發展柳氮磺吡啶之固化自微乳化藥物遞送系統

張為傑; Wei-Chieh Chang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/92681

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳進庭	zh_TW
dc.contributor.advisor	Chin-Tin Chen	en
dc.contributor.author	張為傑	zh_TW
dc.contributor.author	Wei-Chieh Chang	en
dc.date.accessioned	2024-06-04T16:08:09Z	-
dc.date.available	2024-06-05	-
dc.date.copyright	2024-06-04	-
dc.date.issued	2024	-
dc.date.submitted	2024-05-28	-
dc.identifier.citation	1. Baweja, R., The theory and practlce of industrial pharmacy, 3rd ed. Journal of Pharmaceutical Sciences, 1987. 76(1): p. 90-91. 2. Verbalis, J.G., Disorders of body water homeostasis. Best Practice & Research Clinical Endocrinology & Metabolism, 2003. 17(4): p. 471-503. 3. Irvine, J., A. Afrose, and N. Islam, Formulation and delivery strategies of ibuprofen: challenges and opportunities. Drug Development and Industrial Pharmacy, 2018. 44(2): p. 173-183. 4. Gårdebjer, S., et al., Using Hansen solubility parameters to predict the dispersion of nano-particles in polymeric films. Polymer Chemistry, 2016. 7(9): p. 1756-1764. 5. Calvimontes, A., The measurement of the surface energy of solids using a laboratory drop tower. npj Microgravity, 2017. 3(1). 6. Pouton, C.W., Lipid formulations for oral administration of drugs: non-emulsifying, self-emulsifying and ‘self-microemulsifying’ drug delivery systems. European Journal of Pharmaceutical Sciences, 2000. 11: p. S93-S98. 7. Pouton, C.W., Formulation of poorly water-soluble drugs for oral administration: Physicochemical and physiological issues and the lipid formulation classification system. European Journal of Pharmaceutical Sciences, 2006. 29(3-4): p. 278-287. 8. Hsieh, C.-M., et al., Application of Design of Experiments in the Development of Self-Microemulsifying Drug Delivery Systems. Pharmaceuticals, 2023. 16(2): p. 283. 9. Vithani, K., et al., Colloidal aspects of dispersion and digestion of self-dispersing lipid-based formulations for poorly water-soluble drugs. Advanced Drug Delivery Reviews, 2019. 142: p. 16-34. 10. Benet, L.Z., Predicting Drug Disposition via Application of a Biopharmaceutics Drug Disposition Classification System. Basic & Clinical Pharmacology & Toxicology, 2010. 106(3): p. 162-167. 11. Jadhav, K., et al., Applications of Microemulsion Based Drug Delivery System. Current Drug Delivery, 2006. 3(3): p. 267-273. 12. Buya, A.B., et al., Application of Lipid-Based Nanocarriers for Antitubercular Drug Delivery: A Review. Pharmaceutics, 2021. 13(12): p. 2041. 13. St-Onge, M.-P. and P.J.H. Jones, Physiological Effects of Medium-Chain Triglycerides: Potential Agents in the Prevention of Obesity. The Journal of Nutrition, 2002. 132(3): p. 329-332. 14. Sharma, S., et al., Formulation and Characterization of Self-Microemulsifying Drug Delivery System (SMEDDS) of Sertraline Hydrochloride. Recent Patents on Nanotechnology, 2024. 18(1): p. 3-16. 15. Tian, C.-T., et al., Long chain triglyceride-lipid formulation promotes the oral absorption of the lipidic prodrugs through coincident intestinal behaviors. European Journal of Pharmaceutics and Biopharmaceutics, 2022. 176: p. 122-132. 16. Aditya, N.P., et al., Advances in nanomedicines for malaria treatment. Advances in Colloid and Interface Science, 2013. 201-202: p. 1-17. 17. Rahman, M.A., et al., Role of excipients in successful development of self-emulsifying/microemulsifying drug delivery system (SEDDS/SMEDDS). Drug Development and Industrial Pharmacy, 2013. 39(1): p. 1-19. 18. Hintzen, F., et al., In vivo evaluation of an oral self-microemulsifying drug delivery system (SMEDDS) for leuprorelin. International Journal of Pharmaceutics, 2014. 472(1-2): p. 20-26. 