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研究生: 柯良諭
Liang-Yu Ko
論文名稱: 改良式明膠支架之特性及其用於組織工程軟骨培養之研究
A study of the characteristics of modified gelatin scaffold and it's application to in vitro culture of tissue engineered cartilage
指導教授: 黃大仁
Ta-Jen Huang
口試委員:
學位類別: 碩士
Master
系所名稱: 工學院 - 化學工程學系
Department of Chemical Engineering
論文出版年: 2007
畢業學年度: 95
語文別: 中文
論文頁數: 121
中文關鍵詞: 明膠GP交聯劑軟骨組織工程孔洞大小機械測試
外文關鍵詞: Gelatin, Genipin, Cartilage, Tissue Engineering, Pore size, Mechanical test
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    • 本研究利用膠原蛋白的降解物—明膠,作為組織工程體外培養軟骨的支架,明膠屬於天然高分子,具有良好的生物相容性以及降解性等優點,且降解後的分子不容易造成生物體內的發炎或是免疫反應,這些特性使明膠適於軟骨細胞的貼附、增生以及分泌ECM,但由於明膠體的機械性質較弱,所以我們採用由茜草提煉的天然交聯劑(Genipin)來提高其機械性質,延緩它在培養液或體內的降解速率,使之更適合軟骨細胞的培養。
    由本實驗室之前的研究可知明膠相當適合做為培養軟骨的材料,故我們在此利用改變交聯反應的溫度以及調整冷凍乾燥的程序,製造出四種不同孔徑範圍的明膠支架,並植入乳鼠的軟骨細胞觀察其在不同孔徑的孔洞下的生長情形,探討孔洞的大小是否會對軟骨的增生和分化產生影響。
    實驗並針對各孔洞大小的支架進行壓力測試,觀察細胞形成組織後支架機械性質的增減。此外,利用二次冷凍乾燥將各組別的孔洞改良得更具均勻性以及聯通性,觀察培養後的細胞成長情形。未來可以引入醣胺素(GAG)、生長因子(growth-factor)等方式來培養,期望藉由這些因子增加軟骨細胞的ECM分泌、增生的數量與表型的維持,使明膠支架能對培養軟骨組織有更佳的效果。

    The research utilizes gelatin—a degradated product of collagen as scaffolds for cartilage tissue engineering in vitro. Gelatin is a kind of natural polymers, it has advantage of very good biocompatibility and biodegradation property; besides, it’s degradation molecular would hardly induce inflammation and immunization reaction inside bodies. These benefits make it suitable for the adherence, proliferation and synthesizing ECM of cartilage cells. But due to its weak mechanical properties, we use natural cross-linking reagent---genipin which was extracted from Gardeniae to make gelatin more stable, and elongate its degradation time in the medium or even in the body, to make it more suitable for chondrocyte culturing.
    From our lab’s previous study, we know that gelatin is an excellent material for cartilage culture. Hence I further altered the temperature of cross-linking reactions and adjusted the processes of lyophilization, to produce scaffolds with four ranges of different pore size.
    To investigate whether different pore sizes influence proliferation and differentiation of cartilage cells, articular chondrocytes of Wistar rats within 7 days of birth were transplanted into the scaffolds. DNA assay, GAG assay, H&E staining, Safranin-O staining and RT-PCR were used to analyze the behavior of chondrocytes.
    We found that cell’s metabolism could be affected by the configuration of the scaffold. The secretion of ECM of cells in the scaffolds with largest inner pores has the most significant amount over the other groups. We also found that cells in the smallest pores of scaffolds often show a de-differentiation form, because of lacking space in scaffolds. The phenotype of the cells will be maintained easily through the progressive increment of the pore size in scaffolds. In conclusion, cells prefer a pore size between 250μm to 500μm to produce ECM and proliferate, and the size of the space is the key factor for cell’s metabolism.
    On the other hand, the mechanical tests showed that our scaffolds have a good resilience. After 30 days culture, the scafflds’ anti-compression capability have made a great progress in the group with the largest inner pores. These facts have proven that gelatin scaffold is a very suitable material for cartilage tissue engineering.

