由 Sesamolin 酸水解生成Samin 之研究

I-Hsuan Chu; 朱逸瑄

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/77489

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蘇南維
dc.contributor.author	I-Hsuan Chu	en
dc.contributor.author	朱逸瑄	zh_TW
dc.date.accessioned	2021-07-10T22:04:35Z	-
dc.date.available	2021-07-10T22:04:35Z	-
dc.date.copyright	2018-08-21
dc.date.issued	2018
dc.date.submitted	2018-08-16
dc.identifier.citation	洪偉晴 (2015) 由脫脂芝麻粕回收製備芝麻素酚之研究。國立台灣大學農業化學系碩士論文。 Afaf, K. E., Ali, M., & Sidiga, W. (2011). Sesame Seed Lignans: Potent physiological modulators and possible ingredients in functional foods & nutraceuticals. Recent Patents on Food, Nutrition & Agriculture, 3(1), 17-29. Akimoto, K., Kitagawa, Y., Akamatsu, T., Hirose, N., Sugano, M., Shimizu, S., & Yamada, H. (1993). Protective effects of sesamin against liver damage caused by alcohol or carbon tetrachloride in rodents. Annals of Nutrition and Metabolism, 37(4), 218-224. Bellussi, G., Carati, A., Clerici, M. G., Maddinelli, G., & Millini, R. (1992). Reactions of titanium silicalite with protic molecules and hydrogen peroxide. Journal of Catalysis, 133(1), 220-230. Budowski, P., & Markley, K. S. (1951). The chemical and physiological properties of sesame oil. Chemical Reviews, 48(1), 125-151. Dar, A. A., & Arumugam, N. (2013). Lignans of sesame: Purification methods, biological activities and biosynthesis – A review. Bioorganic Chemistry, 50, 1- 10. deMan, J. M., Tie, F., & deMan, L. (1987). Formation of short chain volatile organic acids in the automated AOM method. Journal of the American Oil Chemists’ Society, 64(7), 993-996. Dong, P., Fu, X., Wang, X., Wang, W.-m., Cao, W.-m., & Zhang, W.-y. (2015). Protective Effects of Sesaminol on BEAS-2B Cells Impaired by Cigarette Smoke Extract. Cell Biochemistry and Biophysics, 71(2), 1207-1213. Fukuda, N., Miyagi, C., Zhang, L., Jayasooriya, A. P., Sakono, M., Yamamoto, K., ＆ Sugano, M. (1998). Reciprocal effects of dietary sesamin on ketogenesis and triacylglycerol secretion by the rat liver. Journal of Nutritional Science and Vitaminology, 44(5), 715-722. Fukuda, Y., Nagata, M., Osawa, T., & Namiki, M. (1986-a). Chemical aspects of the antioxidative activity of roasted sesame seed oil, and the effect of using the oil for frying. Agricultural and Biological Chemistry, 50(4), 857-862. Fukuda, Y., Nagata, M., Osawa, T., & Namiki, M. (1986-b). Contribution of lignin analogues to antioxidative activity of refined unroasted sesame seed oil. Journal of the American Oil Chemists’ Society, 63(8), 1027-1031. Fukuda, Y., Osawa, T., Kawakishi, S., & Namiki, M. (1994). Chemistry of lignin antioxidants in sesame seed and oil. 547(6), 264-274. Hiremath, S., G. Patil, C., B. Patil, K., & Nagasampige, M. (2007). Genetic diversity of seed lipid content and fatty acid composition in some species of Sesamum L. (Pedaliaceae). Affrican Journal of Biotechnology, 6(5), 539-543. Hirose, N., Inoue, T., Nishihara, K., Sugano, M., Akimoto, K., Shimizu, S., & Yamada,H. (1991). Inhibition of cholesterol absorption and synthesis in rats by sesamin.The Journal of Lipid Research, 32(4), . Huang, J., Song, G., Zhang, L., Sun, Q., Lu, X., (2012). A novel conversion of sesamolin to sesaminol by acid cation exchang resin. European Journal of Lipid Science and Technology, 114(7), 842-848. Kang, M.-H., Katsuzaki, H., & Osawa, T. (1998). Inhibition of 2,2′-azobis(2,4-dimethylvaleronitrile)-induced lipid peroxidation by sesaminols. Lipids, 33(10), 1031-1036. Kato, M. J., Chu, A., Davin, L. B., & Lewis, N. G. (1998). Biosynthesis of antioxidant lignans in Sesamum indicum seeds. Phytochemistry, 47(4), 583-591. Kiso, Y. (2004). Antioxidative roles of sesamin, a functional lignan in sesame seed, and it's effect on lipid- and alcohol-metabolism in the liver: A DNA microarray study. Biofactors, 21(1), . Kumano, T., Fujiki, E., Hashimoto, Y., & Kobayashi, M. (2016). Discovery of a sesamin-metabolizing microorganism and a new enzyme. Proceedings of the National Academy of Sciences, 113(32), 9087. Kumazawa, S., Koike, M., Usui, Y., Nakayama, T., & Fukuda, Y. (2003). Isolation of sesaminols as antioxidative components from roasted sesame seed oil. Journal of Oleo Science, 52(6), 303-307. Li, C. Y., Chow, T. J., & Wu, T. S. (2005). The epimerization of sesamin and asarinin. Journal of Natural Products, 68(11), 1622-1624. Milder, I. E. J., Arts, I. C. W., Venema, D. P., & Hollman, P. C. H. (2007). Lignan contents of Dutch plant foods: a database including