| Description |
1 online resource (312 pages) |
| Series |
Inorganic materials series |
|
Inorganic materials series.
|
| Contents |
Intro -- Title -- Copyright -- Contents -- Chapter 1 Metallic Implants for Biomedical Applications -- 1.1 Introduction -- 1.2 General Approach to Metallic Implant Design and Manufacturing -- 1.2.1 Selection of Metals -- 1.2.1.4 Metal vs. Bone -- 1.2.2 Materials Processing Using 3D Printing -- 1.2.3 Surface Modification -- 1.3 Key Properties of Major Types of Metallic Implants -- 1.3.1 Steels -- 1.3.2 Co-Cr Alloys -- 1.3.3 Ti and Ti Alloys -- 1.3.4 Noble Metals and Alloys -- 1.3.5 Emerging Biomedical Materials -- 1.4 Corrosion of Metals In Vitro and In Vivo |
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1.4.1 Pitting and Crevice Corrosion -- 1.4.2 Stress Corrosion Cracking and Corrosion Fatigue -- 1.4.3 Hydrogen Embrittlement and Fretting Corrosion -- 1.4.4 Galvanic Corrosion and Intergranular Corrosion -- 1.4.5 Modularity as a Promoter of Corrosion -- 1.4.6 Passivation and Formation of Protective Oxides -- 1.4.7 Effect of Temperature and pH on Corrosion -- 1.5 In Vivo vs. In Vitro Studies of Implant Degradation -- 1.5.1 Dynamic vs. Static Flow Conditions -- 1.5.2 Stability of Artificial Bodily Fluids -- 1.5.3 The Chemical Feedback Loop Between Inflammation and Corrosion |
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1.5.4 Corrosion in Electrically Active Devices -- 1.5.5 Effect of Therapies on the In Vivo Corrosion of Implants -- 1.5.6 Role of Microorganisms in Corrosion and Failure -- 1.5.7 Protein-mediated Mechanisms of Material Degradation In Vivo -- 1.6 Physiological Implications of Corrosion and Wear -- 1.6.1 Interactions Between Macrophages and Metallic Wear Debris -- 1.6.2 Effect of Metallic Wear Debris on Tissue Regeneration -- 1.7 Concluding Remarks -- References -- Chapter 2 Calcium Phosphate Cements: Structure-related Properties -- 2.1 Introduction -- 2.2 Calcium Phosphate Family -- 2.3 CPCs |
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2.3.1 Setting Time -- 2.3.2 Injectability -- 2.3.3 Porosity -- 2.3.4 Bioresorbability -- 2.3.5 Anti-washout Properties -- 2.4 CaP Nanoparticles -- 2.4.1 Preparation and Morphologies -- 2.4.2 Applications -- 2.5 Setting Reactions -- 2.6 Influence of the CPC Microstructure on the Dissolution Rate -- 2.7 Influence of the Microstructure on Bioactivity -- 2.8 Structure-related Mechanical Properties -- 2.9 Summary -- References -- Chapter 3 Inorganic-Organic Hybrids: Mimicking Native Bone -- 3.1 Introduction -- 3.2 Bone as the Native Inorganic-Organic Hybrid Material |
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3.2.1 The Hierarchical Structure of Bone -- 3.2.2 Collagen Type I Protein: The Organic Material -- 3.2.3 Hydroxyapatite Mineral: The Inorganic Material -- 3.2.4 Development of Collagen Mineralisation in Native Tissues -- 3.2.5 Bone Tissue Engineering (BTE) -- 3.2.6 Hybrid Materials for BTE -- 3.3 Inorganic and Organic Materials for Bone Tissue Engineering -- 3.3.1 Inorganic Materials -- 3.3.2 Organic Materials -- 3.3.3 The Inorganic-Organic Interface -- 3.3.4 Chemical Surface Modification -- 3.4 Methods of Hybridising Inorganic-Organic Hybrids -- 3.4.1 Composites -- 3.4.2 Hybrids |
| Summary |
This book overviews the underlying chemistry behind the most common and cutting-edge inorganic materials in current use, or approaching use, in vivo |
| Notes |
3.5 Mimicking Native Bone |
| Subject |
Biomedical materials.
|
|
Biomedical materials
|
|
Chemistry, Inorganic
|
| Form |
Electronic book
|
| Author |
Spicer, Christopher
|
| ISBN |
9781788019835 |
|
1788019830 |
|
9781788019828 |
|
1788019822 |
|
