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Bioactive collagen p的問題,透過圖書和論文來找解法和答案更準確安心。 我們找到下列推薦必買和特價產品懶人包
Bioactive collagen p的問題,我們搜遍了碩博士論文和台灣出版的書籍,推薦Boccaccini, Aldo R. (EDT)/ Ma, P. X. (EDT)寫的 Tissue Engineering Using Ceramics and Polymers 可以從中找到所需的評價。
高雄醫學大學 醫藥暨應用化學系博士班 王志光 教授所指導 Swathi Nedunchezian的 運用仿生支架進行骨軟骨修復組織工程的生物設計策略 (2021),提出Bioactive collagen p關鍵因素是什麼,來自於透明質酸、明膠、混合水凝膠、3D 生物陶瓷腳手架、軟骨組織工程。
而第二篇論文國立臺灣科技大學 材料科學與工程系 施劭儒所指導 吳亭葦的 以冷凍乾燥法製備鈦酸鋇 /ꞵ 三鈣磷酸鹽 /膠原蛋白複合支架與性質鑑定 (2021),提出因為有 齒槽骨保存術、複合支架、膠原蛋白、鈦酸鋇、β-磷酸三鈣的重點而找出了 Bioactive collagen p的解答。
Tissue Engineering Using Ceramics and Polymers
為了解決Bioactive collagen p 的問題,作者Boccaccini, Aldo R. (EDT)/ Ma, P. X. (EDT) 這樣論述:
The second edition of Tissue Engineering Using Ceramics and Polymers comprehensively reviews the latest advances in this area rapidly evolving area of biomaterials science. Part one considers the biomaterials used for tissue engineering. It introduces the properties and processing of bioactive ce
ramics and glasses, as well as polymeric biomaterials, particularly biodegradable polymer phase nanocomposites. Part two reviews the advances in techniques for processing, characterization, and modeling of materials. The topics covered range from nanoscale design in biomineralization strategies for
bone tissue engineering to microscopy techniques for characterizing cells to materials for perfusion bioreactors. Further, carrier systems and biosensors in biomedical applications are considered. Finally, part three looks at the specific types of tissue and organ regeneration, with chapters concern
ing kidney, bladder, peripheral nerve, small intestine, skeletal muscle, cartilage, liver, and myocardial tissue engineering. Important developments in collagen-based tubular constructs, bioceramic nanoparticles, and multifunctional scaffolds for tissue engineering and drug delivery are also explain
ed. Tissue Engineering Using Ceramics and Polymers is a valuable reference tool for both academic researchers and scientists involved in biomaterials or tissue engineering, including the areas of bone and soft-tissue reconstruction and repair, and organ regeneration.Second edition comprehensively ex
amines the latest advances in ceramic and polymers in tissue engineeringProvides readers with general information on polymers and ceramics and looks at the processing, characterization, and modelingReviews the latest research and advances in tissue and organ regeneration using ceramics and polymers
運用仿生支架進行骨軟骨修復組織工程的生物設計策略
為了解決Bioactive collagen p 的問題,作者Swathi Nedunchezian 這樣論述:
Acknowledgment iii摘要 vAbstract viiList of figures xiii1. Chapter One 1Introduction 11.1 Problem statement 11.1.1 Articular cartilage 31.1.2 Structure and composition of articular cartilage 31.1.3 Articular cartilage defect 51.2. Surgical techniques for cartilage and Osteochondral repair
currently in use 61.2.1 Bone marrow techniques 61.2.2 Mosaiplasty 81.2.3 Autologous chondrocyte implantation method 91.2.4 Matrix induced autologous chondrocyte implantation 111.3. Tissue engineering approaches to Osteochondral defect repair 121.3.1 Scaffold and hydrogel-based cell delivery 1
41.4. Cell source for tissue engineering purposes 161.4.1 Chondrocyte cells 161.4.2 Adult somatic stem cells 171.4.3 Bone marrow-derived stem cell (BMSCs) 181.4.4 Adipose-derived stem cells (ADSCs) 191.5 Scaffolds and hydrogels for tissue engineering 211.5.1 Natural hydrogels in cartilage tiss
ue engineering 251.6. Crosslinking of hydrogel for tissue engineering purpose 291.6.2 Silicon-dioxide Nanoparticle as crosslinkers in tissue engineering 341.6.3 Interaction of SiO2 nanoparticle with adipose-derived stem cells 361.7 Bio ceramics for Osteochondral tissue engineering and regenerati
