Surface Modification of Titanium for Biomaterial Applications
Published on 7. January 2019
366 pages
978-1-62257-281-6 (ISBN)
Description
This book starts with concepts of bone, its structure, remodeling, materials for implants and implant testing methods. Calcium phosphate ceramics and need for titanium surface modification are detailed in the initial chapters. Surface modification techniques include plasma spraying, sol-gel, biomimetic, electrochemical, laser, sputtering and ion-implantation methods. Chapters 5 to 19 deal with these modification techniques. Chapters 20-22 deal with less-common methods titanium nitride coating, protein modification, diamond like carbon coating and ultraviolet treatment. Substituting the apatite lattice with other cations like silicon, magnesium, sodium, carbon, etc is provided. The chapters involving these techniques begin with a small introduction about that technique and go on to explain the underlying principles, methodology and properties of the coats. According to the authors, the book gives a complete overview of almost all the surface modification techniques known, as applied to titanium biomaterials.
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Kyo-Han Kim | R. Narayanan | Tapash R. Rautray
Surface Modification of Titanium for Biomaterial Applications
Book
05/2010
Nova Science Publishers Inc
€368.41
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Content
- Intro
- SURFACE MODIFICATION OF TITANIUM FOR BIOMATERIAL APPLICATIONS
- SURFACE MODIFICATION OF TITANIUM FOR BIOMATERIAL APPLICATIONS
- CONTENTS
- PREFACE
- NOTATIONS AND ABBREVIATIONS
- PROLOGUE
- Chapter 1 BIOMATERIALS
- 1.1. BONE
- 1.1.1. Types of Bones:
- 1.1.2. Cells:
- 1.1.3. Matrix:
- 1.1.4. Bone Structure:
- 1.1.5. Bone Anatomy:
- 1.1.6. Bone Formation Method/Mechanism:
- 1.1.7. Bone Remodeling:
- 1.1.8. Bone Mineral:
- 1.1.9. Mechanical Properties of Bone:
- 1.2. BIOMATERIALS FOR HARD TISSUE REPAIR
- 1.2.1. Bioceramics:
- 1.2.2. Polymers:
- 1.2.3. Metals:
- 1.2.4. Composites:
- 1.3. INTERACTION BETWEEN BIOMATERIAL AND HARD LIVING TISSUE- BIOLOGICAL FACTORS
- 1.3.1. Protein Adsorption:
- 1.3.2. Bone-Cell Adhesion:
- 1.3.3. Action of Bone Marrow:
- 1.3.4. Influence of Transforming Growth Factor- Beta (TGF-?):
- 1.4. INTERACTION BETWEEN BIOMATERIAL AND HARD LIVING TISSUE - SURFACE RELATED PARAMETERS
- 1.4.1. Surface Topography:
- 1.4.2. Surface Energy:
- 1.4.3. Surface Charges:
- 1.4.4.Surface Roughness:
- 1.4.5. Surface Chemistry:
- 1.4.6. Surface Texture:
- 1.4.7. Porous Structure:
- 1.5. INTERACTION BETWEEN BIOMATERIAL AND HARD LIVING TISSUE - BIOMECHANICAL CONSIDERATIONS
- 1.6. HOST RESPONSES TO BIOMATERIALS
- 1.6.1. Inflammatory Response:
- 1.6.2. Adaptation:
- 1.6.3. Chemical And Foreign-Body Carcinogenesis:
- 1.6.4. Metal Toxicity:
- 1.7. EVALUATION OF BIOMATERIAL
- 1.8. SCOPE OF THIS BOOK