lariciresinol, pinoresinol, secoisolariciresinol and matairesinol. British Journal of Nutrition, 93(3), 393-402. Miyake, Y., Fukumoto, S., Okada, M., Sakaida, K., Nakamura, Y., & Osawa, T. (2005). Antioxidative catechol lignans converted from sesamin and sesaminol triglucoside by culturing with Aspergillus. Journal of Agricultural and Food Chemistry, 53(1), 22-27. Moazzami, A. A., Andersson, R. E., & Kamal-Eldin, A. (2007). Quantitative NMR analysis of a sesamin catechol metabolite in human urine. The Journal of Nutrition, 137(4), 940-944. Nagata, M., Osawa, T., Namiki, M., Fukuda, Y., & Ozaki, T. (1987). Stereochemical structures of antioxidative bisepoxylignans, sesaminol and its isomers, transformed from sesamolin. Agricultural and Biological Chemistry, 51(5),1285-1289. Nagata, M., Osawa, T., Namiki, M., Fukuda, Y., & Ozaki, T. (2014). Stereochemical structures of antioxidative bisepoxylignans, sesaminol and its isomers, transformed from sesamolin. Agricultural and Biological Chemistry, 51(5),1285-1289. Namiki, M. (1995). The chemistry and physiological functions of sesame. Food Reviews International., 11(2), 281-329. Noh Ryu, S. U., Ho, C. T., & Osawa, T. (2007). High performance liquid chromatographic determination of antioxidant lignan glycosides in some varieties of sesame. Journal of Food Lipids, 5(1), 17-28. Osawa, T., Yoshida, A., Kawakishi, S., Yamashita, K., & Ochi, H. (1995). Protective role of dietary antioxidants in oxidative stress. In “Oxidative Stress and Aging”, ed. R. G. Cutler, pp. 367-377. Parker, R. S., Sontag, T. J., & Swanson, J. E. (2000). Cytochrome P4503A-dependent metabolism of tocopherols and inhibition by sesamin. Biochemical and Biophysical Research Communications, 277(3), 531-534. Shimizu, S., Akimoto, K., Shinmen, Y., Kawashima, H., Sugano, M., & Yamada, H.(1991). Sesamin is a potent and specific inhibitor of Δ5 desaturase in polyunsaturated fatty acid biosynthesis. Lipids, 26(7), Tan, C. P., Che Man, Y. B., Selamat, J., & Yusoff, M. S. A. (2002). Comparative studies of oxidative stability of edible oils by differential scanning calorimetry and oxidative stability index methods. Food Chemistry, 76(3), 385-389. Tomimori, N., Rogi, T., & Shibata, H. (2017). Absorption, distribution, metabolism, and excretion of [14C]sesamin in rats. Mol Nutr Food Res, 61(8). Umeda-Sawada, R., Takahashi, N., & Igarashi, O. (1995). Interaction of sesamin and eicosapentaenoic acid against Δ5 desaturation and n-6/ n-3 ratio of essential fatty acids in rat. Bioscience, Biotechnology, and Biochemistry, 59(12), 2268-2273. Worawalai, W., Khongchai, P., Surachaitanawat, N., & Phuwapraisirisan, P. (2016). Synthesis of furofuran lignans as antidiabetic agents simultaneously achieved by inhibiting α-glucosidase and free radical. Archives of Pharmacal Research, 39(10), 1370-1381. Yamashita, K., Iizuka, Y., Imai, T., & Namiki, M. (1995). Sesame seed and its lignans produce marked enhancement of vitamin E activity in rats fed a low α-tocopherol diet. Lipids, 30(11), 1019-1028. Yasuda, K., Ikushiro, S., Kamakura, M., Munetsuna, E., Ohta, M., & Sakaki, T. (2011). Sequential metabolism of sesamin by cytochrome P450 and UDPglucuronosyltransferase in human liver. Drug Metabolism and Disposition, 39(9), 1538. Yasuda, K., Ikushiro, S., Kamakura, M., Ohta, M., & Sakaki, T. (2010). Metabolism of sesamin by cytochrome P450 in human liver microsomes. Drug Metabolism and Disposition, 38(12), 2117.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/77489	-
dc.description.abstract	芝麻油良好的氧化安定性與芝麻木酚素有關，然而芝麻油中含量最多的兩種木酚素sesamin及sesamolin在試管試驗中卻僅呈現非常低的抗氧化性。過去文獻中發現若能將這類具有methylenedioxy結構的木酚素開環形成catechols，其抗氧化性將可大幅提升。本研究基於此概念，利用氧化劑與芝麻木酚素反應，期望能得到具有抗氧化性的反應產物。本研究第一部分先探討不同氧化劑對sesamin與sesamolin的影響，結果顯示過量的氧化劑對sesamin及sesamolin皆無作用，然而其中發現當在酸性條件下加入30% H2O2(aq)，Sesamolin對酸敏感因而降解形成sesamol和7R, 7’R-samin，其結構對照過去研究將sesamolin以酸水解產生sesamol與7R, 7’S-samin，其7’碳上氫氧基鍵結方向相反。第二部分探討7R, 7’R-samin之生成機制，首先探討加入雙氧水與否、反應的溫度、時間與酸濃度對7R, 7’S-samin與7R, 7’R-samin生成之影響，結果顯示加酸僅產生sesamol與7R, 7’S-samin，生成量隨反應溫度與時間增加呈正相關。以不同濃度之酸溶液與等體積雙氧水反應時，隨酸濃度增加，7R, 7’S-samin逐漸減少，反之7R, 7’R-samin逐漸增加。續探討酸與雙氧水添加之先後順序是否影響7R, 7’S-samin與7R, 7’R-samin之生成，結果顯示基質先加酸反應後產生sesamol與7R, 7’S-samin，此時再添加雙氧水時即產生sesamol與7R, 7’R-samin。過去文獻已知sesamolin經酸水解產生sesamol及oxonium ion之過渡體，接著經由分子內重排而形成sesamol與7R, 7’S-samin，綜合上述之結果推測7R, 7’S-samin於酸環境下會形成oxonium ion，雙氧水與oxonium ion以氫鍵形成七元環而使7’碳上鍵結方向相反。第三部分以Rancimat法評估7R, 7’R-samin對芝麻油三酸甘油酯的影響，結果顯示7R, 7’R-samin隨添加量增加會有促氧化的作用。	zh_TW
