Reprint

Biomechanics of Contemporary Implants and Prosthesis: Modeling, Experiments, and Clinical Application

Edited by
December 2022
228 pages
  • ISBN978-3-0365-5962-9 (Hardback)
  • ISBN978-3-0365-5961-2 (PDF)

This is a Reprint of the Special Issue Biomechanics of Contemporary Implants and Prosthesis: Modeling, Experiments, and Clinical Application that was published in

Chemistry & Materials Science
Engineering
Physical Sciences
Summary

Modern medicine is now more oriented towards patient-based treatments. Taking into account individual biological features allows for increasing the quality of the healing process. Opportunities for modern hardware and software allow not only the complex behavior of implants and prostheses to be simulated, but also take into account any peculiarities of the patient. Moreover, the development of additive manufacturing expands the opportunities for materials. Technical limits for composite materials, biomaterials, and metamaterials are decreasing. On the other hand, there is a need for more detailed analyses of biomechanics research. A deeper understanding of the technological processes of implants, and the mechanobiological interactions of implants and organisms will potentially allow us to raise the level of medical treatment. Modern trends of the biomechanics of contemporary implants and prostheses, including experimental and mathematical modeling and clinical application, are discussed in this book.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
structural design; porous constructions; additive manufacturing; CT; strength; computer simulation; finite element analysis; implant; pelvis; walking; mouthguard; occlusal contact; friction; teeth; Tresca stress; metal-on-metal; total hip arthroplasty; normal walking activity; knee joint; patello-femoral joint; kinematics; cardan sequence; euler angles; conversion; biomechanics; hip replacement; short stems; custom-made medical devices; strain shielding; finite element analysis; hemodynamics; modified Blalock–Taussig shunt; hyperelasticity; anisotropy; fluid–structure interaction; dental prosthesis; porcelain fused to metal; metal-ceramic; adhesion; profilometry; plasma-electrolyte processing; shear strength; TMJ; biomaterials; custom devices; finite element analysis; 3D models; mandibles; tooth; NCCL; contact; modeling; finite element method (FEM); biomaterials; strain; glenoid implant; implant development; finite element analysis; 3D modelling; abrasion test; glenoid defect