Biomechanical Study and Analysis for Cardiovascular/Skeletal Materials and Devices

© 2024 by the authors; CC BY-NC-ND license

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