19. Vithani, K., et al., Inclusion of Digestible Surfactants in Solid SMEDDS Formulation Removes Lag Time and Influences the Formation of Structured Particles During Digestion. The AAPS Journal, 2017. 19(3): p. 754-764. 20. Rani, S., et al., Self-Emulsifying Oral Lipid Drug Delivery Systems: Advances and Challenges. AAPS PharmSciTech, 2019. 20(3). 21. Shah, A.V., et al., Development of self-microemulsifying drug delivery system for oral delivery of poorly water-soluble nutraceuticals. Drug Development and Industrial Pharmacy, 2018. 44(6): p. 895-901. 22. Dokania, S. and A.K. Joshi, Self-microemulsifying drug delivery system (SMEDDS) – challenges and road ahead. Drug Delivery, 2015. 22(6): p. 675-690. 23. Singh, M., et al., Polymeric Precipitation Inhibitor Assisted Supersaturable SMEDDS of Efavirenz Based on Experimental Observations and Molecular Mechanics. Current Drug Delivery, 2021. 18(4): p. 513-530. 24. Kadu, P., T. Parmar, and P. Kale, Critical Strategies for Drug Precipitation Inhibition: A Review with the Focus on Poorly Soluble Drugs. Current Drug Delivery, 2023. 20(5): p. 497-507. 25. Gurjar, R., et al., Inhibitory Effects of Commonly Used Excipients on P-Glycoprotein in Vitro. Molecular Pharmaceutics, 2018. 15(11): p. 4835-4842. 26. Angelika, S. Cohen, and J. Lippincott-Schwartz, Fatty Acid Trafficking in Starved Cells: Regulation by Lipid Droplet Lipolysis, Autophagy, and Mitochondrial Fusion Dynamics. Developmental Cell, 2015. 32(6): p. 678-692. 27. Kazi, M., et al., In vitro Methods for In vitro-In vivo Correlation (IVIVC) for Poorly Water Soluble Drugs: Lipid Based Formulation Perspective. Current Drug Delivery, 2018. 15(7): p. 918-929. 28. Fitzgerald, D.M., et al., Synthesis of Polyethylene Glycol–Poly(glycerol carbonate) Block Copolymeric Micelles as Surfactant-Free Drug Delivery Systems. ACS Macro Letters, 2023. 12(7): p. 974-979. 29. Sato, W., et al., Polyethylene glycol promotes autoxidation of cytochrome c. Biochimica et Biophysica Acta (BBA) - General Subjects, 2018. 1862(6): p. 1339-1349. 30. Bolko, K., A. Zvonar, and M. Gašperlin, Mixed lipid phase SMEDDS as an innovative approach to enhance resveratrol solubility. Drug Development and Industrial Pharmacy, 2014. 40(1): p. 102-109. 31. Liu, Y., et al., Modification and crosslinking of gelatin-based biomaterials as tissue adhesives. Colloids and Surfaces B: Biointerfaces, 2019. 174: p. 316-323. 32. Mandić, J., et al., Evaluation of solid carvedilol-loaded SMEDDS produced by the spray drying method and a study of related substances. International Journal of Pharmaceutics, 2021. 605: p. 120783. 33. Yeom, D.W., et al., Development of a solidified self-microemulsifying drug delivery system (S-SMEDDS) for atorvastatin calcium with improved dissolution and bioavailability. International Journal of Pharmaceutics, 2016. 506(1-2): p. 302-311. 34. Li, L., T. Yi, and C. Lam, Effects of Spray-Drying and Choice of Solid Carriers on Concentrations of Labrasol® and Transcutol® in Solid Self-Microemulsifying Drug Delivery Systems (SMEDDS). Molecules, 2013. 18(1): p. 545-560. 35. Sosnik, A. and K.P. Seremeta, Advantages and challenges of the spray-drying technology for the production of pure drug particles and drug-loaded polymeric carriers. Advances in Colloid and Interface Science, 2015. 223: p. 40-54. 36. Huang, D., et al., Hot melt extrusion of heat-sensitive and high melting point drug: Inhibit the recrystallization of the prepared amorphous drug during extrusion to improve the bioavailability. International Journal of Pharmaceutics, 2019. 565: p. 316-324. 37. Ordoubadi, M., et al., On the particle formation of leucine in spray drying of inhalable microparticles. International Journal of Pharmaceutics, 2021. 592: p. 120102. 38. Schmitt, J.M., J.M. Baumann, and M.M. Morgen, Predicting Spray Dried Dispersion Particle Size Via Machine Learning Regression Methods. Pharmaceutical Research, 2022. 