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博碩士論文 etd-0431116-213616 詳細資訊
Title page for etd-0431116-213616
論文名稱 Title |
尺寸可控之介孔奈米材料: 製備、自組裝及藥物釋放之應用 Pore-Size Tunable Mesoporous Nanomaterials: Preparation, Self-Assembly and Application in Drug Delivery |
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系所名稱 Department |
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畢業學年期 Year, semester |
語文別 Language |
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學位類別 Degree |
頁數 Number of pages |
190 |
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研究生 Author |
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指導教授 Advisor |
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召集委員 Convenor |
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口試委員 Advisory Committee |
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口試日期 Date of Exam |
2016-05-26 |
繳交日期 Date of Submission |
2016-05-31 |
關鍵字 Keywords |
藥物釋放、嵌段共聚高分子、多面體聚矽氧烷、介孔洞材料、揮發導致自組裝 drug delivery, block copolymer, POSS, mesoporous silica, Evaporation Induced Self-assembly |
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統計 Statistics |
本論文已被瀏覽 5702 次,被下載 110 次 The thesis/dissertation has been browsed 5702 times, has been downloaded 110 times. |
中文摘要 |
本論文研究介孔奈米材料的孔洞尺寸調控,最後用於藥物釋放之應用上面,首先利用四氫呋喃、丙酮和二氯甲烷這三種不同極性以及不同蒸氣壓的溶劑,以揮發導致自組裝的方法結合PEO-b-PCL為模板,可用不同的溶劑來調控介孔二氧化矽的規則度、孔洞體積、孔洞大小和比表面積的大小,進而可以在不同的應用上面調整所需要的介孔洞二氧化矽。接著以商業化的三嵌段共聚物F127為模板,可以利用調控矽源(TEOS)濃度可合成高規則度的六角柱和體心立方介孔二氧化矽,合成PCL-b-PEO-b-PPO-b-PEO-b-PCL用以討論多嵌段共聚物PCL鏈段對於介孔材料的影響。為了增加孔隙,將多面體聚矽氧烷POSS改質成為可以水解聚合之材料,利用揮發導致自組裝以F127為模板,調控矽源和POSS含量去討論有機/無機矽孔洞材料的規則度、孔洞體積、孔洞大小。 另一方面,以一系列PE-b-PEO-b-PLA三嵌段共聚物,藉由開環聚合的方式調控疏水端PLA的分子量,利用揮發導致自組裝來製備多層次的介孔二氧化矽,比較多層次的面心立方插層四角柱和單一孔徑球狀的螢光藥物釋放,利用光致螢光光譜儀計算並比較結構對於螢光藥物的釋放效率和載藥量。最後利用雙模板法調控F127和PEO-b-PLA兩種嵌段共聚物模板製備一系列雙孔性介孔二氧化矽,將乘載抗癌藥物Doxorubicin比較單一大孔或者小孔以及雙孔性二氧化矽作為藥物載體,利用紫外光可見光吸收光譜儀計算放效率和釋放量。 |
Abstract |
The mesoporous silica is prepared by controlling different TEOS-to-PEO-b-PCL ratios and different solvents and reveals that the mesostructure will change by various TEOS and solvents contents. The long range ordered mesoporous silica is synthesized by F127, and the morphologies are controlled from a hexagonal cylinder structure to a bcc by varying TEOS. In addition, we synthesize the pentablock copolymer PCL-PEO-PPO-PEO-PCL and then examine the effect of its PCL segments on the morphology. We fabricated a series of mesoporous silica/organosilicate with hybrid porosity through EISA and tailor the mesostructure by varying ratio of TEOS and OV-POSS-SILY. The hierarchical mesoporous silica of with tetragonal cylindrical and fcc pores with uniform pore size is synthesized through EISA by PE-PEO-PLA templates. And then, the FITC is used as drug and load into the hierarchical materials. It has been found that the release kinetics is influenced by these hierarchical materials. Bimodal mesoporous silica is prepared by co-templating method using PEO-b-PLA and F127. The pore size distribution is bimodal can be divided between the larger pores, originating from PEO-b-PLA, and the smaller pores, originating from F127. This novel bimodal mesoporous silica is employed as a drug-carrier for doxorubicin. |
目次 Table of Contents |