- REFERENCES:
- Chapter 2 TITANIUM SYSTEM
- 2.1. TYPES OF TITANIUM ALLOYS AND THEIR USES
- 2.2. PASSIVE OXIDE LAYER ON TITANIUM ALLOYS
- 2.3. WEAR PROPERTIES OF TITANIUM ALLOYS
- 2.4. OSSEOINTEGRATION
- 2.5. CALCIUM PHOSPHATE CERAMIC AND OSSEOINTEGRATION OF TITANIUM
- 2.6. TITANIUM AS DENTAL APPLICATIONS
- 2.7. SURFACE MODIFICATION APPROACH
- REFERENCES:
- Chapter 3 CALCIUM PHOSPHATE CERAMICS
- 3.1. TYPES OF CALCIUM PHOSPHATE
- 3.1.1. Dicalcium Phosphate Dihydrate [Ca(HPO4). 2H2O]:
- 3.1.2. Tricalcium Phosphate [Ca3(PO4)2]:
- 3.1.3. Hydroxyapatite:
- 3.1.4. Amorphous Phase:
- 3.2. RESORBING ABILITY AND SOLUBILITY OF CALCIUM PHOSPHATE COMPOUNDS
- 3.3. FOCUS OF CAP BIOMATERIALS RESEARCH
- REFERENCES:
- Chapter 4 CALCIUM PHOSPHATE COATINGS ON TITANIUM
- 4.1. DIFFERENT METHODS OF COATING CALCIUM PHOSPHATE ON TITANIUM
- 4.1. DIFFERENT METHODS OF COATING CALCIUM PHOSPHATE ON TITANIUM
- REFERENCES:
- Chapter 5 BIOMIMETIC DEPOSITION
- 5.1. IMMERSION IN SBF
- 5.1.1. Activating the Titanium Surface with Hydroxide or Oxides:
- 5.1.2. Altering the SBF Chemistry:
- 5.1.3. Coating the Titanium Surface with Cap and then Immerse it in SBF:
- 5.2. OTHER WET CHEMICAL METHODS
- 5.3. EFFECT OF SINTERING OF HA ON FURTHER BIOMIMETIC FORMATION OF HA
- REFERENCES:
- Chapter 6 THERMAL SPRAYING
- 6.1. PRINCIPLES
- 6.2. DETONATION-GUN SPRAYING
- 6.3. HIGH-VELOCITY OXY-FUEL TECHNOLOGY
- 6.4. HA/TIO2 CONJOINT SPRAYING
- REFERENCES
- Chapter 7 PLASMA SPRAYING
- 7.1. PLASMA SPRAY PROCESS
- 7.1.1. Plasma Arc Formation:
- 7.1.2. Coating Build-Up:
- 7.1.3. Microstructure of the Coating:
- 7.1.4. Lamella Morphology:
- 7.1.5. Ultrastructure of the Coating:
- 7.2. PROCESS PARAMETERS
- 7.2.1. Plasma Power Level:
- 7.2.2. Plasma Forming Gases:
- 7.2.3. Powder Particle Size:
- 7.2.4. Powder Carrier Gas:
- 7.2.5. Powder Feed Rate:
- 7.2.6. Spray Distance:
- 7.2.7. Plasma Gun Relative Movement:
- 7.3. PROPERTIES PF HA COATINGS
- 7.3.1. Coating Purity:
- 7.3.2. Coating Crystallinity:
- 7.3.3. Coating Adhesion:
- 7.3.4. Cohesive Strength:
- 7.3.5. Porosity:
- 7.3.6. Residual Stress:
- 7.3.7. Coating Thickness:
- 7.3.8. Coating Roughness:
- 7.4. APPLICATIONS
- 7.5. BOND COAT
- 7.6. RF-PLASMA TREATMENT
- 7.7. EFFECT OF POST-DEPOSITION HEAT-TREATMENT
- SUMMARY
- REFERENCES:
- Chapter 8 SOL-GEL
- 8.1. STEPS INVOLVED
- 8.1.1. Hydrolysis and Poly Condensation:
- 8.1.2. Gelation:
- 8.1.3. Ageing:
- 8.1.4 Drying:
- 8.1.5. Densification and Crystallization:
- 8.1.6. Advantages and Limitations of Sol-Gel Method:
- 8.2. PROPERTIES
- 8.3. VARIOUS SOL-GEL ROUTES
- 8.3.1. Using Calcium Nitrate:
- 8.3.2. Usage of Triethyl Phosphate:
- 8.3.3. Other Sources:
- SUMMARY
- REFERENCES:
- Chapter 9 ANODIC OXIDATION
- 9.1. USES OF ANODIC OXIDES OF TITANIUM
- 9.2. TYPES OF TITANIUM OXIDE
- 9.3. PASSIVE OXIDE LAYER ON TITANIUM AND ITS ALLOYS
- 9.3.1. Adsorption Theory:
