‘巨峰’葡萄果皮中對二苯代乙烯類化合物之萃取、分離與檢測之研究

Yu-Fen Tu; 杜郁芬

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40601

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王自存
dc.contributor.author	Yu-Fen Tu	en
dc.contributor.author	杜郁芬	zh_TW
dc.date.accessioned	2021-06-14T16:52:49Z	-
dc.date.available	2013-09-02
dc.date.copyright	2008-09-02
dc.date.issued	2008
dc.date.submitted	2008-07-29
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Resurreccion, F.K. Saalia, and R.D. Phillips. 2005. Development of a reverse-phase high-performance liquid chromatography method for analyzing trans-resveratrol in peanut kernels. Food Chem. 89:623-638. Sun, B., A.M. Ribes, M.C. Leandro, A.P. Belchior, and M.I. Spranger. 2006. Stilbenes: Quantitative extraction from grape skins, contribution of grape solids to wine and variation during wine maturation. Anal. Chim. Acta 563:382-390. Tokusoglu, O., M.K. Unal, and F. Yemis. 2005. Determination of the phytoalexin resveratrol (3,5,4 '-trihydroxystilbene) in peanuts and pistachios by high-performance liquid chromatographic diode array (HPLC-DAD) and gas chromatography-mass Spectrometry (GC-MS). J. Agric. Food Chem. 53:5003-5009. Trela, B.C.and A.L. Waterhouse. 1996. Resveratrol: Isomeric molar absorptivities and stability. J. Agric. Food Chem. 44:1253-1257. Vinas, P., C. Lopez-Erroz, J.J. Marin-Hernandez, and M. Hernandez-Cordoba. 2000. 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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40601	-
dc.description.abstract	本試驗使用‘巨峰’葡萄(Vitis vinifera × Vitis labrusca ‘Kyoho’)果皮為材料，探討萃取溶液、樣品前處理以及HPLC(高效能液相層析)分離流程，對於trans-piceid與trans-resveratrol之萃取測定的影響。利用trans-piceid與trans-resveratrol的標準品溶液與巨峰葡萄果皮萃取液以及虎杖萃取液進行HPLC試驗，使用C18層析管柱(Thermo，Hypersil-100 C18，5μm, 250 mm× 4.6 mm)分離，紫外光偵測器設定於波長320 nm偵測，試驗結果顯示，同步分析葡萄果皮萃取液或虎杖萃取液中的trans-piceid與trans-resveratrol兩種化合物時，使用40 %氰甲烷為移動相、每分鐘0.6毫升等度淋洗管柱，偵測結果無法判讀，必須以氰甲烷與水梯度淋洗，才能將萃取液中的化合物分離。比較梯度淋洗移動相的遞變速率發現，從0至72分鐘時移動相中氰甲烷濃度由10 %增加至85 % (GS = 1.04 %/min)，流速1.0 ml/min，萃取樣品中trans-piceid與trans-resveratrol成分峰才有良好的解析度。而管柱溫度提高，可縮短所有成分峰的滯留時間，但會使理論板數降低、成分峰變寬，導致解析度下降。為了有良好的解析度以避免偵測誤差，分析時將管柱設定於30℃。試驗結果顯示，使用0.1%鹽酸之甲醇萃取葡萄果皮得到最大量trans-piceid，75%丙酮萃取出最多trans-resveratrol，乙酸乙酯則不適合用來萃取或純化這兩種物質。單獨使用100%甲醇萃取巨峰葡萄果皮與虎杖中的trans-piceid與trans-resveratrol，經由HPLC分離、紫外光偵測儀設定於320 nm測定兩物質的含量，所得數據相對標準偏差(RSD)介於4.19~5.29 %之間。薄層層析純化樣品試驗，以ethyl acetate：water：acetic acid = 15：5：1 (v/v/v)作為展開溶劑可將待測物質與其他化合物分離，但損失達50 %。使用Amberlite XAD-2作固相萃取純化，tran-piceid與trans-resveratrol溶解於10 %甲醇時，吸附於Amberlite XAD-2的效果最好；以80 %氰甲烷洗脫，將吸附於Amberlite XAD-2樹酯上的trans-piceid與trans-resveratrol沖提出來的效果最佳。綜合萃取、純化以及分離偵測等各部份的試驗結果，可發展出一個快速準確的分析方法，以便於測定園產品中trans-piceid與trans-resveratrol之含量。	zh_TW