on 371.7.1 Bio ceramics in Tissue engineering applications 371.7.2 Applications of bioceramics in Osteochondral tissue engineering 391.8 Research Objectives 421.8.1 The specific aims of this thesis are as follows: 43Chapter Two 44Characteristic and chondrogenic differentiation analysis of hybr
id hydrogels comprise of hyaluronic acid methacryloyl (HAMA), gelatin methacryloyl (GelMA), and the acrylate functionalized nano-silica crosslinker 442.1 Introduction 442.2 Materials and methods 522.2.1 Materials 522.2.2 Synthesis of HAMA hydrogel 522.2.4 Synthesis of acrylate functionalized nS
i crosslinker (AFnSi) 532.2.5 Identification of the synthesis HAMA and GelMA 542.2.6 Production of hybrid hydrogels 552.2.7 Identification of the synthesis AFnSi cross-linker 552.2.8 Fabrication of HG hybrid hydrogels 562.2.9.Swelling ratio evaluation 562.2.10 The microstructure morphology ana
lysis 572.2.11 Mechanical properties evaluation 572.2.12 In vitro degradation assay by hyaluronidase 582.2.13 Isolation and culturing of hADSCs 592.2.14 Cell viability assay 602.2.15 Chondrogenic marker gene expression 612.2.15 Quantification of DNA, sGAG deposition and collagen type Ⅱ synthes
is 622.2.16 Statistical analysis 632.3. Results and Discussion 632.3.1.Identification of the synthesis HAMA and GelMA 632.3.2 Identification of the AFnSi crosslinker 672.3.3 Swelling ratio of HG hybrid hydrogels 702.3.4 Morphological examination of HG hybrid hydrogels 722.3.5 Compressive stud
y of HG hybrid hydrogels 752.3.6.Viscoelastic property of HG hybrid hydrogel 782.3.7. Degradation study of HG hybrid hydrogels 812.3.8.Cell viability evaluation of hADSCs on HG hybrid hydrogels 822.3.8. Chondrogenic differentiation ability of HG hybrid hydrogels 852.4. Conclusion 90Chapter Thr
ee 92Multilayer-based scaffold for Osteochondral defect regeneration in the rabbit model 923.1 Introduction 923.2 Materials and methods 963.2.1 Preparation and Characterization of the 3D bioceramic scaffold by DLP method 963.2.2 Cell isolation and culture 973.2.3 Fabrication of the cell-laden
hydrogel/ 3D bioceramic scaffolds mimicking the Osteochondral tissue. 983.2.4 Surgery 983.2.5 Macroscopic Examination 993.2.6 Tissue Processing for paraffin block 993.2.7 Histological and Immunohistochemical Evaluation 1003.2.8 Masson’s trichrome stain 1013.3 Results and discussion 1023.3.1 C
haracterization of the 3D bioceramic scaffold by DLP method 1023.3.2 Fabrication of the hydrogel with hADSCs into the 3D bioceramic scaffold 1043.3.3 In-vivo studies using rabbit as an animal model 1053.3.5 Histological evaluation of neocartilage formation 1073.3.6 Masson’s trichrome staining an
alysis for neocartilage formation 1093.4. Conclusion 110Chapter four 1104.1 General discussion 1124.2 Future work 1134.2.1 Macroscopic Observation of neocartilage formation for 8 weeks 1145.Reference 115
以冷凍乾燥法製備鈦酸鋇 /ꞵ 三鈣磷酸鹽 /膠原蛋白複合支架與性質鑑定
為了解決Bioactive collagen p 的問題,作者吳亭葦 這樣論述:
針對牙周病與蛀牙問題,患者容易有齒槽骨萎縮之症狀伴隨出血等情況。本研究開發一種治療牙齒脫落後造成的齒槽骨缺損之填充材料應用於齒槽骨保存手術。本實驗設計此填充材料含有三種成分:壓電陶瓷鈦酸鋇(BT)、β-三鈣磷酸鹽(β-TCP)和膠原蛋白。 BT具有人骨的壓電特性,可自發極化產生電訊號刺激骨生長,β-TCP具有良好的生物降解性,膠原蛋白能起到凝血作用,有助於術後止血及修復,並透過冷凍乾燥法在填充材上建立孔洞,提供組織和血管的生長空間。基於上述優點,填充材預計可提高患者齒槽骨的恢復速度,縮短療程,從而減輕患者的痛苦。此研究中製備了不同比例之BT/β-TCP結合膠原蛋白的多孔複合材料。而後通過X射
線繞射(XRD)分析晶體結構,利用掃描電子顯微鏡研究微結構和形貌;藉由壓汞測孔儀測量孔隙率及孔洞大小;萬能試驗機測量其機械性質;毛細作用測試其對液體吸附速率。生物相容性測試則使用ISO10993-5之濃度標準進行細胞存活率分析(MTT assay)。結果顯示噴霧乾燥法造粒之45wt%BT/ 45wt%ꞵ-TCP/ 10wt%collagen複合材料有較佳的性質穩定性,其孔隙率為85.25%,機械強度3.19±0.41 MPa,28天之生物降解量為8.69±0.40wt%,生物相容性之細胞存活率達99.86±2.17%,並且在毛細作用測試有相對快速的液體吸附速率表現,有助於臨床應用上快速吸附並穩
定血塊的效果。