39(12): p. 3223-3239. 39. Strojewski, D. and A. Krupa, Spray drying and nano spray drying as manufacturing methods of drug-loaded polymeric particles. Polymers in Medicine, 2022. 52(2): p. 101-111. 40. Baumann, J.M., M.S. Adam, and J.D. Wood, Engineering Advances in Spray Drying for Pharmaceuticals. Annual Review of Chemical and Biomolecular Engineering, 2021. 12(1): p. 217-240. 41. Gomez, M. and R. Vehring, Spray Drying and Particle Engineering in Dosage Form Design for Global Vaccines. Journal of Aerosol Medicine and Pulmonary Drug Delivery, 2022. 35(3): p. 121-138. 42. Yan, C., et al., Microencapsulation for Food Applications: A Review. ACS Applied Bio Materials, 2022. 5(12): p. 5497-5512. 43. Buljeta, I., et al., Polysaccharides as Carriers of Polyphenols: Comparison of Freeze-Drying and Spray-Drying as Encapsulation Techniques. Molecules, 2022. 27(16): p. 5069. 44. Oh, D.H., et al., Comparison of solid self-microemulsifying drug delivery system (solid SMEDDS) prepared with hydrophilic and hydrophobic solid carrier. International Journal of Pharmaceutics, 2011. 420(2): p. 412-418. 45. Nampi, P.P., et al., The effect of polyvinyl alcohol as a binder and stearic acid as an internal lubricant in the formation, and subsequent sintering of spray-dried alumina. Ceramics International, 2011. 37(8): p. 3445-3450. 46. Agarwal, V., et al., Dissolution and powder flow characterization of solid self-emulsified drug delivery system (SEDDS). International Journal of Pharmaceutics, 2009. 366(1-2): p. 44-52. 47. Rains, C.P., S. Noble, and D. Faulds, Sulfasalazine. Drugs, 1995. 50(1): p. 137-156. 48. Sachar, D.B., The safety of sulfasalazine: the gastroenterologists' experience. J Rheumatol Suppl, 1988. 16: p. 14-6. 49. Nurchis, P., et al., [Sulfasalazine in rheumatology]. Ann Ital Med Int, 1990. 5(3 Pt 1): p. 186-91. 50. Botta-Dukát, Z., Quartile coefficient of variation is more robust than CV for traits calculated as a ratio. Scientific Reports, 2023. 13(1). 51. Kollipara, S. and R.K. Gandhi, Pharmacokinetic aspects and in vitro–in vivo correlation potential for lipid-based formulations. Acta Pharmaceutica Sinica B, 2014. 4(5): p. 333-349. 52. Park, H., et al., Pharmaceutical Applications of Supercritical Fluid Extraction of Emulsions for Micro-/Nanoparticle Formation. Pharmaceutics, 2021. 13(11): p. 1928. 53. Zhu, Y., J. Ye, and Q. Zhang, Self-emulsifying Drug Delivery System Improve Oral Bioavailability: Role of Excipients and Physico-chemical Characterization. Pharmaceutical Nanotechnology, 2020. 8(4): p. 290-301. 54. Meng, Y., et al., Solid self-microemulsifying drug delivery system (S-SMEDDS) prepared by spray drying to improve the oral bioavailability of cinnamaldehyde (CA). Pharmaceutical Development and Technology, 2024: p. 1-11. 55. Zhang, J., et al., Effect of Lipolysis on Drug Release from Self-microemulsifying Drug Delivery Systems (SMEDDS) with Different Core/Shell Drug Location. AAPS PharmSciTech, 2014. 15(3): p. 731-740. 56. Abbasi, S., S. Ghaffari, and N. Safa, Porous Silica as Drug Carrier for Controlled Delivery of Sulfasalazine: The Effect of Alginate-N, O-Carboxymethyl Chitosan Gel Coating and Amine Functionalization. Applied Biochemistry and Biotechnology, 2023. 195(6): p. 3719-3732. 57. Vadlamudi, H.C., et al., In vitro characterization studies of self-microemulsified bosentan systems. Drug Development and Industrial Pharmacy, 2017. 43(6): p. 989-995. 58. Crapse, J., et al., Evaluating the Arrhenius equation for developmental processes. Molecular Systems Biology, 2021. 17(8). 59. Chatterjee, B., et al., Controversies with self-emulsifying drug delivery system from pharmacokinetic point of view. Drug Delivery, 2016. 23(9): p. 3639-3652. 60. Song, Y.