Bone Adaptation [electronic resource] : In Silico Approach / by Yoshitaka Kameo, Ken-ichi Tsubota, Taiji Adachi.
By: Kameo, Yoshitaka [author.].
Contributor(s): Tsubota, Ken-ichi [author.] | Adachi, Taiji [author.] | SpringerLink (Online service).
Material type: BookSeries: Frontiers of Biomechanics: 2Publisher: Tokyo : Springer Japan : Imprint: Springer, 2018Edition: 1st ed. 2018.Description: XIV, 209 p. 93 illus., 24 illus. in color. online resource.Content type: text Media type: computer Carrier type: online resourceISBN: 9784431565147.Subject(s): Biomedical engineering | Orthopedics | Biomathematics | Biophysics | Regenerative medicine | Computer simulation | Biomedical Engineering and Bioengineering | Orthopaedics | Mathematical and Computational Biology | Biophysics | Regenerative Medicine and Tissue Engineering | Computer ModellingAdditional physical formats: Printed edition:: No title; Printed edition:: No title; Printed edition:: No titleDDC classification: 610.28 Online resources: Click here to access onlineOverview: In Silico Approaches to Understand Bone Adaptation -- Microscopic Fluid Flow Analysis in an Osteocyte Canaliculus -- Macroscopic Fluid Flow Analysis in a Poroelastic Trabecula -- Estimation of Bone Permeability for Poroelastic Analysis -- Modeling Trabecular Bone Adaptation Induced by Flow Stimuli to Osteocytes -- Effects of Local Bending Load on Trabecular Bone Adaptation -- Cancellous Bone Adaptation Predicted by Remodeling Simulations -- Trabecular Surface Remodeling toward Uniform Local Stress State -- Spatial and Temporal Regulation of Cancellous Bone Structure by Trabecular Surface Remodeling -- Comparison of Mechanical Quantities as Bone Remodeling Stimuli -- Trabecular Surface Remodeling Simulation of Cancellous Bone Using Image-Based Voxel Finite Element Models -- Functional Adaptation of Cancellous Bone in Human Proximal Femur -- 3D Trabecular Remodeling in Human Proximal Femur: Approach to Understanding Wolff’s Law -- Trabecular Structural Changes in a Vertebral Body with a Fixation Screw.
This book focuses on the systems biomechanics of bone remodeling that provide a multiscale platform for bone adaptation, spanning the cellular, tissue, and organ levels. The mathematical model explained in each section provides concrete examples of in silico approaches for bone adaptation. It will be immensely useful for readers interested in bone morphology and metabolism and will serve as an effective bridge connecting mechanics, cellular and molecular biology, and medical sciences. These in silico approaches towards exploring the mechanisms by which the functioning of dynamic living systems is established and maintained have potential for facilitating the efforts of graduate students and young researchers pioneering new frontiers of biomechanics.
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