Home Image-guided failure assessment of human trabecular bone – Inverse finite element modelling for characterization of elastic properties
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Image-guided failure assessment of human trabecular bone – Inverse finite element modelling for characterization of elastic properties

  • Alexander Zwahlen EMAIL logo , David Christen , Davide Ruffoni , Philipp Schneider , Werner Schmölz and Ralph Müller
Published/Copyright: September 7, 2013
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Biomedical Engineering / Biomedizinische Technik
From the journal Volume 58 Issue SI-1-Track-D

Published Online: 2013-09-07

© 2013 by Walter de Gruyter GmbH & Co.

Articles in the same Issue

  1. Biomechanical Properties of the Human Ventricular Myocardium
  2. Determination of Mechanical and Microstructural Tissue Quantities for Modeling Damage in Arterial Tissues
  3. Material Modeling of the Damage Behavior of Arterial Tissues
  4. Finite Element Analysis of Compliance of Stent-Vesselsystems
  5. The Impact of Design Modifications on the Mechanical Properties of a Polymeric Slotted Tube Coronary Stent
  6. Biomechanics of Optimum Stent Implantation Strategy Considering Vessel Wall Contact and Vessel Trauma
  7. Image-guided failure assessment of human trabecular bone – Inverse finite element modelling for characterization of elastic properties
  8. The Q-Angle and its Effect on Active Knee Joint Kinematics – a Simulation Study
  9. Evaluation of Biomechanical Models for the Planning of Total Hip Arthroplasty
  10. Posturographic Assessment of Increased Fall Risk
  11. The shape of intratidal resistance-volume and compliance-volume curves in mechanical ventilation – an animal study
  12. Dynamic Hysteresis Behaviour of Respiratory System Mechanics
  13. Outcome of 23h Bracing for Tip-toe-walking Children with Cerebral Palsy
  14. Biomechanical Characterisation of Scaffold-Free Cartilage Constructs with Hyperelastic Material Models
  15. The Analysis of Lung Mechanics of Ventilated Patients During Elective Surgical Procedure Indicated Intratidal Recruitment
  16. A Mobile Gait Analysis System for Optimization of Prosthetic Alignments
https://doi.org/10.1515/bmt-2013-4114

Articles in the same Issue

  1. Biomechanical Properties of the Human Ventricular Myocardium
  2. Determination of Mechanical and Microstructural Tissue Quantities for Modeling Damage in Arterial Tissues
  3. Material Modeling of the Damage Behavior of Arterial Tissues
  4. Finite Element Analysis of Compliance of Stent-Vesselsystems
  5. The Impact of Design Modifications on the Mechanical Properties of a Polymeric Slotted Tube Coronary Stent
  6. Biomechanics of Optimum Stent Implantation Strategy Considering Vessel Wall Contact and Vessel Trauma
  7. Image-guided failure assessment of human trabecular bone – Inverse finite element modelling for characterization of elastic properties
  8. The Q-Angle and its Effect on Active Knee Joint Kinematics – a Simulation Study
  9. Evaluation of Biomechanical Models for the Planning of Total Hip Arthroplasty
  10. Posturographic Assessment of Increased Fall Risk
  11. The shape of intratidal resistance-volume and compliance-volume curves in mechanical ventilation – an animal study
  12. Dynamic Hysteresis Behaviour of Respiratory System Mechanics
  13. Outcome of 23h Bracing for Tip-toe-walking Children with Cerebral Palsy
  14. Biomechanical Characterisation of Scaffold-Free Cartilage Constructs with Hyperelastic Material Models
  15. The Analysis of Lung Mechanics of Ventilated Patients During Elective Surgical Procedure Indicated Intratidal Recruitment
  16. A Mobile Gait Analysis System for Optimization of Prosthetic Alignments
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