UID:
edoccha_9961089618602883
Format:
1 online resource (656 pages).
ISBN:
0-12-812457-1
,
0-12-812456-3
Series Statement:
Woodhead Publishing in Materials
Note:
Front Cover -- Titanium in Medical and Dental Applications -- Copyright -- Contents -- List of contributors -- Preface -- About the editors -- Section 1: Titanium alloy properties, fabrication approaches and alloy design for biomedical use -- Chapter 1.1: Titanium for medical and dental applications-An introduction -- 1.1.1. Background -- 1.1.2. Body implants -- 1.1.3. Dental implants -- 1.1.4. Titanium surgical instruments -- 1.1.5. Titanium in wheel chairs, etc. -- 1.1.6. Specifications for titanium in medical and dental applications -- 1.1.7. Other titanium-based materials -- 1.1.8. Post script -- 1.1.9. This book -- References -- Chapter 1.2: Titanium background, alloying behavior and advanced fabrication techniques-An overview -- 1.2.1. Titanium alloys and their importance -- 1.2.2. Metallurgy of the titanium system -- 1.2.3. Advanced fabrication techniques for titanium components -- 1.2.3.1. Metal injection molding of components -- 1.2.3.2. Additive manufacturing -- 1.2.3.3. The future of MIM and AM -- 1.2.4. Conclusions -- References -- Chapter 1.3: The molecular orbital approach and its application to biomedical titanium alloy design -- 1.3.1. Introduction -- 1.3.2. Theory of alloy design -- 1.3.2.1. Alloying parameters -- 1.3.2.2. Molecular orbital calculation for nickel alloys -- 1.3.2.3. New PHPCOMP -- 1.3.3. Molecular orbital calculation and alloying parameters of titanium alloys -- 1.3.3.1. Molecular orbital calculation -- 1.3.3.2. Alloying parameters -- 1.3.4. Correlation of alloying parameters with alloy properties -- 1.3.4.1. Classification of binary phase diagrams -- 1.3.4.2. Classification of practically used alloys into α, α+β, and β-types -- 1.3.4.3. Boundary between slip and twin deformation -- 1.3.4.4. Corrosion resistance -- 1.3.5. Alloy design of titanium alloys -- 1.3.5.1. High strength β-type alloys.
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1.3.5.2. β-Type alloys for biomedical applications -- 1.3.5.3. Extension of Bo-Md diagram over the higher Bo region -- 1.3.5.4. Correlation of phase stability with alloy properties -- 1.3.5.4.1. Young's modulus -- 1.3.5.4.2. Change in β-phase stability with the addition of O, Al, Sn, and Zr -- 1.3.5.4.3. Superelasticity and shape memory effect -- 1.3.6. Conclusion -- References -- Chapter 1.4: Titanium and titanium alloys: Materials, review of processes for orthopedics and a focus on a proprietary ap ... -- 1.4.1. General processes for titanium alloys: From ore to bar material -- 1.4.2. Families of titanium and titanium alloys for orthopedics -- 1.4.2.1. Further processing of titanium alloys to near net shape -- 1.4.2.1.1. Forging -- 1.4.2.1.2. Investment casting -- 1.4.2.1.3. Additive manufacturing -- 1.4.2.1.4. Machining orthopedics -- 1.4.3. Proprietary approach to producing cannulated bars for screws and nails for trauma -- 1.4.3.1. Focus on cannulated -- 1.4.3.1.1. Minimally invasive Kirschner wire-guiding technique -- 1.4.3.1.2. Cannulated instruments and implants -- 1.4.3.1.3. Tubing versus cannulated bars -- 1.4.3.1.4. Manufacturing cannulated -- 1.4.4. Summary -- References -- Section 2: Surface biofunctionalization of titanium and titanium alloys for biomedical applications -- Chapter 2.1: Transition of surface modification of titanium for medical and dental use -- 2.1.1. Clinical demands and purpose of surface modification -- 2.1.1.1. Purpose of surface modification meeting clinical demands -- 2.1.1.2. Bone formation and bone bonding -- 2.1.1.3. Prevention of bone formation -- 2.1.1.4. Soft-tissue adhesion -- 2.1.1.5. Prevention of biofilm formation -- 2.1.1.6. Prevention of thrombus -- 2.1.1.7. Increase of wear resistance -- 2.1.1.8. Coloring -- 2.1.2. Surface of titanium -- 2.1.2.1. Passive film -- 2.1.2.2. Surface hydroxyl groups.
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2.1.2.3. Calcium phosphate formation on titanium -- 2.1.2.4. Protein adsorption matter to titanium -- 2.1.2.5. Mechanism of hard tissue compatibility in titanium -- 2.1.3. Surface modification techniques -- 2.1.3.1. Overview -- 2.1.3.2. Category of surface modification -- 2.1.3.2.1. Dry process and wet process -- 2.1.3.2.2. Surface layer -- 2.1.3.2.3. Calcium phosphate formation -- 2.1.3.2.4. Chemical bonding and anchoring -- 2.1.3.2.5. Cell adhesion -- 2.1.3.3. Electrodeposition and electrochemical techniques -- 2.1.3.4. Immobilization of biofunctional molecules -- 2.1.4. Transient of surface modification -- 2.1.5. Application to regenerative medicine -- 2.1.6. Future of surface modification -- References -- Chapter 2.2: Modern techniques of surface geometry modification for the implants based on titanium and its alloys used fo ... -- 2.2.1. Introduction -- 2.2.1.1. The effect of surface geometry on the biomedical characteristics of titanium implants -- 2.2.2. Classical methods of the surface geometry modification of titanium implants -- 2.2.2.1. Mechanical surface treatment -- 2.2.2.2. Etching -- 2.2.2.3. Anodization -- 2.2.2.4. Coating of TiO2-based materials -- 2.2.2.4.1. Physical methods of applying titanium and titanium oxide-based texturing coating for increasing implant bioact ... -- 2.2.2.4.1.1. Gas thermal spraying -- 2.2.2.4.1.2. Physical vapor deposition -- 2.2.2.5. Chemical methods of applying texturing coating based on titanium oxide to increase the bioactivity of implants -- 2.2.2.5.1. Chemical vapor deposition -- 2.2.2.5.2. The sol-gel technique -- 2.2.3. Prospective methods of geometry implant surface changes to create a two-level hierarchy of topography -- 2.2.4. The practical application of the coating with a two-level hierarchy of the surface relief in implantology -- 2.2.5. Conclusion -- References.