dc.description.abstract	The objects of this research were use the skin of grape (Vitis vinifera × Vitis labrusca ‘Kyoho’) to study the influence of extract solvents, sample purification and separation program of HPLC on extraction and determination of trans-piceid and trans-resveratrol. Results showed, using methanol of 0.1% hydrochloric acid as a extract solvent got the most amount of trans-piceid, 75% acetone extracts the most trans-resveratrol, and ethyl acetate was unsuitable to be used for extracting and purifying these two compounds. Using 100% methanol to extract trans-piceid and trans-resveratrol in the grape skin without purification, via HPLC separated and detected by a UV detector ( λ=320 nm ), and obtained relatively standard deviation of data (RSD) between 4.19~5.29 %. Using ethyl acetate : water : acetic acid =15 : 5 : 1 (v/v/v) as a development solvent to carry out thin-layer chromatography could separate trans-piceid and trans-resveratrol from the extracts, but lost 50%. Proceeding solid phase extraction (SPE) by Amberlite XAD-2 to purify extracts, as trans-piceid and trans-resveratrol dissolving in 10% methanol, the adsorbent ratio in Amberlite XAD-2 was best; and using 80% acetonitrile to elute, had the best efficiency to recover trans-piceid and trans-resveratrol absorbed on the Amberlite XAD-2. The study of HPLC using a C18 column (Thermo，Hypersil-100 C18，5μm, 250 mm× 4.6 mm) to separate trans-piceid, trans-resveratrol and other compounds in extracts of ‘Kyoho’ grape skin and Polygonum cuspidatum. Results of separation detected by a UV detector ( λ=320 nm ). Results of tests showed, while analysing trans-piceid and trans-resveratrol in grapes skin or Polygonum cuspidatum extracts at the same time, using 40% acetonitrile as mobile phase set at 0.6 ml/min isocratic could not separate well, and the chromatogram could not be determined. Contrarily, using acetonitrile and water as mobile phase set at 1 ml/min gradient made better separation than isocratic. To compare divers gradient steepness, gradient elution increased acetonitrile linearly from 10% to 85% over 72 min (GS = 1.04) with a flow rate of 1 ml/min made the best resolution of trans-piceid and trans-resveratrol peaks from grapes skin or Polygonum cuspidatum extracts. As column temperature increased there was a decrease