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研究生: 毛暄瑜
Mao, Hsuan-Yu.
論文名稱: 客製化具有動態與空間調控機械性質的白蛋白/血清水凝膠在術後抗沾黏的應用
Personalized albumin/ serum hydrogel with dynamically and spatially controllable mechanical properties for prevention of post-operative adhesion
指導教授: 陳盈潔
Chen, Ying-Chieh
陳之碩
Chen, Chi-Shuo
口試委員: 王子威
Wang, Tzu-Wei
黃琇珍
Huang, Hsiu-Chen
學位類別: 碩士
Master
系所名稱: 原子科學院 - 生醫工程與環境科學系
Department of Biomedical Engineering and Environmental Sciences
論文出版年: 2019
畢業學年度: 107
語文別: 中文
論文頁數: 70
中文關鍵詞: 白蛋白水凝膠抗沾黏
外文關鍵詞: albumin, hydrogel, anti-adhesion
相關次數: 點閱:3下載:0
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    • 術後沾黏是臨床上很嚴重的問題,不但造成病人需要二次手術來去除,倘若使病人出現慢性疼痛和女性不孕症,也會造成很大的經濟成本。沾黏是指兩個原本應該分開的組織或是器官互相連在一起,目前缺乏有效的預防及診斷方式。在臨床上最常使用的預防沾黏的方法為給予物理屏障,直接阻隔兩個傷口以防止直接碰觸,臨床上較常被使用的材料為透明質酸為基底的材料,因為此分子為天然化合物,可以在體內由酶進行分解,經由體內吸收,故可以避免需要將材料再次取出的問題。在物理屏障的使用上,出現三個問題,第一點天然分子的降解過於快速,第二點材料無法完全覆蓋不規則的損傷,第三點材料無法黏附在傷口表面上,還有一個現實面的問題為目前臨床使用的防止沾黏的材料過於昂貴。
    本研究希望可以製備出一種價格較為低廉、可依照病患傷口需求而調控降解速度、材料可以完整覆蓋且容易黏附於傷口表面,故選用體內含量最豐富的蛋白質-白蛋白,不但擁有很好的生物相容性,也可以利用抽血的方式容易取得。本研究將白蛋白修飾上用酪胺(tyramine)或是甲基丙烯酸 2-氨基乙酯鹽酸鹽(2-Aminoethyl methacrylate hydrochloride, AEMA),可利用化學交聯及光交聯的方式形成三維結構的水凝膠,可以藉由調控交聯劑的濃度或是照光時間,以調控水凝膠的機械性質,因此調控降解時間、藥物釋放的劑量,也可以製備出具圖樣化的水凝膠。
    研究結果發現以白蛋白為基底的水凝膠,在材料鑑定中,證實具備動態調控機械性質及空間化的特性;在細胞實驗中,證實製備出可選擇性貼附的表面;體內降解實驗中,證實此水凝膠在體內存留的時間比可降解的天然高分子材料具有大範圍可調控的降解時間;腹腔模型實驗中,證實此水凝膠具有預防沾黏的特性。

    Postoperative adhesion is a serious clinical problem, which not only causes the patient to need secondary surgery to remove, but also causes chronic pain and female infertility, which also causes great economic costs. Adhesion refers to two tissues or organs that should be separated from each other. There is currently no effective prevention and diagnosis method. The most commonly used method of preventing adhesion in the clinic is to give a physical barrier that directly blocks the two wounds to prevent direct contact. The material that is currently used more often is a hyaluronic acid-based material. Since this molecule is a natural compound, the problem of requiring the material to be removed again can be avoided. In the use of physical barriers, three problems arise. The first point of degradation of natural molecules is too fast, the second point of material cannot completely cover irregular damage, and the third point of material cannot adhere to the surface of the wound. There is also a real problem that the currently used anti-adhesive materials are too expensive.
    This study focus on developing a material that is relatively inexpensive and has controllable mechanical and biodegrdation properties, easily fully coverage on wounds and tissue adhesive. Therefore, the most abundant protein-albumin in the body is selected, which not only has good biocompatibility, but also can be easily obtained by means of blood drawing. In this study, albumin was modified with tyramine or 2-Aminoethyl methacrylate hydrochloride (AEMA) to form a three-dimensional hydrogel by chemical crosslinking and photocrosslinking. The concentration of crosslinked reagents and light exposure time can adjust the mechanical properties of the hydrogel, thus regulating the degradation time and the dosage of drug release and can also prepare a patterned hydrogel.
    The results showed that the albumin-based hydrogel have dynamic mechanical properties and spatialization characteristics in material identification. In cell experiments, it was confirmed that a selectively anti-adhesive surface was prepared; in vivo degradation experiments It was confirmed that the hydrogel stayed in the body for a longer period of time than other natural degradable polymer material; in the abdominal cavity model test, the hydrogel was confirmed to have the property of preventing adhesion.