-K., et al., Quercetin Is a Flavonoid Breast Cancer Resistance Protein Inhibitor with an Impact on the Oral Pharmacokinetics of Sulfasalazine in Rats. Pharmaceutics, 2020. 12(5): p. 397. 61. Chungi, V.S., L.W. Dittert, and L. Shargel, Pharmaceutical Research, 1989. 06(12): p. 1067-1072. 62. Suram, D., A. Narala, and K. Veerabrahma, Development, characterization, comparative pharmacokinetic and pharmacodynamic studies of iloperidone solid SMEDDS and liquisolid compact. Drug Development and Industrial Pharmacy, 2020. 46(4): p. 587-596. 63. Sun, M., et al., Intestinal absorption and intestinal lymphatic transport of sirolimus from self-microemulsifying drug delivery systems assessed using the single-pass intestinal perfusion (SPIP) technique and a chylomicron flow blocking approach: Linear correlation with o. European Journal of Pharmaceutical Sciences, 2011. 43(3): p. 132-140. 64. Shah, R.B., M.A. Tawakkul, and M.A. Khan, Comparative Evaluation of Flow for Pharmaceutical Powders and Granules. AAPS PharmSciTech, 2008. 9(1): p. 250-258.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/92681	-
dc.description.abstract	自微乳化藥物遞送系統（Self-microemulsifying drug delivery system, SMEDDS）是目前用來提高難溶解口服藥物生體可用率（Bioavailability）的一種方法。這種藥物載體是由油 (oil)、介面活性劑 (surfactant)和共溶劑 (cosolvent)所組成，在特定比例下，這三種成分可以順利混溶而不發生相分離。由於SMEDDS內部含有介面活性劑和共溶劑，可以提高水溶性差藥物的溶解度，當SMEDDS與人體腸道中的水接觸後，可以快速自乳化，形成微小的油滴，使藥物更容易被吸收，進一步提高藥物的生體可用率。柳氮磺吡啶（Sulfasalazine）是一種合成藥物，目前在臨床上用於治療類風濕性關節炎、潰瘍性結腸炎和其他類似的炎症性腸道疾病。然而，由於其低水溶解度和高滲透性特性，若能提高磺胺嘧啶的水溶解度，即有提升其生體可用率的可能。本研究的目的在於探討何種條件是最適合製備出穩定且含有最高藥物含量的固化SMEDDS。在SMEDDS的研究中，最終所篩選出的SMEDDS配方在溶離後粒徑約30 nm，PDI為0.181，最大的載藥量為12.5 mg/mL。為提高SMEDDS長時間儲存的穩定性我們進一步利用噴霧乾燥 (spray drying)技術，並使用親水性載體葡萄聚醣和疏水性載體矽酸鈣將SMEDDS製備成固化SMEDDS (solidified SMEDDS, s-SMEDDS)，來評估這兩種不同載體與SMEDDS的比例對於噴霧乾燥過程的影響。並透過實驗設計的方式優化s-SMEDDS，找出能乘載最高藥物含量的固化SMEDDS配方。最終確認的s-SMEDDS配方為SMEDDS 64.25 %、葡萄聚醣35.75 %，其製備後的產率為90 %，藥物回收率達到85 %，其藥物乘載劑量為10.5 mg/g。在藥物釋放率試驗中，SMEDDS及優化後固化SMEDDS在4小時內釋放80 %的藥物。安定性試驗中藥物含量在3個月內也維持在90 %之上。藥物動力學試驗中，SMEDDS和優化後的s-SMEDDS的血液中最高濃度 (Cmax)遠高於游離藥物，相對生體可用率分別增加2.3和2倍。綜合上述結果，SMEDDS及優化固化SMEDDS製劑皆成功製備，兩種製劑皆有表現出色的安定性和藥物釋放能力，同時在生體可用率上也有明顯提高。	zh_TW
dc.description.abstract	Self-microemulsifying drug delivery system (SMEDDS) has been used to enhance thesolubility and bioavailability of poorly water soluble drugs for oral administration. This drug carrier consists of oil, surfactant, and cosolvent at specific ratios, which can dissolve drug without phase separation. In the gastrointestinal tract, SMEDDS spontaneously Self-emulsify and form small oil droplets, facilitating drug absorption and further enhancing drug bioavailability. Sulfasalazine is a synthetic drug currently used to treat rheumatoid arthritis, ulcerative colitis, and other similar inflammatory bowel diseases in clinic. In this study, the SMEDDS and solidified SMEDDS (s-SMEDDS) was developed to encapsulate sulfasalazine with the characteristics of low water solubility and high permeability. To identify the Self-emulsifying regions, a pseudoternary phase diagram was constructed by mixing the selected excipients at various ratios. An optimal SMEDDS incorporating sulfasalazine (SSZ SMEDDS) was generated in the formulation of peanut oil 20 %、TPGS 70%、Transcutol® P 10%. The particle size, PDI and drug content in the SSZ SMEDDS is about 30 nm, 0.181 and 12.5 mg/mL, respectively. Furthermore, spray drying technology is used to convert the SMEDDS into s-SMEDDS, aiming to enhance the long-term stability of SSZ SMEDDS. The formulation of SSZ s-SMEDDS was optimized by experimental design. The final SSZs-SMEDDS formulation was 64.25 % SMEDDS and 35.75 % dextran, capable of carrying 10.5 mg/g of drug. The fabricated SSZ SMEDDS and s-SMEDDS were well dispersed well in aqueous solutions without any problems of physical or chemical