in retention time of both compounds, but the theoretical plates decreased and the peaks widened resulted in resolution decreased. In order to detect well, the column set at 30℃. To develop a quick and accurate method through these results of extraction, purification, separation and detection make analyzing trans-piceid and trans-resveratrol in horticulture crops easy.	en
dc.description.provenance	Made available in DSpace on 2021-06-14T16:52:49Z (GMT). No. of bitstreams: 1 ntu-97-R94628210-1.pdf: 1774146 bytes, checksum: 1c4e3bd6d01a326a283317b68c0dfe9b (MD5) Previous issue date: 2008	en
dc.description.tableofcontents	目錄頁碼口試委員會審定書.…………………………………………………………..i 誌謝.……………………………………………………………………...…...ii 中文摘要……………………………………………………………………..iii 英文摘要………………………………………………………….….…….....v 第一章前言………………………………………………………..............1 第二章前人研究一、對二苯代乙烯化合物之簡介..…………………………………..…3 二、對二苯代乙烯類化合物之萃取.…………………………..…....…4 三、對二苯代乙烯類化合物之分離、偵測方法…………….……..…7 四、具有對二苯代乙烯類化合物的園產品…………………..…….…8 第三章白藜蘆醇與白藜蘆醇糖苷分離方法之研究摘要………………………………………………………………….……....15 前言…………………………………………………………….….………...15 材料與方法………………………………………………………….……....16 結果與討論………………………………………………………….….…...20 結論………………………………………………………….……………....24 第四章 ‘巨峰’葡萄果皮中白藜蘆醇和白藜蘆醇糖苷之萃取與純化摘要…………………………………………………………..………..…….41 前言…………………………………………………………..…………..….41 材料與方法…………………………………………………..……………...42 結果與討論…………………………………………………..………..…….46 結論…………………………………………………………..………..…….50 參考文獻………………………………………………………….…….......77 附錄………………………………………………………………….………81 圖次頁碼圖1. 自苯丙胺酸合成白黎蘆醇與黃酮的生合途徑。………….………….….9 圖2. 對二苯代乙烯化合物衍生物之結構。…………………….…………….10 圖3. Stlibenes標準品螢光3D掃描等高線圖。……………….………………25 圖4. Stlibenes標準品螢光3D掃描鳥瞰圖。……………..……………………25 圖5.　trans-Piceid標準品之螢光光譜。………………………..…………..….26 圖6. trans- Resveatrol標準品之螢光光譜。………...…………………….….27 圖7. Stlibenes標準品HPLC層析圖。……………………………..…………28 圖8. 對二苯代乙烯類標準品之紫外線連續掃描光譜圖。…..………………29 圖9. 標準品連續光譜圖 (偵測波長＝200~400 nm)。……………….………30 圖10. 標準品HPLC層析圖(紫外線偵測器λ＝320nm）。移動相為40%氰甲烷，每分鐘0.6毫升等度淋洗管柱。………………………..……………31 圖11. 標準品HPLC層析圖(紫外線偵測器λ＝320nm）。梯度淋洗管柱。…32 圖12. 虎杖萃取液HPLC層析圖。移動相為40%氰甲烷，每分鐘0.6毫升等度淋洗管柱。…………………………………………………….…………33 圖13. 虎杖萃取液HPLC層析圖。梯度淋洗管柱。………………….….…..…34 圖14. 標準品HPLC層析圖(紫外線偵測器λ＝320nm）。管柱層析時移動相為3%冰醋酸與氰甲烷梯度淋洗，氰甲烷濃度每分鐘增加4.17 %。….….35 圖15. 葡萄果皮萃取液HPLC層析圖(紫外線偵測器λ＝320nm）。管柱層析時移動相為3%冰醋酸與氰甲烷梯度淋洗，氰甲烷濃度每分鐘增加4.17 %。………………………………………….……………..………………35 圖16. 葡萄果皮萃取液HPLC層析圖(紫外線偵測器λ＝320nm）。梯度淋洗管柱，移動相中氰甲烷濃度每分鐘增加4.17 %。………….….…...………36 圖17. 葡萄果皮萃取液HPLC層析圖(紫外線偵測器λ＝320nm）。梯度淋洗管柱，移動相中氰甲烷濃度每分鐘增2.08 %。…………………….………37 圖18. 葡萄果皮萃取液HPLC層析圖(紫外線偵測器λ＝320nm）。梯度淋洗管柱，移動相中氰甲烷濃度每分鐘增加1.04 %。……………….……..