ride through the heart and into blood flows within its chamber, the coronary tree, the aorta, and finally into coronary flow and bypass grafting. The train starts from the heart's central station and journeys through exciting places of heart wall stresses, cardiac contractility measures to characterize heart failure, and active stress generation to develop systolic heart pressure. We learn about cardiomyopathic heart remodeling and its surgical ventricular restoration, theory of ECG and vector cardiogram with medical applications, and heart rate variability signal processing to detect cardiac arrhythmias. In the heart chamber, we witness the amazing intricate intra-ventricular flow patterns. Then, we study pressure pulse wave propagation into the aorta, determination of pulse wave velocity and arterial elasticity as a measure of arteriosclerosis. We climb into the mountainous coronary terrain and look at the fascinating scenery of coronary flows and myocardial perfusion that governs cardiac contractility. Finally, we arrive at coronary bypass grafting and witness the new sequential anastomosis design for enhanced patency. This fascinating journey helps us to fully appreciate cardiology from the science, technology, engineering, and mathematics viewpoint. The book represents what can be termed as computational cardiology, and hence belongs to the emerging field of computational medicine.