stability. The dissolution profiles of sulfasalazine in the SMEDDS and s-SMEDDS were similar with 80% of drug release within 4 hours. The in vivo pharmacokinetic study shows that the maximum concentration (Cmax) of optimized SMEDDS and s-viSMEDDS in the blood was significantly higher than that of free drugs, increasing the relative bioavailability by 2.3 and 2 times, respectively. These results demonstrated that the formulation of s-SMEDDS incorporating sulfasalazine can significantly increase drug solubility and stability, enhance drug absorption, leading to increased oral bioavailability	en
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dc.description.tableofcontents	目次 ................................................................................................................................................... ii 致謝............................................................................................................................................ i 摘要.......................................................................................................................................... iii Abstract.................................................................................................................................... v 目次......................................................................................................................................... vii 圖次........................................................................................................................................... x 表次.......................................................................................................................................... xi 第一章緒論............................................................................................................................. 1 1.1 溶解度............................................................................................................................ 1 1.2 乳化 (Emulsion)........................................................................................................... 1 1.3 脂質劑型分類系統 (Lipid formulation classification system, LFCS)..................... 2 1.4 自微乳化藥物遞送系統 (Self-microemulsifying drug delivery system, SMEDDS)2 1.4.1 自微乳化藥物遞送系統的賦形劑.......................................................................... 3 1.4.2 自微乳化藥物遞送系統所面臨到的困境............................................................. 5 1.5 固化自微乳化藥物遞送系統 (solidified Self-microemulsifying drug delivery system, s-SMEDDS)............................................................................................................. 6 1.5.1 噴霧乾燥 (spray drying)....................................................................................... 6 1.5.2 固體載體 (solid carrier) ....................................................................................... 7 1.6 實驗設計........................................................................................................................ 7 1.7 柳氮磺吡啶 (sulfasalazine, SSZ)................................................................................. 8 1.8 研究動機與目的.......................................................................................................... 8 第二章材料和方法............................................................................................................... 10 2.1 實驗藥品...................................................................................................................... 10 2.2 SMEDSS 賦形劑篩選.................................................................................................. 11 2.3 SMEDDS 製備 ............................................................................................................. 11 2.3.1 配製未乘載藥物的 SMEDDS ............................................................................. 