Reprint

Biomechanical Study and Analysis for Cardiovascular/Skeletal Materials and Devices

Edited by
July 2024
374 pages
  • ISBN978-3-7258-1669-9 (Hardback)
  • ISBN978-3-7258-1670-5 (PDF)

This is a Reprint of the Special Issue Biomechanical Study and Analysis for Cardiovascular/Skeletal Materials and Devices that was published in

Biology & Life Sciences
Chemistry & Materials Science
Engineering
Summary

Biomedical materials are a promising solution to overcoming tissue and organ failure in the cardiovascular and skeletal systems. In recent decades, there has been incredible progress made in regard to the repair, remodelling, and regeneration of tissues such as vasculature, heart valves, joint, cartilage, cornea, retina, etc. There is a great need for novel therapeutic options in treating numerous cardiovascular/skeletal diseases related to tissue failure. Biomechanical studies and analyses of cardiovascular/skeletal materials and devices are critical areas of examination in regard to creating solution strategies for related clinical concerns. The aim of this Reprint is to demonstrate state-of-the-art biomechanical studies and analyses of cardiovascular/skeletal materials, devices, and their applications. Its scope includes—but is not limited to—fundamental studies of related materials, structures, devices and application issues.

Format
  • Hardback
License and Copyright
© 2024 by the authors; CC BY-NC-ND license
Keywords
mineralized collagen; microstructure; physical characterization; chemical characterization; coronary angioscopy; flush conditions; CFD; two-phase flow; dextran injection; flow chamber; endothelial cells; coculture techniques; microfluidics; lab-on-a-chip; aspirin; anti-inflammation; amorphous calcium phosphate composite scaffold; dental pulp-capping material; dental pulp stem cell; bone regeneration; hydrogels; mechanical properties; polyvinyl alcohol; tannic acid; finite element updating approach; arterial material properties; in vivo; material parameters estimation; medical degradation; porous zinc; protein foaming; elasticity modulus; compressive strength; biodegradable vascular stents; continuum damage mechanics; finite element method; non-uniform degradation; Zinc-based biodegradable materials; orthopedic implant; biodegradability; mechanical property; biocompatibility; interstitial fluid (ISF); microflow; perivascular and adventitial clearance; neurovascular bundles; accompanying vein; accompanying artery; kinematic law; nitinol; polydioxanone; self-expanding occluder; braided wire occluder; finite element analysis (FEA); mechanical performance; diabetes mellitus erythrocyte; retinal vessel; fluid–structure interaction; lingering time; coronary; vulnerable plaque; coronary plaque models; multilayer vessel geometry; hemodynamic; geometric features; side holes; catheter; shear stress; thyroid; biomechanics; constitutive model; hyperelasticity; 3D printing; silicone phantom; CT scanning; aortic dissection; interlayer adhesion damage; cellular reprogramming; cell transdifferentiation; direct cellular lineage-conversion; tissue engineered vascular grafts; vascular regeneration; stem cells; vascular progenitor cells; smooth muscle cells; endothelial cells; atherosclerosis; cardiovascular disease; coronary vulnerable plaque; plaque models; fibrous cap thickness; vulnerable plaque model; plaque vulnerability prediction; bone; biomaterial; collagen; mineralization; biomechanics; bone cement; cobalt–chrome alloy; Exeter stem; periprosthetic femoral fractures; polished tapered stem; fluid–structure interaction (FSI); polymeric heart valves (PHVs); thickness; strain; stress; angioplasty; balloon dilatation catheter; finite element analysis; bench test; insertion force; balloon pleating simulation; n/a