Cargando…
Metallic Biomaterials: New Directions and Technologies.
With its comprehensive coverage of recent progress in metallic biomaterials, this reference focuses on emerging materials and new biofunctions for promising applications. The text is systematically structured, with the information organized according to different material systems, and concentrates o...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Otros Autores: | , , , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
[Place of publication not identified] :
John Wiley and Sons, Inc. : Wiley-VCH,
2017.
|
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Title Page; Copyright; Contents; Preface; About the Authors; Chapter 1 Introduction; 1.1 Traditional Metallic Biomaterials; 1.2 Revolutionizing Metallic Biomaterials and Their New Biofunctions; 1.2.1 What are Revolutionizing Metallic Biomaterials?; 1.2.2 Antibacterial Function; 1.2.3 Promotion of Osteogenesis; 1.2.4 Reduction of In-stent Restenosis; 1.2.5 MRI Compatibility; 1.2.6 Radiopacity; 1.2.7 Self-Adjustment of Young's Modulus for Spinal Fixation Applications; 1.3 Technical Consideration on Alloying Design of Revolutionizing Metallic Biomaterials.
- 1.3.1 Evolution of Mechanical Properties with Implantation Time1.3.2 Biocorrosion or Biodegradation Behavior and Control on Ion Release; 1.4 Novel Process Technologies for Revolutionizing Metallic Biomaterials; 1.4.1 3D Printing; 1.4.2 Safety and Effectiveness of Biofunctions; 1.4.3 Severe Plastic Deformation; References; Chapter 2 Introduction of the Biofunctions into Traditional Metallic Biomaterials; 2.1 Antibacterial Metallic Biomaterials; 2.1.1 Antibacterial Metals; 2.1.2 Antibacterial Stainless Steels; 2.1.3 Antibacterial Ti Alloys; 2.1.4 Antibacterial Mg Alloys.
- 2.1.5 Antibacterial Bulk Metallic Glasses2.2 MRI Compatibility of Metallic Biomaterials; 2.2.1 MRI Compatibility of Traditional Metallic Biomaterials; 2.2.2 MRI-Compatible Zr Alloys; 2.2.3 MRI-Compatible Nb Alloys; 2.2.4 Other MRI-Compatible Alloys; 2.3 Radiopacity of Metallic Biomaterials; 2.3.1 Stainless Steel Stents; 2.3.2 Co-Cr Stents; 2.3.3 Nitinol Stents; 2.3.4 Ta Stents; 2.3.5 Other Metallic Stents; References; Chapter 3 Development of Mg-Based Degradable Metallic Biomaterials; 3.1 Background; 3.2 Mg-Based Alloy Design and Selection Considerations; 3.2.1 Biodegradation.
- 3.2.2 Biocompatibility3.2.3 Considerations in Mg-Based Alloy Design; 3.2.4 Methods to Improve Mechanical Property; 3.3 State of the Art of the Mg-Based Alloy Material Research; 3.3.1 Pure Mg; 3.3.2 Mg-Based Alloys with Essential Elements; 3.3.3 Mg-Based Alloys with High Strength; 3.3.4 Mg-Based Alloys with Special Biofunctions; 3.3.5 Mg-Based Alloys with Improved Corrosion Resistance; 3.3.6 Mg-Based Alloys with Bioactive Surfaces; 3.4 State of the Art of Medical Mg-Based Alloy Device Research; 3.4.1 Cardiovascular Devices; 3.4.2 Orthopedic Devices.
- 3.5 Challenges and Opportunities for Mg-Based Biomedical Materials and DevicesReferences; Chapter 4 Development of Fe-Based Degradable Metallic Biomaterials; 4.1 Background; 4.2 Pure Iron; 4.2.1 Mechanical Properties of Pure Iron; 4.2.2 Metabolism and Toxicity of Pure Iron; 4.2.3 Basic Properties of Pure Iron; 4.2.4 Degradation Behavior of Pure Iron in the Physiological Environment; 4.2.5 In Vitro Experiments of Pure Iron; 4.2.6 In Vivo Experiments of Pure Iron; 4.3 Iron Alloys; 4.4 Iron-Based Composites; 4.4.1 Compositing with Metals; 4.4.2 Compositing with Nonmetallic Materials.