11 2.3.2 繪製未乘載藥物之 SMEDDS 三相圖................................................................. 12 2.3.3 製備乘載 sulfasalazine 之 SMEDDS.................................................................. 12 2.3.4 測定 sulfasalazine 對不同 SMEDDS 比例之溶解度......................................... 12 2.3.5 測定乘載 sulfasalazine 及未乘載 sulfasalazine 之 SMEDDS 粒徑及多分散指數 (Polydispersity index, PDI)..................................................................................... 12 2.4 sulfasalazine 分析方法 ................................................................................................ 13 2.4.1 sulfasalazine 溶液 HPLC 分析方法及確立 .................................................... 13 2.4.2 檢測血液中 sulfasalazine 之 HPLC 分析方法開發及確立 .............................. 14 2.5 固態自微乳化藥物遞送系統製備.............................................................................. 15 2.5.1 製備乘載 sulfasalazine 之固態自微乳化藥物遞送系統 (solidified SMEDDS, s-SMEDDS).................................................................................................................... 15 2.5.2 以葡萄聚醣 (Dextran 40)製備 SSZ s-SMEDDS............................................... 16 2.5.3 以矽酸鈣 (Calcium Silicate)製備 SSZ s-SMEDDS.......................................... 16 2.5.4 Solid SMEDDS 藥物回收率................................................................................. 16 2.6 利用實驗設計優化配方.............................................................................................. 17 2.7 藥物體外釋放試驗 (In vitro drug release studies) .................................................. 17 2.7.1 配製擬似胃液 (stimulated gastric fluid, SGF) ................................................. 17 2.7.2 SSZ SMEDDS 及優化過後 SSZ s-SMEDDS 在擬似胃液中的溶離後的粒徑和PDI.................................................................................................................................. 17 2.7.3 SMEDDS 及優化過後 s-SMEDDS 在擬似胃液中的藥物釋放 (drug release)試驗..................................................................................................................................... 18 2.8 安定性測試.................................................................................................................. 18 2.8.1 藥物含量試驗....................................................................................................... 18 2.8.1 藥物含量加速性測試........................................................................................... 18 2.9 藥物動力學試驗 (pharmacokinetic studies)............................................................ 19 第三章結果與討論............................................................................................................... 20 3.1 SMEDDS 賦形劑篩選 ................................................................................................. 20 3.1.1 利用 sulfasalazine 在不同濃度下的吸光值製作 sulfasalazine 的檢量線........ 20 3.1.2 sulfasalazine 在不同賦形劑下之溶解度測試 ..................................................... 20 3.2 乘載 sulfasalazine SMEDDS 配製............................................................................. 21 3.2.1 SMEDDS 配製以及繪製三相圖 .......................................................................... 21 3.2.2 SSZ SMEDDS 配製 .............................................................................................. 22 3.2.3 sulfasalazine 對不同 SMEDDS 比例之溶解度................................................... 23 3.3 粒徑及 PDI.................................................................................................................. 23 3.4 製備乘載 sulfasalazine 之 s-SMEDDS...................................................................... 24 3.4.1 利用噴霧乾燥技術製備 SSZ s-SMEDDS........................................................... 24 3.4.2 sulfasalazine 之分析方法建立 ............................................................................. 