    目錄 誌謝 viii 摘要 ix Abstract x 第一章 緒論 1 第二章 文獻回顧 4 2-1術後沾黏介紹 4 2-1-1沾黏機制 4 2-1-2沾黏形成判斷方法 6 2-1-3腹膜沾黏 7 2-2目前臨床治療的方式及材料 8 2-3目前學術上的研究成果 10 2-3-1 學術研究上的材料 10 2-3-2 動物模型的建立 11 2-4 白蛋白 11 2-4-1白蛋白介紹 11 2-4-2 白蛋白抗沾黏特性 13 2-4-3 白蛋白水凝膠 14 第三章 實驗流程與方法 16 3-1實驗藥品 16 3-2實驗流程 16 3-2-1實驗流程概述 16 3-2-2實驗流程圖 17 3-3 實驗步驟 18 3-3-1 血清的純化 (Serum purification ) 18 3-3-2 十二烷基硫酸鈉聚丙烯醯胺凝膠電泳(sodium dodecyl sulfate polyacrylamide gel electrophoresis, SDS-PAGE)和胺基酸分析: 18 3-3-3 白蛋白/血清前驅物的製備(albumin/ serum conjugate) 19 3-3-4 氫原子核磁共振儀( 1H NMR ) 20 3-3-5 白蛋白/血清水凝膠(albumin/ serum hydrogel )成膠方法 20 3-3-6 流變儀分析(Rheological Analysis) 21 3-3-7 血液相容性分析( Hemolysis assay ) 21 3-3-8 膨潤比 (Swelling) 22 3-3-9 藥物釋放(Drug release) 22 3-3-10 細胞存活率(Cell Viability) 23 3-3-11 細胞沾黏測試( Cell Anti-adhsion Test) 24 3-3-12 體內降解(In Vivo Degradation) 25 3-3-13 體內抗沾黏測試 (In Vivo Anti-adhesion array) 26 第四章 實驗結果 28 4-1 血清純化及蛋白質定量: 28 4-2 材料改質鑑定及定量圖4- 2 29 4-2-1 化學交聯白蛋白/血清前驅物鑑定 29 4-2-2 光交聯白蛋白/血清前驅物的材料鑑定 30 4-2-3 材料改質定量 31 4-3 血液相容性評估 33 4-4 水凝膠的動態調控的機械性質圖4- 4 34 4-4-1 化學交聯的白蛋白/血清水凝膠的成膠時間及機械性質 34 4-4-2 光交聯的白蛋白/血清水凝膠的機械性質及圖樣化應用 36 4-4-3 兩階段交聯的白蛋白/血清水凝膠的機械性質 37 4-4-4 可動態調控的機械性質在圖樣化的應用 39 4-5 水凝膠之吸水特性之評估 40 4-6 水凝膠之藥物釋放測試 42 4-7 水凝膠之Doxorubicin癌細胞測試 44 4-8 細胞實驗之存活率之評估 45 4-9 細胞實驗之抗沾黏測試 47 4-10 動物實驗之體內降解測試 49 4-11 動物實驗之腹膜抗沾黏測試 51 4-12 動物實驗之組織切片分析圖4- 12 52 4-12-1 組織切片 52 4-12-2 組織切片之統計結果 54 第五章 討論 56 5-1 白蛋白水凝膠成膠機制的差異: 56 5-2 白蛋白藥物載體的功效: 57 5-3 不同抗沾黏水凝膠在材料性質方面的差異: 57 5-4 不同抗沾黏水凝膠在腹膜抗沾黏的結果 58 第六章 結論 61 第七章 參考文獻 62

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