Bio Implant Interface Improving Biomaterials and Tissue Reactions 1st Edition by Ellingsen, Lyngstadaas 0367395231 9780367395230
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ISBN 10: 0367395231
ISBN 13: 9780367395230
Author: J.E. Ellingsen, S.P. Lyngstadaas
Achieving good clinical outcomes with implanted biomaterials depends upon achieving optimal function, both mechanical and biological, which in turn depends upon integrating advances realized in biological science, material science, and tissue engineering. As these advances push back the frontiers of biomaterial medicine , the control and patterning
Bio Implant Interface Improving Biomaterials and Tissue Reactions 1st Table of contents:
Section I Success and Failure of Bone–Implant Attachments: An Evidence-Based Approach
1 Role of Implant Surface Properties on the Clinical Outcome of Osseointegrated Oral Implant Therapy: An Evidence-Based Approach
Contents
1.1 Introduction
1.2 Materials and Methods
1.3 Results
1.4 Discussion
1.5 Conclusions
Acknowledgments
References
Section II Can Implant Macro Design and Micro Texturing Improve Bone Response?
2 Toward an Optimized Dental Implant Design
Contents
2.1 Introduction
2.2 Wolff’S Law and Its Implications for Dental Implant Design
2.3 Determining Which Parts of an Implant should be Provided with Retention Elements
2.4 Ideal Surface Roughness from A Biomechanical Angle
2.5 Ideal Implant Thread
2.6 The Implant–Abutment Interface
2.7 Summary
References
3 Implant Surface Design for Development and Maintenance of Osseointegration
Contents
3.1 Introduction
3.2 Implant Maintenance: Avoidance of Crestal Bone Loss
3.3 Sintered Porous Surfaces: Rationales of Design and Use
3.4 Surface Modification for Enhancing Osteoconductivity
3.5 Maintenance of Osseointegration and Implant Design
3.6 Summary
References
4 Bone Response to Surface Roughness: Measurements and Results from Experimental and Clinical Studies
Contents
4.1 Introduction
4.2 Surface Roughness
References
5 From Microroughness to Resorbable Bioactive Coatings
Contents
5.1 Introduction
5.2 Materials and Methods
5.3 Discussion
References
Section III Cell and Tissue Reactions to Biomaterials
6 Improving the Bio-Implant Interface by Controlling Cell Behavior Using Surface Topography
Contents
6.1 Introduction
6.2 Strategy in Selecting Potential Experimental Systems
6.3 Cell Responses to Topography
6.4 Cell Population Density
6.5 Role of Extracellular Matrix
6.6 Cell Responses to Surfaces Produced by Industrial Processes
6.7 Cell Selection in an in Vivo Model
6.8 Conclusions
Acknowledgment
References
7 Osteoblast Response to Pure Titanium and Titanium Alloy
Contents
7.1 Introduction
7.2 Titanium Dioxide: Dental Implant or Orthopedic Interface to Bone
7.3 Proteomics as the Future
7.4 Conclusions
Acknowledgments
References
8 Biomedical Implant Surface Topography and Its Effects on Osteoblast Differentiation in Vitro
Contents
8.1 Introduction
8.2 Methods and Materials
8.3 Results and Discussion
8.4 Summary
Acknowledgments
References
9 Cellular Interactions at Commercially Pure Titanium Implants
Contents
9.1 Introduction
9.2 Cellular Diversity and Osseointegration
9.3 Understanding Biological Conditioning of the Endosseous Implant Surface
9.4 Osteoinduction is a Function of the Implant–Resident Cell Population
9.5 Early Responses to Osteoinductive Signals
9.6 Potential Specialization of Bone Formation at Implants
9.7 Summary
References
10 A Selection of Oral Implant Materials Based on Experimental Studies
Contents
10.1 Introduction
10.2 Commercially Pure Titanium
10.3 Titanium Alloys
10.4 Surface-Modified C.P. Titanium and Ti-6Al-4V
10.5 Tantalum
10.6 Niobium
10.7 Zirconium
10.8 Hafnium
10.9 Vitallium (Cobalt/Chromium Alloy)
10.10 Summary
Acknowledgments
References
11 Possibilities of Improving Implants and Regenerating Dentoalveolar Tissues by Tissue Engineering Using Stem Cells and Growth Factors
Contents
