生物增材制造骨植入物

Chapter 1 Improvement of Mechanical Properties
1．1 Biodegradable Metallic Bone Implants
1．1．1 Introduction
1．1．2 Types of Biodegradable Metals
1．1．3 Biodegradability
1．1．4 Mechanical Properties
1．1．5 Biocompatibility
1．1．6 Conclusive Remarks
1．2 Refined Lamellar Eutectic in Biomedical Zn-A1-Zr Alloys for Mechanical Reinforcement
1．2．1 Introduction
1．2．2 Experimental Details
1．2．3 Results and Discussions
1．2．4 Conclusions
1．3 nMgO-incorporated PLIA Bone Scaffolds：Enhanced Crystallinity and Neutralized Acidic Products
1．3．1 Introduction
1．3．2 Materials and Methods
1．3．3 Results and Discussio
1．3．4 Conclusions

Chapter 2 Regulation of Degradation Rate
2．1 3 D Honeycomb Nanostructure-encapsulate Magnesium Alloys with Superior Corrosion Resistance and Mechanical Properties
2．1．1 Introduction
2．1．2 Materials and Methods
2．1．3 Resuhs and Discussion
2．1．4 Conclusions
2．2 Regulating Degradation Behavior by Incorporating Mesoporous Silica for Mg Bone Implants
2．2．1 Introduction
2．2．2 Materials and Methods
2．2．3 Results and Discussion
2．2．4 Conclusions
2．3 Uniform Degradation Mode and Enhanced Degradation Resistance of Mg Alloy via a Long Period Stacking Ordered Phase in the Grain Interior
2．3．1 Introduction
2．3．2 Experimental Procedures
2．3．3 Results and Discussion
2．3．4 Conclusions
2．4 Positive Feedback Effects of Mg on the Hydrolysis of Poly-L-lactic Acid（PLLA） Promoted Degradation of PLLA Scaffolds
2．4．1 Introduction
2．4．2 Materials and Methods
2．4．3 Results and Discussion
2．4．4 Conclusions

Chapter 3 Endow of Anti·bacterial Function
3．1 Antibacterial Polymer Scaffold Based on Mesoporous Bioactive Glass Loaded with in Situ Grown Silver
3．1．1 Introduction
3．1．3 Results and discussion
3．1．4 Conclusions
3．2 Montmorillonite with Unique Interlayer Space Imparted Polymer Scaffolds with Sustained Release of Ag
3．2．1 Introduction
3．2．2 Material and Methods
3．2．3 Resuhs and Discussion
3．2．4 Conclusions
3．3 Lanthanum-Containing Magnesium Alloy with Antitumor Function Based on Increased Reactive Oxygen Species
3．3．1 Introduction
3．3．2 Experimental Methods
3．3．3 Results and Discussion
3．3．4 Conclusions

Chapter 4 Promotion of Osteogenic Ability
4．1 Physical Stimulations and Their Osteogenesis-inducing Mechanisms
4．1．1 Introduction
4．1．2 The Osteogenesis-inducing Mechanisms of Physical Stimulations
4．1．3 The Effects of Physical Stimulations on Bone Cells
4．1．4 In vivo StUdies of Physical Stimulation
4．1．5 The Equipments of Physical Stimulation Systems
4．1．6 The Opportunities and Challenges of Physical Stimulations
4．2 Disperse magnetic Sources Constructed with Functionalized Fe3 04 Nanoparticles in Poly 1-1actic Acid Scaffolds
4．2．1 Introduction
4．2．2 Materials and Methods
4．2．3 Results and Discussion
4．2．4 Conclusions
References