TY - BOOK ID - 145039429 TI - Advances in Biological Tissue Biomechanics AU - Lee, Chung-Hao AU - Liao, Jun PY - 2020 PB - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - Research & information: general KW - Biology, life sciences KW - computational fluid dynamics KW - bileaflet mechanical heart valve KW - adverse hemodynamics KW - transvalvular pressure gradients KW - turbulent shear stresses KW - blood damage KW - platelet activation KW - aortic valve KW - calcification KW - elastin degradation KW - leaflet KW - curvature KW - biomarker KW - early detection KW - porcine brain KW - mechanical behavior KW - hydration effects KW - Split-Hopkinson pressure bar KW - micromechanics KW - finite element analysis KW - collagen crimp KW - elastin KW - microstructures KW - force-controlled mechanical testing KW - the tricuspid valve KW - functional tricuspid regurgitation KW - cardiovascular imaging KW - mechanical characterization KW - in-vitro experiments KW - constitutive modeling KW - geometrical modeling KW - finite element modeling KW - isogeometric analysis (IGA) KW - biaxial mechanical characterization KW - fluid-structure interactions KW - material anisotropy KW - sub-valvular components KW - soft tissue KW - liver KW - high-rate compression KW - polymeric split-Hopkinson pressure bar KW - pentagalloyl glucose KW - aneurysm KW - enzyme KW - biomechanics KW - aorta KW - biaxial mechanical testing KW - cardiac valves KW - osmotic swelling KW - parameter estimation KW - nonlinear preconditioning KW - gradient-based minimization KW - cirrus KW - myocardium KW - stiffness KW - viscoelastic property KW - anisotropy KW - fibrosis KW - the mitral valve KW - collagen fiber architecture KW - glycosaminoglycan KW - uniaxial mechanical testing KW - in-vitro flow loops KW - polarized spatial frequency domain imaging KW - tricuspid regurgitation KW - spatial alignment KW - collagen fiber reorientation KW - in vivo stress/strain quantification KW - constitutive models KW - soft tissues KW - growth and remodeling (G & R) KW - multiscale biomechanics KW - patient-specific modeling KW - computational fluid dynamics KW - bileaflet mechanical heart valve KW - adverse hemodynamics KW - transvalvular pressure gradients KW - turbulent shear stresses KW - blood damage KW - platelet activation KW - aortic valve KW - calcification KW - elastin degradation KW - leaflet KW - curvature KW - biomarker KW - early detection KW - porcine brain KW - mechanical behavior KW - hydration effects KW - Split-Hopkinson pressure bar KW - micromechanics KW - finite element analysis KW - collagen crimp KW - elastin KW - microstructures KW - force-controlled mechanical testing KW - the tricuspid valve KW - functional tricuspid regurgitation KW - cardiovascular imaging KW - mechanical characterization KW - in-vitro experiments KW - constitutive modeling KW - geometrical modeling KW - finite element modeling KW - isogeometric analysis (IGA) KW - biaxial mechanical characterization KW - fluid-structure interactions KW - material anisotropy KW - sub-valvular components KW - soft tissue KW - liver KW - high-rate compression KW - polymeric split-Hopkinson pressure bar KW - pentagalloyl glucose KW - aneurysm KW - enzyme KW - biomechanics KW - aorta KW - biaxial mechanical testing KW - cardiac valves KW - osmotic swelling KW - parameter estimation KW - nonlinear preconditioning KW - gradient-based minimization KW - cirrus KW - myocardium KW - stiffness KW - viscoelastic property KW - anisotropy KW - fibrosis KW - the mitral valve KW - collagen fiber architecture KW - glycosaminoglycan KW - uniaxial mechanical testing KW - in-vitro flow loops KW - polarized spatial frequency domain imaging KW - tricuspid regurgitation KW - spatial alignment KW - collagen fiber reorientation KW - in vivo stress/strain quantification KW - constitutive models KW - soft tissues KW - growth and remodeling (G & R) KW - multiscale biomechanics KW - patient-specific modeling UR - https://www.unicat.be/uniCat?func=search&query=sysid:145039429 AB - Advanced experimental and computational biomechanics have become essential components to better understand the physiological and pathological conditions of biological tissues in the human body. Recent advances in medical imaging modalities, image segmentation, tissue characterization experiments, and predictive computer simulations have made major contributions to transforming current therapeutic paradigms, towards the facilitation of patient-specific diagnostics and individualized surgery planning. This Special Issue of Bioengineering on Advances in Biological Tissue Biomechanics, therefore, focuses on research dealing with cutting-edge experimental and computational methodologies for biomechanical investigations of tissues in the human body system across multiple spatial and temporal scales. ER -