11.1 Introduction
11.2 Stem Cells and their Potential in Tissue Regeneration
11.3 Use of Bioactive Signal Molecules in Induction of Stem Cell Differentiation
11.4 Possibilities for Improving or Replacing Implants through Tissue Engineering
References
12 Critical Issues in Endosseous Peri-Implant Wound Healing
Contents
12.1 Introduction
12.2 Osteoconduction
12.3 De Novo Bone Formation
12.4 Bone Bonding
12.5 Concluding Remarks
References
Section IV Extracellular Matrix Biology and Biomineralization in Bone Formation and Implant Integration
13 Initiation and Modulation of Crystal Growth in Skeletal Tissues: Role of Extracellular Matrix
Contents
13.1 Introduction
13.2 Role of Organic Matrix
13.3 Summary
References
14 Use of a Matrix Scaffold for Tissue Engineering and Bone Regeneration
Contents
14.1 Introduction
14.2 Materials and Methods
14.3 Results
14.4 Discussion
Acknowledgments
References
15 Inducing Bone Growth Using Extracellular Matrix Proteins
Contents
15.1 Introduction
15.2 Surface Molecular Recognition
15.3 Growth Factors and Extracellular Matrix Proteins
15.4 Enamel Matrix Proteins for Bone Growth
15.5 Conclusion
References
Section V Surface Chemistry, Biochemistry, and Molecules: How do they Interact with Biological Environment?
16 How Surfaces Interact with the Biological Environment
Contents
16.1 Introduction
16.2 The Biomaterial Interface
16.3 Protein Adsorption
16.4 Blood Plasma–Surface Interactions
16.5 Immune System Recognition of Biomaterials
16.6 Cells at Interfaces
16.7 Final Remarks
References
17 Osteocapacities of Calcium Phosphate Ceramics
Contents
17.1 Introduction
17.2 Osteogenic Lineage
17.3 Cell–Substrate Adhesion
17.4 Oral Implant Materials
17.5 Osteocapacities of CP Ceramics
17.6 Sputter Deposition of Cap Coatings
17.7 Interface Physics of Sputtered Cap Coatings
17.8 In Vitro Cell Behavior of Sputtered Cap Coatings
17.9 In Vivo Bone Behavior of Sputtered Cap Coatings
17.10 Conclusion and Final Remarks
References
18 Increasing Biocompatibility by Chemical Modification of Titanium Surfaces
Contents
18.1 Introduction
18.2 Surface Modifications
References
19 Use of Molecular Assembly Techniques for Tailoring Chemical Properties of Smooth and Rough Titanium Surfaces
Contents
19.1 Introduction
19.2 Surface Modifications of Titanium by Alkane Phosphate Self-Assembled Monolayers to Control Physicochemical Properties
19.3 Molecular Assembly Systems to Control Non-Specific Protein Adsorption and Specific Interactions with Cells
19.4 Conclusions and Outlook
Acknowledgments
References
Section VI Development and Application of Scientific Data: Regulatory and Commercial Aspects
20 Development and Application of Scientific Data: Do Industry and Academia have Different Scientific Perspectives?
21 Medical Devices: Regulatory Perspectives and Aspects of Regulatory Risk Management
Contents
21.1 Regulation of Medical Devices
21.2 Definitions of Medical Devices
21.3 Classification
21.4 Regulatory Issues Concerning Medical Devices Used in Dentistry
21.5 Risk Analysis, Assessment, and Management
21.6 Information Sources
Section VII Inventive Forward Looks: Where do We Go from Here?
22 Self-Assembling and Biomimetic Biomaterials
Contents
22.1 Introduction
22.2 Tissue Engineering
22.3 Design and Synthesis of an Extracellular Matrix
22.4 Mineralization of Nanofibers
22.5 Chemically Customized Extracellular Matrices
22.6 Conclusions
Acknowledgments
References
23 The Inert–Bioactivity Conundrum
Contents
23.1 Introduction
23.2 Inertness and Bioactivity: How Materials Control Host Response
23.3 Clinical Experience with Implanted Medical Devices
23.4 Bioactive Surfaces
23.5 General Discussion and Conclusions
References
24 Enhancing the Processes of Discovery and Innovation for Optimal Host Response at Implant Surfaces
Contents
24.1 Introduction
24.2 Methods and Materials
24.3 Data and Discussion
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