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研究生:郭繼勳
研究生(外文):Paul Chi-Hsiun Kuo
論文名稱:強化鈦基合金及奧氏體不銹鋼之生物與生物力學特性以用於植體之立即承載
論文名稱(外文):Enhance the Biological and Biomechanical Properties of Titanium Based Alloys and Austenitic Stainless Steels for Implant Immediate Loading
指導教授:李婉若
學位類別:博士
校院名稱:臺北醫學大學
系所名稱:醫學科學研究所
學門:醫藥衛生學門
學類:醫學學類
論文種類:學術論文
論文出版年:2012
畢業學年度:100
語文別:英文
論文頁數:168
中文關鍵詞:鈦基植體奧氏不銹鋼立即承載
外文關鍵詞:Titanium implantAustenitic stainless steelsImmediate loading
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Acknowledgement I
Abstract IX

Chapter One: Introduction 1
1-1 Trend of Maxillofacial Treatment 1
1-2 Implant Surface and Osseointegration 2
1-3 Surface Analysis of Retrieved Human Implants 4
1-4 Surface Oxides – Experimental Studies 5
1-5 Implant Surface Functionalization 8
1-6 Implant Material Composition 11
1-7 Implant and Immediate Loading 11
1-8 Healing Time 12
1-9 One-stage, Two-stage Surgery 13
1-10 Surgical Timing 13
1-11 Immediate Placement 14
1-12 Immediate Function 15
1-13 Postloading Complications 18
1-14 Improve Implant and Implant-retained Prosthesis Biomechanical Properties 27
1-15 Aims and Strategies 28

Chapter Two: Materials and Methods 32
2-1 Previous Work 32
2-2 Preparation of Titanium Based Alloys Specimens 33
2-3 Surface Modification of the Titanium Based Alloys Using Two-step Electrochemical Functionalization 33
2-4 Evaluations of Surface Properties 35
2-5 Thermal-treated Plasma Nitriding 35

Chapter Three: Results and Discussions 38
3-1 Titanium Based Alloys Surface Microstructural Variations due to Electrochemical Functionalization 38
3-2 Surface Morphologies of the Titanium Based Alloys with Different Electrochemical Functionalizations 39
3-3 Surface Chemistry of Titanium Based Alloys with and without a Two-step Electrochemical Functionalization 39
3-4 Variations in the Crystallinity of the Cathodic Pretreated Titanium Based Alloys after Anodic Oxidation 41
3-5 Selected-area Diffraction Pattern (SADP) of Nanoparticles Formed on Titanium Based Alloys 42
3-6 Load-displacement Curves for Titanium Based Alloys with and without a Two-step Electrochemical Functionalization 42
3-7 SEM Images of the Nitride Layer After Plasma Nitriding 44
3-8 Surface Roughness as a Function of Plasma Temperature 44
3-9 Identify the Characteristic Elements on the Plasma Nitriding Stainless Steels 45
3-10 Nitrogen Depth and Nitrogen Concentration of the Plasma Nitriding Stainless Steels 46
3-11 Nitrogen Content and Friction Coefficient and Electrical Resistivity of the Plasma Nitriding Stainless Steels at Different Temperature 47
3-12 Surface Functionalization of Titanium Based Alloy Increased Biocompatibility Properties 47

Chapter Four: Conclusions 49
Chapter Five: References 52
Chapter Six: Tables Capture 58
Chapter Seven: Figures Capture 63
Chapter Eight: Appendix 76
Appendix I: Effects of Surface Functionalization on the Nanostructure and Biomechanical Properties of Binary Titanium-Niobium Alloys 76
Appendix II: The effect of the Temperature on Austenitic Stainless Steels Treated with Plasma Nitriding 81

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