Computational Biomechanics for Medicine: Solid and fluid mechanics for the benefit of patients contributions and papers from the MICCAI Computational Biomechanics for Medicine Workshop help in conjunction with Medical Image Computing and Computer Assisted Intervention conference (MICCAI 2020) in Lima, Peru. The content is dedicated to research in the field of methods and applications of computational biomechanics to medical image analysis, image-guided surgery, surgical simulation, surgical intervention planning, disease prognosis and diagnostics, analysis of injury mechanisms, implant and prostheses design, as well as artificial organ design and medical robotics.  This book appeals to researchers, students and professionals in the field. 

Part I: Computational Biomechanics Frameworks and Models for Computer-Assisted Therapy and Understanding of Disease Mechanisms

Chapter 1. Automatic framework for patient-specific biomechanical computations of organ deformation
Chapter 2. Computer simulation of the resection induced brain shift; Preliminary results
Chapter 3. Mandibular teeth movement variations in tipping scenario: A finite element study on several patients
Chapter 4. Computational biomechanics model for analysis of cervical spinal cord deformations under whiplash-type loading.- Part II: Biomechanical tissue characterisation, determining organ geometry, and organ deformation measurements.- Chapter 5. An unsupervised learning based deformable registration network for 4D-CT: Analysis and application
Chapter 6. 3D reconstruction of patient-specific carotid artery geometry using clinical ultrasound imaging
Chapter 7. Feasibility of using Freehand Ultrasound imaging to measure anatomical features of the Ischial Tuberosity to improve the prevention of seating-related pressure injury: US-based versus EOS-based assessment
Chapter 8. Characterising the soft tissue mechanical properties of the lower limb of a below-knee amputee: a review
Chapter 9. <i>3</i>D Brain Deformation in cadaveric specimens compared to healthy volunteers under non-injurious loading conditions.