Description |
1 online resource |
Contents |
Intro; Preface; Contents; Making Head and Neck Reconstruction Surgery an Engineering Process; Atlas of Acceleration-Induced Brain Deformation from Measurements In Vivo; 1 Introduction; 2 Methods; 2.1 Image Acquisition and Preprocessing; 2.2 Displacement and Strain Estimation From Tagged MRI; 2.3 Group Analysis; 3 Results and Discussion; 3.1 Individual Patterns; 3.2 Group-Based Deformation Patterns; 4 Conclusion; References |
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Reconstruction of Real-World Car-to-Pedestrian Accident Using Computational Biomechanics Model: Effects of the Choice of Boundary Conditions of the Brain on Brain Injury Risk1 Introduction; 2 Methods; 2.1 Description of the Car-to-Pedestrian Impact Accident; 2.2 Investigation of the Effects of Approach for Modelling the Brain-Skull Interface on Predicted Brain Deformations and Brain Injury Risk Due to Car-to-Pedestrian Accident; 2.2.1 Accident Reconstruction; 2.2.2 Investigation of the Effects of Approach for Modelling the Brain-Skull Interface on the Brain Injury; 3 Results |
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3.1 Accident Reconstruction3.2 Investigation of Effects of the Approach for Modelling the Brain-Skull Interface on the Brain Injury; 4 Discussions and Conclusions; References; Computational Modeling of Fluid-Structure Interaction Between Blood Flow and Mitral Valve; 1 Introduction; 2 Related Work; 3 Basics; 3.1 Mitral Valve Dynamics; 3.2 Smoothed Particle Hydrodynamics; 4 Methodology; 4.1 Embedded Deformable Model; 4.2 Casson Non-Newtonian Blood; 4.3 Blood-MV Interaction; 4.4 Mechanical Interactions Between Valve Leaflets; 5 Results; 6 Conclusion; References |
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Maximum Principal AAA Wall Stress Is Proportional to WallThickness1 Introduction; 2 Methods; 2.1 Problem Geometry; 2.2 Image Segmentation; 2.3 Wall Thickness Measurement and Specification; 2.4 Geometry Creation; 2.5 Finite Element Meshing, Model Creation and Analysis; 3 Results; 4 Discussion and Conclusions; References; An Immersed Boundary Method for Detail-Preserving Soft Tissue Simulation from Medical Images; 1 Introduction; 2 Method; 2.1 From a Continuous Problem to a Discrete Formulation; 2.2 Numerical Considerations; 3 Results; 3.1 Cylinder Compression and Bending Scenarios |
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3.2 Brain Shift Simulation4 Conclusion and Perspectives; References; A Flux-Conservative Finite Difference Scheme for the Numerical Solution of the Nonlinear Bioheat Equation; 1 Introduction; 2 Methods; 2.1 Governing Equations; 2.2 Numerical Solution of the Bioheat Equation; 2.2.1 Flux-Conservative Finite Difference Scheme; 2.2.2 Meshless Approximation Methods; 3 Results; 3.1 Code Verification; 3.2 Example 1: 2D Computation of Temperature Distribution Within Soft Tissue Using Image Data; 3.3 Example 2: 3D Computation of Temperature Distribution Within Soft Tissue; 4 Conclusions; References |
Notes |
Online resource; title from PDF title page (EBSCO, viewed May 21, 2018) |
Subject |
Medicine -- Data processing.
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Biomedical engineering -- Data processing
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Maths for scientists.
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Mechanics of solids.
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Radiology.
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Medical physics.
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Robotics.
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Biomedical engineering.
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HEALTH & FITNESS -- Holism.
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HEALTH & FITNESS -- Reference.
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MEDICAL -- Alternative Medicine.
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MEDICAL -- Atlases.
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MEDICAL -- Essays.
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MEDICAL -- Family & General Practice.
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MEDICAL -- Holistic Medicine.
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MEDICAL -- Osteopathy.
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Biomedical engineering -- Data processing
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Medicine -- Data processing
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Form |
Electronic book
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Author |
Nielsen, Poul M. F. (Poul Michael Fønss), editor.
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Wittek, Adam, editor
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Miller, Karol, editor
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Doyle, Barry, editor
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Joldes, Grand R., editor.
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Nash, Martyn P., editor
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ISBN |
9783319755892 |
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3319755897 |
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