    第一章 緒論 1 第二章 文獻回顧 4 2-1 骨關節炎(退化性關節炎) 4 2-2 軟骨組織學 7 2-2-1 軟骨組織生理、結構 7 2-2-2 軟骨的分類 10 2-2-3 關節軟骨(articular cartilage) 12 2-2-4 膠原蛋白與多醣 15 2-2-4-1 膠原蛋白(Collagen) 15 2-2-4-2 蛋白多醣(Proteoglycan) 16 2-2-4-3 醣胺素(Glycosaminglycan,GAG) 18 2-2-5 細胞表面與細胞外間質受器 20 2-3 生長因子 22 2-3-1 TGF-β簡介: 24 2-3-2 FGF簡介: 26 2-3-3 其他生長因子簡介: 27 2-3-3-1 骨形態發生蛋白(BMPs) 27 2-3-3-2 類胰島素生長因子(IGFs) 27 2-3-3-3 血小板源生長因子(PDGFs) 27 2-3-3-4 血管內皮細胞生長因子(VEGFs) 28 2-3-3-5 介白素和腫瘤壞死因子(ILs,TNFs) 28 2-4 關節軟骨缺損與病變 30 2-5 組織工程簡介 33 2-5-1 細胞(cells): 35 2-5-2 支架(scaffolds): 36 2-5-3 訊息因子(signals): 38 2-6 明膠材料簡介 39 2-6-1 明膠特性: 39 2-6-2 明膠製作法: 39 第三章 研究規劃 41 第四章 實驗方法與步驟 43 4-1 明膠支架製作 43 4-1-1 不同反應溫度下的支架製作(含二次冷凍乾燥流程) 43 4-2 支架特性分析 44 4-2-1 支架含水率分析 44 4-2-2 支架孔徑分部以及孔徑大小分析 45 4-2-3 支架結構SEM觀察 45 4-2-4 支架交聯指數分析 45 4-2-5 支架降解率分析 46 4-2-6 支架機械抗壓力測試 47 4-2-6-1支架單次壓力測試 47 4-2-6-2支架多次壓力測試 48 4-3 軟骨細胞培養 49 4-3-1 支架前處理 49 4-3-2 小鼠軟骨細胞分離與植入支架 49 4-4 定性分析 51 4-4-1 組織切片染色 51 4-4-2 RT-PCR分析 52 4-4-2-1 細胞RNA萃取 52 4-4-2-2 RNA定性以及定量 53 4-4-2-3 反轉錄聚合酶連鎖反應 54 4-4-2-4 PCR反應 54 4-5 定量分析 55 4-5-1 DNA assay 55 4-5-2 GAG assay 56 4-5-2 空支架吸光值校正 57 第五章 實驗結果與討論 58 5-1 支架結構製作法 58 5-1-1 交聯溶液的pH値影響 58 5-1-2 反應的溫度以及時間的影響 58 5-1-3 交聯程度的影響 62 5-2 支架特性分析 64 5-2-1 支架結構SEM觀察 64 5-2-2 二次冷凍乾燥結構SEM觀察 65 5-2-3 支架含水率 66 5-3 細胞培養實驗(一次冷凍乾燥支架) 68 5-3-1 不同孔洞細胞培養染色切片觀察 68 5-3-1-1 DAY9 H&E: 68 5-3-1-2 DAY9 縱切 H&E以及Safranin-O: 70 5-3-1-3 DAY 22 H&E: 71 5-3-1-4 DAY 22 safranin-O : 73 5-3-1-5 22天 H&E以及safranin-O 比較: 74 5-3-2 DNA assay 77 5-4 細胞培養實驗(二次冷凍乾燥支架) 79 5-4-1 使用二次冷凍乾燥法製造支架之優點 79 5-4-2不同孔洞細胞培養染色切片觀察(二次冷凍乾燥) 80 5-4-2-1 2 WEEKS H&E STAINING 80 5-4-2-2 2 WEEKS SAFRANIN-O STAINING 82 5-4-2-3 3 WEEKS H&E STAINING 83 5-4-2-4 3 WEEKS SAFRANIN-O STAINING 84 5-4-3 DNA ASSAY & GAG ASSAY (二次冷凍乾燥) 86 5-4-4支架RT-PCR與半定量分析 88 5-5 支架機械測試 92 5-5-1 乾燥空支架機械強度測試 92 5-5-2 濕潤空支架機械強度測試 92 5-5-3 培養細胞後的機械強度測試 97 5-5-4 機械性質結果探討 99 5-6 不均勻的支架孔洞所引發的細胞生理現象 100 5-7 軟骨細胞在支架內部的各種去分化情形 104 第六章 結論 105 第七章 未來工作 107 第八章 參考文獻 108 第九章 附錄 115 9-1 實驗儀器與設備 115 9-2 實驗藥品 117 9-3三週RT-PCR GAPDH基因 修正細節解釋 120 9-4校正曲線 121

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