Kooperativer Bibliotheksverbund

UID:

Format: XVI, 226 S.

ISBN: 978-3-8300-3016-4 , 3-8300-3016-9

Series Statement: Studien zur Rechtswissenschaft 199

Note: Zugl.: Saarbrücken, Univ., Diss., 2007

Language: German

Subjects: Law

Keywords: Unternehmenskauf ; Sachmangel ; Rechtsvergleich ; Hochschulschrift ; Hochschulschrift

URL: http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015683052&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA

URL: Inhaltsverzeichnis

URL: Cover

URL: Inhaltstext

URL: Ausführliche Beschreibung

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Format: XVI, 628 S. , Ill., graph. Darst.

Edition: First edition

ISBN: 9780128000540

Note: Includes bibliographical references and index

Language: English

Subjects: Engineering

Keywords: Pulvermetallurgie

UID:

Format: 604 Seiten

Edition: Online-Ausgabe Bei jing 2012 1 Online-Ressource Min guo tu shu shu ju ku = Early Twentieth Century Book in China, 1911-1949. tu shu ; yi qi

Original writing title: 仓库原论

Original writing person/organisation: 前马治一

Original writing publisher: 东京 : 岩松堂书店

Note: Pinyin-Umschrift und Langzeichen wurden automatisiert erstellt , System requirements: Internet browser, Acrobat reader with Adobe simplified Chinese fonts.

Language: Chinese

URL: lizenzpflichtig

URL: lizenzpflichtig

UID:

Format: 1 online resource

Edition: First edition

ISBN: 9780128009109 , 0128009101

Content: This book contains comprehensive and authoritative information for, and understanding of, all key issues of titanium powder metallurgy (Ti PM). It summarizes the past, reviews the present and discusses the future of the science and technology of Ti PM while providing the world titanium community with a unique and comprehensive book covering all aspects of titanium powder metallurgy, including: powder production, powder processing, green shape formation, consolidation, property evaluation, current industrial applications and future developments. It documents the fundamental understanding and technological developments achieved since 1937 and demonstrates why powder metallurgy now offers a cost-effective approach to the near net or net shape fabrication of titanium, titanium alloys and titanium metal matrix composites for a wide variety of industrial applications. --

Note: Includes bibliographical references and index

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-0-12-800054-0

Language: English

Subjects: Engineering

Keywords: Pulvermetallurgie

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Format: 3, 4, 234 S. , 图, 地图

Original writing title: 重新发现上海 1843-1949

Original writing person/organisation: 王千马

Original writing publisher: 杭州 : 浙江大学出版社

ISBN: 9787308122290

Note: 附参考文献 , SBB-PK Berlin

Language: Chinese

UID:

Format: 1 online resource (367 p.)

ISBN: 3-03813-884-3

Series Statement: Key Engineering Materials ; v.520

Content: The conference upon which this work is based fully achieved its objectives and turned out to be the largest international gathering dedicated solely to the topic of titanium processing via powder metallurgy. The 50 peer-reviewed papers are grouped into 8 chapters: PM titanium alloy design and processing developments; Powder Production; Effect of Impurities; Metal Injection Moulding of Titanium; Biomedical Titanium Alloys; Titanium Composites; Forging and Equal-Channel Angular Pressing of Titanium; Laser Cladding, Welding, Slip Casting and Other Processing Developments. Review from Book News In

Note: Description based upon print version of record. , Powder Metallurgy of Titanium; Preface, Acknowledgements, Sponsors and Committees; Table of Contents; Chapter 1: PM Titanium Alloy Design and Processing Developments; Current Status of Ti PM: Progress, Opportunities and Challenges; Application Status and Market Analysis of Non-Aero Titanium in China; Pathways to Optimize Performance/Cost Ratio of Powder Metallurgy Titanium - A Perspective; Design of Low Cost High Performance Powder Metallurgy Titanium Alloys: Some Basic Considerations; High Performance Titanium Alloy Compacts by Advanced Powder Processing Techniques , Rare Earth Element: Is it a Necessity for PM Ti Alloys?Microstructure Development and Alloying Elements Diffusion during Sintering of Near-β Titanium Alloys; Scandium (Sc) Behavior in High Temperature Ti Alloys; Modification of Sintered Titanium Alloys by Hot Isostatic Pressing; Preparation, Microstructure and Properties of Ti-6Al-4V Rods by Powder Compact Extrusion of Powder Mixture; Porous Ti-6Al-4V Alloy Prepared by a Press-and-Sinter Process; Comparison of Blended Elemental (BE) and Mechanical Alloyed (MA) Powder Compact Forging into Ti-6Al-4V Rocker Arms , Enhanced Sintering of Pre-Alloyed Binary TiAl Powder by a Small Addition of IronChapter 2: Powder Production; Titanium Powder from the TiROTM Process; Fundamental Reactor Design Considerations for Reducing TiCl4 Metallothermically to Produce Ti Powder; A Novel Process for Making Spherical Powders of High Nb Containing TiAl Alloys; Chapter 3: Effect of Impurities; Role of Surface Contamination in Titanium PM; Effects of Lubrication on the Powder Metallurgy Processing of Titanium; Effect of Contaminants on Sintering of Ti and Ti-6Al-4V Alloy Powders in an Argon-Back-Filled Graphite Furnace , Chapter 4: Metal Injection Moulding of TitaniumMetal Injection Moulding of Low Interstitial Titanium; Metal Injection Moulding of Titanium and Titanium-Aluminides; Design Strategy of Binder Systems for Ti Injection Moulding; A Study of Polyvinyl Butyryl Based Binder System in Titanium Based Metal Injection Moulding; Debinding Kinetics of a Water Soluble Binder System for Titanium Alloys Metal Injection Moulding; Removal of the Water Soluble Binder Components from Titanium and Titanium Alloy Powder Compacts Produced by MIM , Evaluation and Analysis of Distortion of Complex Shaped Ti-6Al-4V Compacts by Metal Injection Molding ProcessChapter 5: Biomedical Titanium Alloys; A Brief Review of Biomedical Shape Memory Alloys by Powder Metallurgy; A Newly Developed Biocompatible Titanium Alloy and its Scaffolding by Powder Metallurgy; Biomedical Ti-24Nb-4Zr-7.9Sn Alloy Fabricated by Conventional Powder Metallurgy and Spark Plasma Sintering; Fabrication of Ti14Nb4Sn Alloys for Bone Tissue Engineering Applications; Direct Metal Laser Sintering of a Ti6Al4V Mandible Implant , Selective Laser Melting of Low-Modulus Biomedical Ti-24Nb-4Zr-8Sn Alloy: Effect of Laser Point Distance , English

