Osseoconductive Surface Engineering for Orthopedic Implants Biomaterials Engineering
Auteur : Goharian Amirhossein
Osseoconductive Surface Engineering for Orthopedic Implants provides a comprehensive overview of the state of the art of osseointegration based on surface-mediated engineering.
It offers a practical approach to the design and development of implant surface engineering, by reviewing and discussing the usability and efficacy of each processing technique. The reader can learn about the variety, characteristics, advantages, challenges, and optimum parameters for each process?enabling targeted selection of coatings and technologies to enhance long-term implant?bone integration.
1. General concepts of osseoconductive surface engineering2. Plasma spraying process for osseoconductive surface engineering3. Vapor deposition process for osseoconductive surface engineering4. Plasma electrolyte oxidation for osseoconductive surface engineering5. Biomimetic coating process for osseoconductive surface engineering6. Porous structuring process for osseoconductive surface engineering7. Effectiveness of osseoconductive surface engineering methods and future perspectiveGlossary for surface engineering methods and treatmentsGlossary of technical terms
- Practical and engineering notions in the field of osseoconductive surface engineering are reviewed and discussed using scientific principles and concepts.
- Engineering cases are analyzed in depth giving a thorough exploration and description of the engineering and scientific concepts for all osseoconductive surface engineering processes.
- Chapters integrate topics and are organised in such a way as to build on themes and practice.
Date de parution : 01-2021
Ouvrage de 250 p.
15x22.8 cm
Thèmes d’Osseoconductive Surface Engineering for Orthopedic Implants :
Mots-clés :
Bead sintering; Bioactive coating; Bioglass coating; Biological integration; Biomimetic coating; Biomimetic solution; Bone–implant interface; Calcium phosphate; Chemical vapor deposition; Collagen–hydroxyapatite (Col-HA) coating; Corrosion resistance layering; Electron beam melting; Hydroxyapatite; Hydroxyapatite coating; Joint prostheses; Lease engineered net shaping; Magnesium (Mg) screws; Orthopedic implants; Osseoconductive layer; Osseoconductive surface engineering; Osseoconductivity; Osseointegration; Physical vapor deposition magnetron sputtering; Plasma electrolyte oxidation; Plasma spraying; Plasma spraying process; Porous layering; Porous structuring; Selective laser melting; Solution precursor plasma spraying; Suspension plasma spraying; Tantalum coating; Tantalum porous structure; Titanium coating; Vapor deposition process