牙根分岔再生探討: 現行臨床治療策略功效評估與快速列印三維羥基磷灰石生物支架設計

Hsiang-Ling Huang; 黃湘翎

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/80480

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張博鈞(Po-Chun Chang)
dc.contributor.author	Hsiang-Ling Huang	en
dc.contributor.author	黃湘翎	zh_TW
dc.date.accessioned	2022-11-24T03:07:31Z	-
dc.date.available	2021-12-30
dc.date.available	2022-11-24T03:07:31Z	-
dc.date.copyright	2021-12-30
dc.date.issued	2021
dc.date.submitted	2021-11-16
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Reich, A. Sculean, K. Jepsen, and S. Jepsen. 2004. 'A randomized clinical trial comparing enamel matrix derivative and membrane treatment of buccal class II furcation involvement in mandibular molars. Part II: secondary outcomes', J Periodontol, 75: 1188-95. Miron, R. J., M. Dard, and M. Weinreb. 2015. 'Enamel matrix derivative, inflammation and soft tissue wound healing', J Periodontal Res, 50: 555-69. Miron, R. J., A. Sculean, D. L. Cochran, S. Froum, G. Zucchelli, C. Nemcovsky, N. Donos, S. P. Lyngstadaas, J. Deschner, M. Dard, A. Stavropoulos, Y. Zhang, L. Trombelli, A. Kasaj, Y. Shirakata, P. Cortellini, M. Tonetti, G. Rasperini, S. Jepsen, and D. D. Bosshardt. 2016. 'Twenty years of enamel matrix derivative: the past, the present and the future', J Clin Periodontol, 43: 668-83. Muschler, G. F., C. Nakamoto, and L. G. Griffith. 2004. 'Engineering principles of clinical cell-based tissue engineering', J Bone Joint Surg Am, 86: 1541-58. Nesic, D., B. M. Schaefer, Y. Sun, N. 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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/80480	-
dc.description.abstract	"研究目的在下顎大臼齒牙周分叉缺損的牙周再生手術成功率仍是牙周再生一大挑戰，本研究旨在製作客製化三維組織支架用以有效率促進齒槽骨再生。研究材料與方法本實驗第一部分是收集臺大醫院牙周病科在2017年2月到2020年12月所進行的下顎大臼齒牙根分岔處牙周再生手術的病例，牙周再生手術材料骨粉包含自體骨骨粉、異體骨骨粉及異種牛骨粉(DBBM, Deproteinized bovine bone mineral)搭配再生凝膠或牙周再生膜的應用。牙根分叉處骨缺損分為單純牙根分岔處缺損與合併牙根分岔與牙周齒槽骨周圍缺損兩大類，並比對手術前與手術後六個月的臨床根尖放射線影像上牙根分岔處，齒頸部到牙根分岔處齒槽骨線性高度的變化，以牙根分岔到新生成齒槽骨線性高度變化所占牙根分岔點到牙根分岔骨缺損的距離作為線性再生骨高度的比例，另外以牙根分岔到新生成齒槽骨線性高度變化所占患齒近心側與遠心側齒槽骨高度的中心點的比例做為校正骨再生比例。我們以齒槽骨高度的變化、骨再生比例、校正再生比例，三種評估方式作為牙周骨再生效果的評估。實驗第二部分是評估三維快速成型生物支架在實驗豬下顎骨模型貼合度，利用實驗豬模擬下顎大臼齒牙根分叉的臨床破壞，並利用錐狀電腦斷層掃描實驗豬下顎骨模型後搭配三維影像編輯軟體設計骨缺損模型後，我們利用此模型進行模擬臨床客製化牙根分岔骨支架列印，用三維光固化列印技術列印樹脂模型作為對照組，同時羥基磷灰石彈性骨墨水採用生物列印方式印出三維骨支架。將樹脂骨塊與骨支架分別放回下顎豬骨缺損後，使用微米電腦斷層掃描後，利用影像軟體檢驗此骨生物支架與實驗豬下顎骨缺損到三維骨支架外緣的線性貼合度與比對我們電腦設計的骨塊形狀與三維骨支架相比的體積差異性。結果從臨床根尖片可以看出，我們利用手術前後牙根分岔處齒槽骨再生影像的變化，作為評估牙根分岔牙周再生手術的成功指標。在單純的牙根分岔處缺損，在影像上線性再生骨高度為1.45±1.15毫米，骨再生比例為50±40%與校正骨再生比例為39±30%。三種骨粉的使用當中，使用異種牛骨粉(DBBM, Deproteinized bovine bone mineral)達64±38%的骨再生效果，相較自體骨骨粉(Autogenous bone)的16±25%與異體骨骨粉(FDBA) 52±34%有較顯著的成果。女性病患相比於男性病患有顯著更好的牙周再生的成果。在合併角狀骨缺損和牙根分岔處缺損，在影像上線性再生骨高度為1.35±1.25毫米，骨再生比例為50±34%與校正骨再生比例為38±32%。使用再生凝膠(EMD)較引導骨再生手術牙周再生膜有更顯著性的牙周再生效果。在實驗豬下顎骨實驗之中，利用電腦斷層分析掃描後的羥基磷灰石生物支架對比電腦設計生物支架線性邊緣貼合度為 82.99±21.12% 和體積密合度85.58±5.48%。結論目前臨床牙根分岔再生大約有1.4mm 或40%的再生效果。在三維列印骨支架貼合實驗中，骨生物支架相比樹脂生物支架線性邊緣貼合度為82.99% 和體積密合度85.58%。"	zh_TW