- 9.3.2. Electrochemical Theory:
- 9.4. VARIOUS OXIDIZING MEDIA
- 9.4.1. Sulphuric Acid:
- 9.4.2. Phosphoric Acid:
- 9.4.3. Chromic Acid:
- 9.4.4. Non-Acid Electrolytes:
- 9.5. VARIOUS PARAMETERS OF OXIDE GROWTH
- 9.5.1. Oxide Formation and Growth:
- 9.5.2. Crystallization of Films:
- 9.5.3. Thickening of The Films:
- 9.5.4. Breakdown of Films:
- 9.6. CHARACTERISTICS OF OXIDE FILMS
- 9.6.1. Stability of Films:
- 9.6.2. Color of the Film:
- 9.6.3. Porosity of Films:
- 9.6.4. Heterogeneity of the Film:
- 9.6.5. Stress Generation:
- REFERENCES:
- Chapter 10 TIO2 NANOTUBES
- 10.1. ELECTROLYTE
- 10.2. EVOLUTION OF SURFACE MORPHOLOGY
- 10.3. SELF-ORDERING OF NANOTUBES
- 10.4. CRYSTALLINITY
- 10.5. HA DEPOSITION
- 10.6 IN VITRO TESTS
- REFERENCES:
- Chapter 11 MICRO-ARC OXIDATION
- 11.1. PROCESS DESCRIPTION
- 11.1.1. MAO Equipment:
- 11.1.2. Characteristics of MAO Coatings:
- 11.2. MAO AND FURTHER BIOMIMETIC HA DEPOSITION
- 11.3. HA DEPOSITION BY MAO IN COMBINATION WITH OTHER TECHNIQUES
- 11.4. HEAT-TREATMENT AIDED HA FORMATION
- 11.5. INCORPORATION OF OTHER CATIONS IN THE MICRO-ARC OXIDIZED HA
- 11.6. DIRECT SINGLE-STEP HA FORMATION
- REFERENCES:
- Chapter 12 HYDROTHERMAL
- 12.1. VARIOUS DEFINITIONS OF 'HYDROTHERMAL'
- 12.2. SOLVENTS
- 12.3. USE OF WATER AS SOLVENT
- 12.4. MINERALIZER
- 12.5. OPEN/CLOSED SYSTEMS
- 12.6.TYPES OF HYDROTHERMAL TECHNIQUES
- 12.7. GENERAL APPLICATIONS
- 12.8. TITANIUM HYDROTHERMAL TREATMENT FOR IMPROVING BIOACTIVITY
- REFERENCES:
- Chapter 13 ELECTROPHORETIC DEPOSITION
- 13.1. MECHANISM
- 13.2. ELECTROPHORESIS AT CONSTANT VOLTAGE
- 13.3. DYNAMIC VOLTAGE ELECTROPHORESIS
- 13.4. PRE-SURFACE TREATMENT OF ELECTROPHORETIC COATINGS
- 13.5. VARIATIONS OF CONVENTIONAL ELECTROPHORESIS METHOD
- REFERENCES:
- Chapter 14 CATHODIC DEPOSITION
- 14.1. MECHANISM
- 14.2. FEATURES OF CATHODIC CALCIUM PHOSPHATE COATINGS
- 14.3. NUCLEATION AND GRAIN GROWTH
- 14.4. ADVANTAGES OF USING NANO-CRYSTALLINE COATINGS
- 14.5. NANO-GRAINED CATHODIC HA COATINGS
- REFERENCES:
- Chapter 15 HOT ISOSTAIC PRESSING
- 15.1. HA GRANULE PRESSING
- 15.2. VARIATIONS OF HIP
- 15.3. HIPPING AND BONE GROWTH
- 15.4. DISADVANTAGES AND ADVANTAGES
- REFERENCES:
- Chapter 16 LASER BASED COATINGS
- 16.1. PULSED LASER DEPOSITION (PLD)
- 16.2. LASER RADIATION POWER DENSITY (LASER FLUENCE)
- 16.3. LASER OPERATIONAL FREQUENCY
- 16.4. LASER WAVELENGTH
- 16.5. REACTIVE ATMOSPHERES
- 16.6. PROCESSES
- 16.7. CONJOINT PLD-BIOMIMETIC PROCESSES
- 16.8. ADVANTAGES AND USES
- REFERENCES:
- Chapter 17 RF SPUTTERING
- 17.1. ADVANTAGES AND DISADVANTAGES
- 17.2. HA DEPOSITION
- REFERENCES:
- Chapter 18 ION IMPLANTATION
- 18.1. ACCELERATOR BASED IMPLANTATION
- 18.1.1. Accelerator Setup:
- 18.1.2. Implantation Beam Line and Chamber:
- 18.1.3. Parameters of Ion Implantation:
- 18.2. ION BEAM ASSISTED DEPOSITION
- 18.3. OTHER ION ASSISTED PROCESSES
- 18.4. SPECIFIC IONS