Additional Edition: ISBN 3-03785-468-5

Language: English

UID:

Format: 1 online resource (374 pages)

ISBN: 0-12-816264-3

Content: "Titanium for Consumer Applications is the first book to tie together the metallurgical advantages of titanium in consumer applications. The book begins with a discussion of the metallurgy and properties of titanium that is followed by six distinct sections that look at the use of titanium in consumer products, the sports industry, buildings and architecture design, arts field, aerospace, automotive, and medical applications. This book is useful for individuals involved in the manufacturing of titanium components, as well as those looking to define new applications for this versatile metal." -- Publisher's description.

Note: An Introduction to Titanium in Consumer Applications /Francis Herbert Froes and Ma Qian ; Anodized Colored Titanium Pictures / Francis Herbert Froes ; Some Other Rainbows / James Ward ; Titanium Pictures and Colored Tumblers / Takuji Horie ; The ethics of use of advanced materials such as Titanium in sports / Francis Herbert Froes ; Automobile Applications of Titanium / Tadahiko Furuta ; Sporting Good Components for Bicycles / Masahiko Ikeda ; Titanium Trumpet Mouthpieces / Mitsuo Niinomi ; The Beauty of Titanium: enhancing residential design utilizing titanium elements / Ellen Semeniuta ; Titanium-Niobium Superconducting Materials and Applications / Jianfeng Li ; Titanium Products in Everyday Life by Panzhihua Stories / Huan Yang ; Porous Titanium Materials and Applications / Krzysztof Palka ; Application examples and its applied technology for architectural material / Kazuhiro Takahashi ; Titanium Springs and Fasteners / Tingting Song and Ma Qian ; Bone Regeneration on Implants of Titanium Alloys Produced by Laser Powder Bed Fusion: a Review / Igor Yadroitsev ; Additively manufactured titanium artworks / Tingting Song and Ma Qian ; 'Titanium and titanium alloys in drones and other small flying objects / Ming Yan and Thomas Ebel ; Titanium in electronic devices / Peng Yu ; Titanium Implants / Igor Yadroitsev ; Titanium Glasses Frames / Hiroyuki Tada.

Additional Edition: ISBN 0-12-815820-4

Language: English

UID:

Format: 1 online resource (374 pages)

ISBN: 0-12-816264-3

Content: "Titanium for Consumer Applications is the first book to tie together the metallurgical advantages of titanium in consumer applications. The book begins with a discussion of the metallurgy and properties of titanium that is followed by six distinct sections that look at the use of titanium in consumer products, the sports industry, buildings and architecture design, arts field, aerospace, automotive, and medical applications. This book is useful for individuals involved in the manufacturing of titanium components, as well as those looking to define new applications for this versatile metal." -- Publisher's description.

Note: An Introduction to Titanium in Consumer Applications /Francis Herbert Froes and Ma Qian ; Anodized Colored Titanium Pictures / Francis Herbert Froes ; Some Other Rainbows / James Ward ; Titanium Pictures and Colored Tumblers / Takuji Horie ; The ethics of use of advanced materials such as Titanium in sports / Francis Herbert Froes ; Automobile Applications of Titanium / Tadahiko Furuta ; Sporting Good Components for Bicycles / Masahiko Ikeda ; Titanium Trumpet Mouthpieces / Mitsuo Niinomi ; The Beauty of Titanium: enhancing residential design utilizing titanium elements / Ellen Semeniuta ; Titanium-Niobium Superconducting Materials and Applications / Jianfeng Li ; Titanium Products in Everyday Life by Panzhihua Stories / Huan Yang ; Porous Titanium Materials and Applications / Krzysztof Palka ; Application examples and its applied technology for architectural material / Kazuhiro Takahashi ; Titanium Springs and Fasteners / Tingting Song and Ma Qian ; Bone Regeneration on Implants of Titanium Alloys Produced by Laser Powder Bed Fusion: a Review / Igor Yadroitsev ; Additively manufactured titanium artworks / Tingting Song and Ma Qian ; 'Titanium and titanium alloys in drones and other small flying objects / Ming Yan and Thomas Ebel ; Titanium in electronic devices / Peng Yu ; Titanium Implants / Igor Yadroitsev ; Titanium Glasses Frames / Hiroyuki Tada.

Additional Edition: ISBN 0-12-815820-4

Language: English

UID:

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. , 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. , 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. , 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. , 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. , 3.3.3. Microstructural characteristics and mechanical properties of SEBM-fabricated Ti-6Al-4V.

Language: English

UID:

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. , 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. , 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. , 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. , 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. , 3.3.3. Microstructural characteristics and mechanical properties of SEBM-fabricated Ti-6Al-4V.

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