dc.description.abstract	Sesame lignans are responsible for outstanding oxidative stability of sesame oil. However, sesamin and sesamolin, the major lignans in sesame oil, possess no antioxidant activity in vitro. Previous studies reported that antioxidant activity of lignans would be increased by converting methylenedioxy structures to catechols. On the basis of previous study, this study utilizes oxidants to react with sesamin and sesamolin, expected to obtain the resultant products with better antioxidant activity. In the first part of this study, we investigated the effect of different oxidant agents on sesamin and sesamolin. The results showed that excess oxidant agents had no effect on sesamin and sesamolin. However, when 30% H2O2(aq) was added under acidic condition, sesamolin was sensitive to acid and hydrolyzed to form sesamol and 7R, 7'R-samin. Such structure was compared with the finding in our previous study, sesamolin acid hydrolysis resulting in formation of sesamol and 7R, 7’S-samin, revealing that the binding of hydroxyl group on the C7’ was reversed. In the second part of this study, we studied on the mechanism of 7R, 7'R-samin formation. Firstly, we investigated the effect of hydrogen peroxide addition, reaction temperature, time-course study and acid concentration on the formation of 7R, 7'S-samin and 7R, 7'R-samin. The results showed that the addition of acid produced sesamol and 7R, 7’S-samin and the content of sesamol and 7R, 7’S-samin was positively correlated with the increase of reaction temperature and time-course. When different acid concentrations were added with an equal volume of hydrogen peroxide, 7R, 7'S-samin gradually decreased with increasing acid concentration, whereas 7R, 7'R-samin gradually increased. Secondly, we investigated the effect of the addition sequence of acid and hydrogen peroxide on 7R, 7’S-samin and 7R, 7’R-samin formation. The results showed that sesamol and 7R, 7’S-samin were formed after substrates have hydrolyzed with acid and 7R, 7’S-samin converted to 7R, 7’R-samin after hydrogen peroxide has reacted with reaction mixtures. Previous study has shown that sesamolin acid hydrolysis formed sesamol and an oxonium ion in transition state, followed by intramolecular rearrangement to form sesamol and 7R, 7’S-samin. Based on the results, it is speculated that 7R, 7'S-samin forms transitional oxonium ions in acid conditions and then hydrogen peroxide would be accessible to form hydrogen bonds with oxonium ion to generate a seven-membered ring structure and the bonding of C7' was opposite. In the third part of this study, we evaluated the effects of 7R, 7'R-samin on sesame oil triglyceride by Rancimat method. The results showed that 7R, 7'R-samin was pro-oxidation with the increase of the amount.	en
dc.description.provenance	Made available in DSpace on 2021-07-10T22:04:35Z (GMT). No. of bitstreams: 1 ntu-107-R05623026-1.pdf: 4770134 bytes, checksum: 0575f5943082a31368160889933d73c5 (MD5) Previous issue date: 2018	en
dc.description.tableofcontents	口試委員審定書中文摘要........................................................................................................................ I Abstract...................................................................................................................... IV 目錄............................................................................................................................. VI 圖目錄......................................................................................................................... IX 表目錄......................................................................................................................... XI 縮寫對照表................................................................................................................XII 第一章前言..................................................................................................................1 第二章、文獻回顧........................................................................................................2 第一節芝麻油........................................................................................................2 1. 簡介................................................................................................................2 2. 芝麻油脂肪酸組成........................................................................................2 3. 芝麻油製取工藝............................................................................................4 4. 