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Chapter 2.3: Nanobioceramic thin films: Surface modifications and cellular responses on titanium implants -- 2.3.1. Introduction -- 2.3.2. Adhesion of thin films and coatings -- 2.3.2.1. Adhesion related to mechanical theory, chemistry, electrostatic attraction, diffusion, and interfaces -- 2.3.3. Anodic oxidation (anodizing) of titanium surfaces -- 2.3.3.1. Titanium anodizing process -- 2.3.3.2. Formation mechanism of anodic oxide films -- 2.3.4. Surface coatings on titanium -- 2.3.4.1. Plasma spray coating -- 2.3.4.2. Sol-gel nanocoating -- 2.3.5. Stresses in thin films and coatings -- 2.3.6. Stress and adhesion measurement techniques -- 2.3.6.1. Shear testing and tensile pull-off -- 2.3.6.2. Scratch testing -- 2.3.6.3. Bend testing -- 2.3.6.4. Blister and bulge test -- 2.3.6.5. In situ microtensile testing -- 2.3.6.6. Instrumented nanoindentation -- 2.3.6.7. Finite element approach -- 2.3.7. Cellular responses and biological activities -- 2.3.8. Concluding remarks -- References -- Chapter 2.4: Ti-Nb-Zr system and its surface biofunctionalization for biomedical applications -- 2.4.1. Introduction -- 2.4.2. Classification of titanium alloys -- 2.4.3. Fabrication of titanium alloys -- 2.4.4. Titanium alloy types used in medicine -- 2.4.5. Elastic modulus of Ti-Nb-Zr system -- 2.4.6. Corrosion resistance of the Ti-Nb-Zr system -- 2.4.7. In vitro biological properties of the Ti-Nb-Zr system -- 2.4.8. Methods for improving the bioactivity of the Ti-Nb-Zr system -- 2.4.8.1. Hydroxyapatite -- 2.4.8.2. Peptides -- References -- Section 3: Additive manufacturing of titanium and titanium alloys for implant applications -- Chapter 3.1: Design of titanium implants for additive manufacturing -- 3.1.1. Introduction -- 3.1.2. Additive manufacture -- 3.1.2.1. Powder bed fusion -- 3.1.2.2. Selective laser melting -- 3.1.2.3. Selective electron beam melting.
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3.1.2.4. Candidate PBF materials -- 3.1.3. Manufacturability -- 3.1.3.1. Geometric resolution and fidelity -- 3.1.3.2. Melt pool solidification -- 3.1.4. Cellular structures and lattice design -- 3.1.4.1. Lattice structural response -- 3.1.4.2. Effect of geometric stress concentrations -- 3.1.5. Data management -- 3.1.6. Geometry conformance -- 3.1.7. Topology optimization -- 3.1.7.1. Topology optimization methods -- 3.1.7.2. Application to MAM implants -- 3.1.8. Just-in-time implant philosophy -- References -- Chapter 3.2: Anatomics 3D-printed titanium implants from head to heel -- 3.2.1. Anatomics-Company overview -- 3.2.2. 3D-printed titanium implants-Selected case studies -- 3.2.2.1. Calcaneus (heel) implant-Case study courtesy of Prof. Peter Choong, St. Vincent's Hospital, Melbourne, Australia -- 3.2.2.2. Sternum and ribs implant (version one)-Case study courtesy of Dr. José Aranda, Salamanca University Hospital, Sa ... -- 3.2.2.3. Sternum and ribs implant (version two)-Case study courtesy of Dr. Paul Peters, Greenslopes Private Hospital, Bri ... -- 3.2.2.4. Sternum and ribs implant (version three)-Case study courtesy of Dr. Ehab Bishay, Heartlands Hospital, Birmingham ... -- 3.2.2.5. Cervical spine posterior fusion implant-Case study courtesy of Dr. Paul DUrso, Epworth Hospital, Melbourne, Aust ... -- 3.2.2.6. Spine fusion implants-Case studies courtesy of Dr. Ralph J. Mobbs and Dr. Marc Coughlan, Prince of Wales Hospita ... -- 3.2.2.6.1. Case one -- 3.2.2.6.2. Case two -- 3.2.2.7. Pelvic replacement implant-Case study courtesy of A/Prof. Ian Woodgate, East Sydney Private Hospital, Sydney, Au ... -- 3.2.3. Conclusion -- References -- Chapter 3.3: Ti-6Al-4V orthopedic implants made by selective electron beam melting -- 3.3.1. Introduction -- 3.3.2. Feedstock material and the SEBM manufacturing process.
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3.3.3. Microstructural characteristics and mechanical properties of SEBM-fabricated Ti-6Al-4V.
Language:
English
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