25 3.4.3 s-SMEDDS 藥物回收率及藥物含量測試............................................................ 25 3.5 優化 s-SMEDDS 製備比例 ........................................................................................ 26 3.5.1 實驗設計假設....................................................................................................... 26 3.5.2 葡萄聚醣和 SSZ SMEDDS 組別分析討論 ......................................................... 27 3.5.3 矽酸鈣和 SSZ SMEDDS 組別分析討論 ............................................................. 27 3.5.4 優化後的 SSZ s-SMEDDS 配方 .......................................................................... 27 3.6 SSZ SMEDDS 及 SSZ s-SMEDDS 在擬似胃液中的粒徑、PDI 及藥物釋放率(Drug release)..................................................................................................................... 28 3.7 安定性試驗.................................................................................................................. 29 3.7.1 藥物含量試驗....................................................................................................... 29 3.7.2 加速性藥物含量試驗............................................................................................ 29 3.8 藥物動力學試驗.......................................................................................................... 30 3.8.1 建立血液中 sulfasalazine 之 HPLC 分析方法 .................................................. 30 3.8.2 藥物動力學試驗................................................................................................... 31 第四章結論........................................................................................................................... 33 第五章未來展望................................................................................................................... 34 參考文獻................................................................................................................................. 75 圖次附圖一、生物藥劑學分類系統 (biopharmaceutics classification system, BCS )............ 35 附圖二、噴霧乾燥示意圖..................................................................................................... 36 附圖三、疏水性及親水性載體............................................................................................. 37 圖一、sulfasalazine 可見光全圖譜波長 .............................................................................. 38 圖二、sulfasalazine 檢量線（calibration curve）配製結果............................................. 39 圖三、sulfasalazine 對不同賦形劑之溶解度 ...................................................................... 40 圖四、sulfasalazine 對不同 LCT 之溶解度........................................................................ 41 圖五、Corn oil、TPGS、Transcutol® P 製備 SMEDDS 之三相圖................................. 42 圖六、Peanut oil、TPGS、Transcutol® P 製備 SMEDDS 之三相圖.............................. 43 圖七、Cottonseed oil、TPGS、Transcutol® P 製備 SMEDDS 之三相圖....................... 44 圖八、Corn oil、TPGS、Transcutol® P 製備 SSZ SMEDDS 之三相圖......................... 45 圖九、Peanut oil、TPGS、Transcutol® P 製備 SSZ SMEDDS 之三相圖...................... 46 圖十、Cottonseed oil、TPGS、Transcutol® P 製備 SSZ SMEDDS 之三相圖............... 47 圖十一、以 HPLC 分析 sulfasalazine 之圖譜 .................................................................... 48 圖十二、以 HPLC 分析 sulfasalazine 之檢量線 ................................................................ 48 圖十三、SSZ SMEDDS 和優化配方之 SSZ s-SMEDDS 藥物釋放率.............................. 49 圖十四、SSZ SMEEDS、優化後之 SSZ s-SMEDDS 之藥物含量測試 (儲存在 25 ℃) 50 圖十五、SSZ SMEEDS、優化後之 SSZ s-SMEDDS 之藥物含量測試 (儲存在 40 ℃) 51 圖十六、以 HPLC 分析血液之圖譜.................................................................................... 52 圖十七、以 HPLC 所分析血中 sulfasalazine 之檢量線 .................................................... 52 圖十八、比較 Free form SSZ、SSZ SMEDDS、優化後之 SSZ s-SMEDDS 口服給藥後，在小鼠血液中的藥物濃度對時間之關係圖................................................................. 