Content 論文審定書 i 謝誌 ii 摘要 iii Abstract iv Content v Table Caption xi Figure Captions xiii Chapter 1 Introduction 1 1-1 Nanomaterial 1 1-2 Block copolymer 2 1-3 Porous materials 3 1-4 Evaporation-induced self-assembly (EISA) 4 1-5 Polyhedral Oligomeric Silsesquioxane (POSS) 5 1-4 Hierarchical Mesoporous Silicas 6 1-7 Reference 10 Chapter 2 Solvent Tuning Ordered Mesoporous Silicas Templated by Poly(ethylene oxide-block-ε-caprolactone) Copolymer through Evaporation-Induced Self-Assembly Mechanism 21 2-1 Background 21 2-2 Experimental 23 2-2-1 Materials 23 2-2-2 Synthesis of the mesoporous silicas 24 2-2-3 Characterization 25 2-3 Result and discussion 25 2-3-1 Synthesis of mesoporous silicas at various TEOS/PEO-b-PCL ratios with solvent of dichloromethane 25 2-3-2 Mesoporous silicas at various TEOS/PEO-b-PCL ratios in THF solvent 27 2-3-2 Mesoporous silicas at various TEOS/PEO-b-PCL ratios in acetone solvent 29 2-3-4 Effect of solvent of mesoporous silicas at TEOS/PEO-b-PCL = 5/1 31 2-4 Conclusions 35 2-5 Reference 44 Chapter 3 Mesoporous Silicas Templated by Symmetrical Multiblock Copolymers through Evaporation-Induced Self-Assembly 50 3-1 Background 50 3-2 Experimental 53 3-2-1 Materials 53 3-2-2 PCL-PEO-PPO-PEO-PCL pentablock copolymers (PCL-F127-PCL) 53 3-2-3 Mesoporous silica 54 3-2-4 Characterization 55 3-3 Result and discussion 56 3-3-1 Synthesis of mesoporous silicas at various TEOS/F127 ratios 56 3-3-2 Mesoporous silicas prepared using PCL-F127-PCL ABCBA-type pentablock copolymer 59 3-3-3 Effect of hydrophobic PCL segments in symmetrical pentablock copolymer of mesoporous silicas 62 3-4 Conclusions 65 3-5 Reference 76 Chapter 4 Hierarchical Mesoporous Silicas Incorporating Microporous Polyhedral Oligomeric Silsesquioxane (POSS) Walls 83 4-1 Background 83 4-2 Experimental 86 4-2-1 Materials 86 4-2-2 OV-POSS-SILY 87 4-2-3 Mesoporous silicas containing POSS 87 4-2-4 Characterization 88 4-3 Result and discussion 89 4-3-1 NMR Analyses of OV-POSS-SILY 89 4-3-2 Phase Behavior of Microporous POSS Walls 90 4-3-3 Nitrogen sorption isotherms of Microporous POSS Walls 93 4-4 Conclusions 95 4-5 References 102 Chapter 5 Heirarchical Mesoporous Silicas Templated by PE-b-PEO-b-PLA Triblock Copolymer for Fluorescent Drug-Delivery 106 5-1 Background 106 5-2 Experimental 108 5-2-1 Materials 108 5-2-2 Synthesis of the poly(ethylene-b-ethylene oxide-b-lactide) 108 5-2-3 Synthesis of the mesoporous silica materials 109 5-2-4 FITC load and release 109 5-2-5 Characterization 110 5-3 Results and Discussion 111 5-3-1 Mesoporous Silica Materials Templated by E13-b-EO42 Diblock Copolymer (EOA0) 111 5-3-2 Mesoporous Silica Materials Templated by E13-b-EO42-b-LA11 (EOA1) 112 5-3-3 Mesoporous Silica Materials Templated by E13-b-EO42-b-LA26 (EOA2) 113 5-3-4 Mesoporous Silica Materials Templated by E13-b-EO42-b-LA61 (EOA3) 116 5-3-5 Mesoporous Silica Materials at TEOS/Template weight ratios of 5:1 117 5-3-5 Release of FITC Molecules into Hierarchical mesoporous silica material 118 5-4 Conclusions 120 5-5 Reference 131 Chapter 6 Co-templating Synthesis of Bimodal Mesoporous Silica for Potential Drug Carrier 135 6-1 Background 135 6-2 Experimental 138 6-2-1 Materials 138 6-2-2 Synthesis of the poly(ethylene glycol-block-lactide) as the template 138 6-2-3 Synthesis of the bimodal mesoporous silicas 139 6-2-4 Adsorption and Release of Doxorubicin 140 6-2-5 Characterization 140 6-3 Results and Discussion 141 6-3-1 Characterization of Bimodal mesoporous silicas co-templated by PEO-b-PLA/F127 141 6-3-2 Bimodal mesoporous silica as drug carry deliver experiment 145 6-4 Conclusions 148 6-5 Reference 162 Resume 165 |
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