…38 圖19. 標準品HPLC層析圖(紫外線偵測器λ＝320nm）。梯度淋洗管柱，移動相中氰甲烷濃度每分鐘增加1.04 %。…………..………………………38 圖20. 不同管柱溫度之標準品HPLC層析圖(紫外線偵測器λ＝320nm）。…40 圖21. 不同溶液萃取巨峰葡萄果皮中對二苯代乙烯類化合物之效率比較。.59 圖22. 不同萃取溶液之葡萄果皮萃取物HPLC層析圖。………..……….……60 圖23. 虎杖萃取液之紫外線連續掃描光譜圖。…………….……..……………64 圖24. 甲醇萃取樣品HPLC-PDA光譜圖(Photodiode array detection λ＝ 200~400 nm)。…………………….………………………………………65 圖25. trans-Piceid與trans-resveratrol薄層層析圖。……..…………..………66 圖26. 60μg trans-Piceid、60μg trans-resveratrol 標準品經薄層層析後之HPLC層析圖。………………………………….…………………………67 圖27. 75μl 虎杖萃取液經薄層層析後之HPLC層析圖。………………….…68 圖28. 50μl葡萄皮萃取液經薄層層析後之HPLC層析圖。…………..………69 圖29. 混合50μg trans-piceid、60μg trans-resveratrol標準品以及60μl葡萄皮萃取液之點樣經薄層層析後之HPLC層析圖。…………………………70 圖30. 不同濃度的甲醇或氰甲烷沖提已吸附10μg trans-resveratrol之1 ml Amberlite XAD-2樹酯，回收之trans-resveratrol重量。……………….72 圖31. 不同濃度氰甲烷溶液沖提已吸附10μg trans-resveratrol或10μg trans-piceid之1 ml Amberlite XAD-2樹酯，回收之trans-resveratrol 或trans-piceid重量。………………………………………………………73 圖32. 葡萄果皮萃取液以不同方式經1 ml Amberlite XAD-2樹酯純化後，所測定每一公克乾重之trans-piceid與trans-resveratrol含量。……...…74 圖33. 葡萄果皮萃取液HPLC層析圖(紫外線偵測器λ=320nm)。……………75 圖34. 葡萄果皮萃取液經由Amberlite XAD-2樹酯純化後之HPLC層析圖(紫外線偵測器λ=320nm)。.……………………………………………….…76 表次頁碼表1. 文獻中萃取葡萄組織resveratrol與piceid的方法比較…………….…….11 表2. 文獻中以HPLC分析花生與葡萄的對二苯乙稀物質之方法比較。….....12 表3. 管柱溫度不同時，HPLC分析標準品溶液、葡萄果皮萃取液、虎杖萃取液中trans-piceid與trans-resveratrol之成分峰滯留時間與理論板數。39 表4. 乙酸乙酯純化與不經乙酸乙酯純化之甲醇萃取葡萄果皮樣品中trans-piceid和trans-resveratrol含量。……………………….……..……63 表5. 甲醇單一步驟萃取之葡萄果皮與虎杖中trans-piceid、trans-resveratrol 含量。..………………………………………………………………………63 表6. 1 ml以10%甲醇配製之100 μg/ml trans-resveratrol標準品，調整為不同酸度以及使用不同注入方式通過1 ml Amberlite XAD-2後，吸附於 Amberlite XAD-2之trans-resveratrol百分比。……………..……..……71 表7. 1 ml不同濃度之甲醇溶液配製之10 μg/ml trans-resveratrol標準品，通過1 ml Amberlite XAD-2後，吸附於Amberlite XAD-2之 trans-resveratrol百分比。…………………………………………………71
dc.language.iso	zh-TW
dc.subject	葡萄	zh_TW
dc.subject	白藜蘆醇糖&#33527	zh_TW
dc.subject	對二苯代乙烯	zh_TW
dc.subject	白藜蘆醇	zh_TW
dc.subject	grapes	en
dc.subject	stilbenes	en
dc.subject	trans-piceid	en
dc.subject	trans-resveratrol	en
dc.title	‘巨峰’葡萄果皮中對二苯代乙烯類化合物之萃取、分離與檢測之研究	zh_TW
dc.title	Extraction, Separation and Detection of Stilbenes in the Skin of ‘Kyoho’ Grape	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳開憲,張祖亮
dc.subject.keyword	對二苯代乙烯,白藜蘆醇,白藜蘆醇糖&#33527,葡萄,	zh_TW
dc.subject.keyword	stilbenes,trans-piceid,trans-resveratrol,grapes,	en
dc.relation.page	81
dc.rights.note	有償授權
dc.date.accepted	2008-07-31
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	園藝學研究所	zh_TW
顯示於系所單位：	園藝暨景觀學系

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