Bioscience and Bioengineering of Titanium Materials

2nd Edition - December 5, 2012
Author: Yoshiki Oshida
Language: English
Paperback ISBN:
9 7 8 - 0 - 4 4 4 - 6 0 2 3 6 - 7
Hardback ISBN:
9 7 8 - 0 - 4 4 4 - 6 2 6 2 5 - 7
eBook ISBN:
9 7 8 - 0 - 4 4 4 - 6 2 6 2 6 - 4

The second edition of Bioscience and Bioengineering of Titanium Materials is an essential resource for anyone researching titanium in its fundamental aspects and in medical/d… Read more

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The second edition of Bioscience and Bioengineering of Titanium Materials is an essential resource for anyone researching titanium in its fundamental aspects and in medical/dental applications. The book organizes and processes the findings from over 2,000 published articles and studies into a coherent and easily accessible volume, deftly weaving together older and newer technologies to give a clear overview. Bridging the gap between medical/dental and engineering/technology areas, the book covers material classification, fabrication and modification, as well as applications and biological reactions to titanium implants.

The author, with extensive work in academics and industry, helps medical practitioners and students answer many practical questions, including: What is titanium? What type of titanium materials should I use in this case? How can I fabricate my design using titanium? Are there any alternative materials or methods? In the second edition, macro-, micro-, and nano-texturing of titanium surfaces, tissue engineering-related materials including scaffolds, and functionally graded materials and structures are extensively included and analyzed.

Dedication

Prologue

Preface for the Second Edition

1. Introduction

References

2. Materials Classification

2.1. Introduction

2.2. General Classification

2.3. Medical/Dental Titanium Materials

References

3. Chemical and Electrochemical Reactions

3.1. Introduction

3.2. Discoloration

3.3. Corrosion in Media Containing Fluorine Ion and Bleaching Agents

3.4. Corrosion under Influences of Environmental and Mechanical Actions

3.5. Metal Ion Release and Dissolution

3.6. Galvanic Corrosion

3.7. Microbiology-Induced Corrosion

3.8. Reaction with Hydrogen

References

4. Oxidation and Oxides

4.1. Introduction

4.2. Formation of Titanium Oxides

4.3. Influences on Biological Processes

4.4. Crystal Structures of Titanium Oxides

4.5. Characterization of Oxides

4.6. Unique Applications of Titanium Oxide

4.7. Oxide Growth, Stability, and Breakdown

4.8. Reaction with Hydrogen Peroxide

4.9. Applications of Advanced Technologies

References

5. Mechanical and Tribological Behaviors

5.1. Introduction

5.2. Fatigue

5.3. Fretting

5.4. Fracture and Fracture Toughness

5.5. Biotribological Actions

5.6. Improvement for Antitribological Deterioration

References

6. Biological Reactions

6.1. Introduction

6.2. Toxicity

6.3. Cytocompatibility (Toxicity to Cells)

6.4. Allergic Reaction

6.5. Metabolism

6.6. Biocompatibility

6.7. Biomechanical Compatibility

References

7. Implant-Related Biological Reactions

7.1. Introduction

7.2. Bone Healing

7.3. Bone Grafting

7.4. Hemocompatibility

7.5. Cell Adhesion, Adsorption, Spreading, and Proliferation

7.6. Roughness and Cellular Response to Biomaterials

7.7. Cell Growth

7.8. Tissue Reaction and Bone Ingrowth

7.9. Osteointegration and Bone–Implant Interface

7.10. Some Adverse Factors for Loosening Implants

7.11. Nonmetallic Implants

References

8. Implant Application

8.1. Introduction

8.2. Intraoral Implants Versus Extraoral Implants

8.3. Clinical Reports

8.4. Surface and Interface Characterizations

8.5. Reactions in Chemical and Mechanical Environments

8.6. Reaction in Biological Environment

8.7. Surface Modification Effects

References

9. Other Applications

9.1. Introduction

9.2. Denture Bases

9.3. Crowns and Bridges, and Abutment

9.4. Clasps

9.5. Posts and Cores

9.6. Titanium Fiber and Oxide Powder as Reinforcement for Bone Cement

9.7. Sealer Material

9.8. Shape Memory Effect Dental Implant

9.9. Orthodontic Appliances

9.10. Endodontic Files and Reamers

9.11. Clamps and Staples

9.12. Stents

9.13. MRI Safety and Image Compatibility

References

10. Fabrication Technologies

10.1. Introduction

10.2. Casting

10.3. Machining

10.4. Electro-discharge Machining

10.5. CAD/CAM

10.6. Isothermal Forging

10.7. Superplastic Forming

10.8. DB and SPF/DB

10.9. Powder Metallurgy

10.10. Metal Injection Molding

10.11. Mechanical Alloying

10.12. Laser Processing

10.13. Friction Stir Welding

10.14. Soldering

10.15. Heat Treatment

10.16. Coating

10.17. Electrospinning

10.18. Electron Beam Melting

10.19. Additive Manufacturing

References

11. Surface Modifications

11.1. Introduction

11.2. Mechanical Modification

11.3. Chemical, Electrochemical, Thermal, and Physical Modifications

11.4. Coating

11.5. Collagen, Protein, and CHI Coating

11.6. Coloring

References

12. Advanced Materials, Technologies, and Processes

12.1. Introduction

12.2. Materials, Structures, and Processes

12.3. Functionally Graded Materials and Design Concept

12.4. Controlled Porosity/Foamed Structures

12.5. Near-Net Shape Forming

12.6. Nanotechnology—Materials and Structures

12.7. Hybridization and Multifunctionality

12.8. Bioengineering and Biomaterial-Integrated Implant System

References

Epilogue

Life Sciences

Physical Sciences & Engineering

Social Sciences & Humanities

Health

Bioscience and Bioengineering of Titanium Materials

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Yoshiki Oshida