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Mechanics of Biological Tissue

The mechanics of biological tissues is a multidisciplinary and rapidly expanding area of research. This book highlights some important research directions that combine mechanical sciences with exciting new developments in biology. It includes state-of-the-art articles on: Tissue growth and remodelli...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor Corporativo: SpringerLink (Online service)
Otros Autores: Holzapfel, Gerhard A. (Editor ), Ogden, Ray W. (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 2006.
Edición:1st ed. 2006.
Temas:
Acceso en línea:Texto Completo
Tabla de Contenidos:
  • Tissue Growth and Remodelling
  • Towards a Theory of Vascular Growth and Remodeling
  • Complementary Roles of Theoretical Modeling and Computer-controlled Experimentation in Vascular Growth and Remodeling
  • On the Modeling of Growth and Adaptation
  • Growth in Soft Biological Tissue and Residual Stress Development
  • Characterization and Modeling of Growth and Remodeling in Tendon and Soft Tissue Constructs
  • Modeling and Simulation of Remodeling in Soft Biological Tissues
  • Anisotropic Remodelling of Biological Tissues
  • A Mechanobiological Formulation of Bone Healing
  • Continuum Models of Growth with Emphasis on Articular Cartilage
  • Micromechanics, Cells and Matrix
  • Tensile Properties and Local Stiffness of Cells
  • Microfluid-dynamics in Three-dimensional Engineered Cell Systems
  • Nonlinear Constitutive Models for Cochlear Outer Hair Cells
  • Prediction of Changes in Cell-substrate Contact under Cyclic Substrate Deformation Using Cohesive Zone Modelling
  • Micromechanics and Macromechanics of the Tensile Deformation of Nacre
  • Arteries in Health and Disease
  • Mechanical Properties of Atherosclerotic Tissues
  • Towards a Computational Methodology for Optimizing Angioplasty Treatments with Stenting
  • Computational Modeling of Stented Arteries: Considerations for Evolving Stent Designs
  • Simulation of In-stent Restenosis for the Design of Cardiovascular Stents
  • Material Property Alterations with Early Atheroma in an Animal Model
  • Microscopic Analysis of Residual Stress and Strain in the Aortic Media Considering Anisotropy of Smooth Muscle Layer
  • Parameter Identification in Arteries Using Constraints
  • Collagen Organization and Biomechanics of the Arteries and Aneurysms of the Human Brain
  • Image-based Simulation of Blood Flow and Arterial Wall Interaction for Cerebral Aneurysms
  • Biological Tissues
  • A Framework for Soft Tissue and Musculo-skeletal Modelling: Clinical Uses and Future Challenges
  • Invariant Formulation for Dispersed Transverse Isotropy in Tissues of the Aortic Outflow Tract
  • Mathematical Modelling of Cardiac Mechanoenergetics
  • Creep and Relaxation in Ligament: Theory, Methods and Experiment
  • Viscoelastic Constitutive Law Based on the Time Scale of the Mechanical Phenomena
  • A Coupled FE Analysis of the Intervertebral Disc Based on a Multiphasic TPM Formulation
  • Is the Free Energy of Hydrogel the Sum of Elastic Energy and Ionic Energy?
  • In Vivo Experiments to Characterize the Mechanical Behavior of the Human Uterine Cervix
  • Viscoelastic Response of Vocal Fold Tissues and Scaffolds at High Frequencies
  • An Alternative Fabric-based Yield and Failure Criterion for Trabecular Bone
  • Image-based Analysis
  • Functional Micro-imaging at the Interface of Bone Mechanics and Biology
  • Strain Measurement Using Deformable Image Registration
  • Image-based Hierarchical Analysis and Design of Tissue Engineering Scaffolds.