- 18.4.1. Ca and P Ions:
- 18.4.2. Carbon Implantation:
- 18.4.3. Oxygen Ion:
- 18.4.4. Nitrogen Ion:
- 18.4.5. Fluoride Ion:
- 18.4.6. Sodium Ion:
- 18.4.7. Argon Ion:
- 18.4.8. Silver Ion:
- 18.5. PROPERTIES OF ION BEAM FORMED CALCIUM PHOSPHATES
- REFERENCES:
- Chapter 19 CHEMICAL VAPOR DEPOSITION
- 19.1. GENERAL DESCRIPTION OF PVD AND CVD
- 19.2. COMPARISON OF THE 2 PROCESSES
- 19.3. DIAMOND FILMS
- 19.4. DIAMOND FILMS AND BIOCOMPATIBILITY
- REFERENCES:
- Chapter 20 OTHER METHODS
- 20.1. THERMAL SUBSTRATE
- 20.1.1. Practical Application:
- 20.2. ADSORPTION OF PROTEINS/GROWTH FACTORS
- 20.2.1. Adsorption of Protein:
- 20.2.2. Modification Using Growth Factors:
- 20.3. BLASTING/CHEMICAL ETCHING TECHNIQUES
- 20.3.1. Types of Blasting Techniques:
- 20.3.2. Other Novel Blasting Processes:
- 20.3.3. Practical Aspects of Blasting:
- 20.3.4. Properties of Blasted Surfaces:
- 20.3.5. Chemical Etching:
- 20.4. ULTRAVIOLET (UV) LIGHT TREATMENT
- 20.5. ELECTROCHEMICAL NANO OXIDE NETWORK
- REFERENCES:
- Chapter 21 TITANIUM NITRIDE COATING
- 21.1. APPLICATIONS OF TITANIUM NITRIDE
- 21.2. Properties of Titanium Nitride
- 21.3. TITANIUM NITRIDE AS COATINGS
- REFERENCES:
- Chapter 22 HA SUBSTITUTED WITH OTHER IONS
- 22.1. SILVER DEPOSITION
- 22.2. CARBONATED HA
- 22.3. FLUORINATED HA
- 22.4. MAGNESIUM SUBSTITUTION
- 22.5. SODIUM SUBSTITUTION
- 22.6. STRONTIUM SUBSTITUTION
- 22.7. SILICON SUBSTITUTION
- REFERENCES:
- Chapter 23 PHYSICAL AND CHEMICAL PROPERTIES OF THE COATINGS
- 23.1. STABILITY
- 23.1.1. Growth - Dissolution Mechanism:
- 23.1.2. HA Coating Loss:
- 23.1.3. Case Study:
- 23.2. SURFACE ROUGHNESS
- 23.3 ADHESION
- 23.4. COATING THICKNESS
- 23.5. POROSITY
- 23.6. WETTABILITY
- 23.7. TEXTURE OF THE COATINGS
- 23.8. PROPERTIES OF HA COATINGS USED IN DENTISTRY
- REFERENCES:
- Chapter 24 CORROSION AND WEAR OF THE COATINGS
- 24.1. Corrosion of Titanium Alloys in SBF
- 24.1.1. Corrosion of Alkali-Treated Titanium:
- 24.1.2. Corrosion of Anodically Oxidized Titanium:
- 24.1.3. Corrosion of Surface Modified Nitinol Alloy:
- 24.1.4. Corrosion of Ion-Implanted Titanium:
- 24.1.5. Corrosion of Sol-Gel Derived HA:
- 24.1.6. Corrosion of Plasma-Nitrided Titanium:
- 24.1.7. Corrosion of Laser-Treated Titanium:
- 24.2. WEAR OF TITANIUM ALLOYS
- 24.2.1. Corrosive Wear of Titanium Alloys:
- REFERENCES:
- Chapter 25 BIOLOGICAL PROPERTIES OF THE COATINGS
- 25.1. IN VITRO CELL CULTURE
- 25.1.1. Surface Features and In Vitro Behavior:
- 25.1.2. In Vitro Activity of Surface Modified Titanium:
- 25.1.3. In Vitro Activity of Ion-Implanted Titanium:
- 25.2. IN VIVO RESULTS
- 25.2.1. Surface Features and In Vivo Behavior:
- 25.2.2. In Vivo Activity of Surface Modified Titanium:
- SUMMARY:
- REFERENCES:
- Chapter 26 COMPARISON OF VARIOUS PROCESSES
- 26.1. VARIOUS METHODS
- 26.2. APPLICATIONS
- 26.3. RECENT TRENDS
- REFERENCES:
- INDEX
- Blank Page