53 表次附表一、脂質劑型分類系統................................................................................................. 54 表一、以不同的 Corn oil、TPGS、Transcutol® P 比例配製之 SMEDDS 配方............ 55 表二、以不同的 Peanut oil、TPGS、Transcutol® P 比例配製之 SMEDDS 配方。..... 56 表三、以不同的 Cottonseed oil、TPGS、Transcutol® P 比例配製之 SMEDDS 配方。................................................................................................................................................. 57 表四、以不同的 Corn oil、TPGS、Transcutol® P 比例配製之 SSZ SMEDDS 樣貌.... 58 表五、以不同的 Peanut oil、TPGS、Transcutol® P 比例配製之 SSZ SMEDDS 樣貌. 59 表六、以不同的 Cottonseed oil、TPGS、Transcutol® P 比例配製之 SSZ SMEDDS 樣貌............................................................................................................................................. 60 表七、Sulfasalazine 對不同的 corn oil、TPGS、Transcutol® P 比例配製之 SMEDDS之溶解度測試......................................................................................................................... 61 表八、Sulfasalazine 對不同的 peanut oil、TPGS、Transcutol® P 比例配製之 SMEDDS之溶解度測試......................................................................................................................... 62 表九、Sulfasalazine 對不同的 cottonseed oil、TPGS、Transcutol® P 比例配製之SMEDDS 之溶解度測試 ....................................................................................................... 63 表十、SMEDDS 和 SSZ SMEDDS 溶離後脂粒徑及 PDI................................................. 64 表十一、不同比例之 Calcium silicate 和 Dextran 40 製備之 s-SMEDDS 溶離後之粒徑及 PDI..................................................................................................................................... 65 表十二、以 HPLC 分析 sulfasalazine 溶液的準確度與精密度 ........................................ 66 表十三、不同比例之 Calcium silicate 和 Dextran 40 製備之 s-SMEDDS 之產率、藥物含量及藥物回收率................................................................................................................. 67 表十四、混合設計之 SMEDDS/Dextran 組別與部分反應 ............................................... 68 表十五、混合設計之 SMEDDS/Calcium silicate 組別與部分反應值 .............................. 69 表十六、優化後之最佳配方 SMEDDS/Calcium silicate 和 SMEDDS/Dextran 組別與預測反應值................................................................................................................................. 70 表十七、優化後之最佳配方 SMEDDS/Calcium silicate 和 SMEDDS/Dextran 組別與實際反應值................................................................................................................................. 71 表十八、SSZ SMEDDS 與 SSZ s-SMEDDS 以 SGF 溶離後之粒徑及 PDI.................... 72 表十九、以 HPLC 分析血液中 sulfasalazine 的準確度與精密度 .................................... 73 表二十、Free form sulfasalazine、sulfasalazine SMEDDS、sulfasalazine s-SMEDDS 口服給藥後於小鼠體內的藥物動力學參數............................................................................. 74	-
dc.language.iso	zh_TW	-
dc.subject	自微乳化藥物遞送系統	zh_TW
dc.subject	柳氮磺吡啶	zh_TW
dc.subject	噴霧乾燥	zh_TW
dc.subject	實驗設計	zh_TW
dc.subject	sulfasalazine	en
dc.subject	spray drying	en
dc.subject	Self-Microemulsifying Drug Delivery System	en
dc.subject	design of experiment	en
dc.title	發展柳氮磺吡啶之固化自微乳化藥物遞送系統	zh_TW
dc.title	Development of solidified Self-microemulsifying drug delivery system for sulfasalazine	en
dc.type	Thesis	-
dc.date.schoolyear	112-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	林甫容 ;吳亘承;蔡翠敏	zh_TW
dc.contributor.oralexamcommittee	Fu-Jung Lin;Hsuan-Chen Wu;Tsui-Min Tsai	en
dc.subject.keyword	自微乳化藥物遞送系統,柳氮磺吡啶,噴霧乾燥,實驗設計,	zh_TW
dc.subject.keyword	Self-Microemulsifying Drug Delivery System,sulfasalazine,spray drying,design of experiment,	en
dc.relation.page	79	-
dc.identifier.doi	10.6342/NTU202400993	-
dc.rights.note	未授權	-
dc.date.accepted	2024-05-28	-
dc.contributor.author-college	生命科學院	-
dc.contributor.author-dept	生化科技學系	-
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