and for incorporating the observed regional distributions of fibre and sheet orientations. A model of active tissue properties, based on isolated muscle experiments, is also introduced in order to predict transmural distributions of 3D principal strains at the end of the contraction phase of the cardiac cycle. Ter Keurs, Modelling the mechanical properties of cardiac muscle. Google Scholar Kluwer Academic Publishers 2000. Buy this book eBook 109.00 price for Mexico (gross buy eBook isbn Digitally watermarked, DRM-free Included format: PDF ebooks can be used on all reading devices Immediate eBook download after purchase Softcover 139.99 price for Mexico Buy Softcover isbn Free shipping for individuals worldwide Usually. Le Grice, Anisotropic shear properties of passive ventricular myocardium. PhD Thesis, The University of Auckland, New Zealand (1998). Examine the effect of varying the heart rate. Properly functioning mitral and aortic valves are critical to ensure normal cardiovascular performance. .
Cardiomyocyte stress/strain relates to muscle energy expenditure, which dictates oxygen and substrate utilization. Policy, table of contents (34 chapters ca2 Transients in Perfused Hearts: Fundamental Properties of the Chemical Signals Underlying Ventricular Mechanics. Yin, Ventricular wall stress.
Pages 35-44, preview, buy Chapter.95, pathology of the Cardiac Collagen Matrix: Mechanical and Functional Effects. Medicine, cardiology Angiology, buy this book eBook 109.00 price for Mexico (gross buy eBook. 71 (1) (1999) 91138.
The Biomedical Engineering Handbook. Reneman, Porous medium finite element model of the beating left ventricle. McCulloch, Stress-dependent finite growth in soft elastic tissues. Mirsky, In vivo stresses in the human left ventricular wall: Analysis accounting for the irregular 3-dimensional geometry and comparison with idealised geometry analyses. Covell, Transmural myocardial deformation in the canine left ventricle: Normal in vivo three-dimensional finite strains. Pages 3-11, preview, buy Chapter.95, mechanics of the Sarcomere, pages 13-22.