芝麻油氧化安定性........................................................................................6 第二節芝麻木酚素(sesame lignan).......................................................................9 1. 簡介................................................................................................................9 2. 生合成路徑..................................................................................................13 3. 生理活性......................................................................................................15 4. 芝麻木酚素於油脂精煉過程中的轉換......................................................16 5. Sesaminol 製備相關研究............................................................................20 第三節由芝麻木酚素轉化之新型抗氧化劑......................................................24 第四節芝麻木酚素光學異構物..........................................................................27 第五節油脂氧化安定性......................................................................................28 1. 簡介..............................................................................................................28 2. Rancimat method .........................................................................................28 第三章材料與方法..................................................................................................29 第一節實驗架構..................................................................................................29 第二節實驗材料..................................................................................................30 第三節實驗方法..................................................................................................32 1. 不同強氧化劑對基質的影響......................................................................32 2. 不同強氧化劑加酸對基質的影響..............................................................32 3. 分離純化 7R, 7’R-samin 之條件................................................................32 4. 高壓液相層析串聯質譜儀(UHPLC-HR-ESI-OB)分析7R, 7’R-samin 之條件…… ..................................................................................................................33 5. 核磁共振光譜分析 7R, 7’S-samin 之條件................................................33 6. 7R, 7’S-samin 及7R, 7’R-samin 生成機制................................................33 7. 芝麻油三酸甘油酯之製備..........................................................................34 8. 油脂氧化安定性試驗..................................................................................34 第四章結果與討論..................................................................................................36 第一節不同強氧化劑對基質的影響..................................................................36 第二節不同強氧化劑加酸對基質的影響..........................................................38 第三節 Sesamolin 與酸化雙氧水反應之產物分析............................................40 1. 以半製備級高效液相層析儀分離 7R, 7’R-samin.....................................40 2. 7R, 7’R-samin 光譜資訊............................................................................41 第四節由sesamolin 形成7R, 7’R-samin 之機制探討......................................44 1. 探討基質與2 M H2SO4 在不同溫度及反應時間對生成7R, 7’S-samin 之影響…………………………………………………………………………....... 45 2. 探討基質加酸化雙氧水在不同溫度及酸濃度對 7R, 7’S-samin 及7R, 7’Rsamin 生成量之影響............................................................................................46 3. 基質加酸或 H2O2 添加順序對7R, 7’S-samin 及7R, 7’R-samin 生成的影響….. ....................................................................................................................48 4. 7R, 7’S-samin 及7R, 7’R-samin 之生成機制............................................51 第五節芝麻木酚素與7R, 7’R-samin 對芝麻油三酸甘油酯氧化安定性之影響 ..................................................................................................................................54 第五章結論..............................................................................................................57 第六章參考資料......................................................................................................58
dc.language.iso	zh-TW
dc.title	由 Sesamolin 酸水解生成Samin 之研究	zh_TW
dc.title	Studies on the Formation of Samin derived from Acid Hydrolysis of Sesamolin	en
dc.type	Thesis
dc.date.schoolyear	106-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	鍾玉明,李偉如,高彩華,李敏雄
dc.subject.keyword	芝麻林素,酸水解,samin異構物,	zh_TW
dc.subject.keyword	sesamolin,acid hydrolysis,samin stereoisomer,	en
dc.relation.page	60
dc.identifier.doi	10.6342/NTU201803651
dc.rights.note	未授權
dc.date.accepted	2018-08-16
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	農業化學研究所	zh_TW
顯示於系所單位：	農業化學系

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