dc.description.provenance	Made available in DSpace on 2022-11-24T03:07:31Z (GMT). No. of bitstreams: 1 U0001-1910202116200200.pdf: 2257946 bytes, checksum: c9a954aa0415eb6e83d31ac5d1a66763 (MD5) Previous issue date: 2021	en
dc.description.tableofcontents	口試委員會審定書 1 誌謝 2 中文摘要 3 Abstract 5 Chapter 1: Introduction 10 1.1. Periodontitis 10 1.2. Furcation anatomy and classification in molars 13 1.3. Treatment strategies for furcation involvement 15 1.3.1 Guided tissue regeneration 18 1.3.2 Enamel matrix derivatives 20 1.4. Comparison between enamel matrix derivatives and guided tissue regeneration 21 1.5. Current concerns of regeneration strategies 22 1.6. Three-dimensional printing technology in dentistry 23 1.6.1. Digital dentistry 23 1.6.2. Common 3D printing technologies 25 1.6.3. Tissue engineering scaffold 27 1.6.4. Clinical application of 3D-printed scaffolds for periodontal regeneration 31 Chapter 2: Research Goal 32 2.1 Hypotheses 33 2.2 Specific Aims 34 Chapter 3: Materials and Methods 35 3.1 Clinical outcomes of furcation defect regeneration 35 3.1.1 Ethical approval and the selection of charts 36 3.1.2 Data stratification 38 3.1.3 Analysis of radiographs and the definition of parameters 39 3.1.4 Statistical analysis 41 3.2 Experimental furcation defects in pig jaws 42 3.2.1 Defect creation 43 3.2.2 Image-based design for furcation defect regeneration 44 3.2.3 Preparation of resin blocks 45 3.2.4 Preparation of a HA-based porous scaffold 46 3.2.5 Radiographic analysis of scaffold and bone block statistical analysis 48 Chapter 4: Results 49 4.1 Furcation defect regeneration 49 4.2 Combined furcation-angular defects 52 4.3 Fitness of 3D-printed HA-based scaffold in a pig jaw furcation defect model 54 4.3.1 Characterization of the 3D-printed scaffolds 54 4.3.2 Scaffold adaptation in the furcation defects 55 5 Chapter 5: Discussion 56 5.1 Clinical outcomes of regeneration 56 5.2 Three-dimensionally-printed HA scaffolds 62 Chapter 6: Conclusion 65 Tables and Figures 66 References 87
dc.language.iso	en
dc.subject	三維列印	zh_TW
dc.subject	牙根分岔骨缺損	zh_TW
dc.subject	組織支架	zh_TW
dc.subject	骨再生	zh_TW
dc.subject	tissue scaffold	en
dc.subject	three dimensional printing	en
dc.subject	bone regeneration	en
dc.subject	furcation defects	en
dc.title	牙根分岔再生探討: 現行臨床治療策略功效評估與快速列印三維羥基磷灰石生物支架設計	zh_TW
dc.title	Furcation Defect Regeneration: The Outcome of Current Treatment Strategies and the Development of a Rapidly Prototyped Hydroxyapatite Scaffold	en
dc.date.schoolyear	110-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	郭彥彬(Hsin-Tsai Liu),侯欣翰(Chih-Yang Tseng),王進瑋
dc.subject.keyword	牙根分岔骨缺損,組織支架,骨再生,三維列印,	zh_TW
dc.subject.keyword	furcation defects,tissue scaffold,bone regeneration,three dimensional printing,	en
dc.relation.page	93
dc.identifier.doi	10.6342/NTU202103882
dc.rights.note	同意授權(限校園內公開)
dc.date.accepted	2021-11-16
dc.contributor.author-college	醫學院	zh_TW
dc.contributor.author-dept	臨床牙醫學研究所	zh_TW
顯示於系所單位：	臨床牙醫學研究所

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