大豆異黃酮定量方法之改良及加工方式對大豆異黃酮種類轉換之研究

Chih-Kang Chang; 常致綱

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32011

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	李敏雄(Min-Hsiung Lee)
dc.contributor.author	Chih-Kang Chang	en
dc.contributor.author	常致綱	zh_TW
dc.date.accessioned	2021-06-13T03:27:56Z	-
dc.date.available	2006-07-31
dc.date.copyright	2006-07-31
dc.date.issued	2006
dc.date.submitted	2006-07-27
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32011	-
dc.description.abstract	大豆及大豆製品為大豆異黃酮的主要攝取來源，大豆異黃酮為植物雌激素的一種，目前認為對於人體健康方面有保健效果。已有關於大豆異黃酮定量方法已有許多報告，一般係使用乙腈水溶液萃取大豆異黃酮。然後在30℃下真空濃縮後再覆溶於80%甲醇水溶液中，定容後以HPLC進行定量分析，此種樣品製備方法複雜、耗時、容易造成含量被低估、標準偏差大的缺點。在本篇研究係探討一種較為迅速且較為簡易的萃取方法以用於大豆食品中的異黃酮定量分析。在本研究中係利用65%甲醇水溶液作為萃取溶劑，選用benzoic acid或fluorescein化學安定性高的化合物作為定量所需的內標準品，萃取後直接取部份萃取液離心取上清液部分以高效率層析儀分析定量；並可同時選用兩種內標準品雙重確認（double check）。本方法有過程較簡便，且再現性高的優點。65%甲醇水溶液為萃取大豆異黃酮的最佳溶劑，萃取1小時便可達最佳的萃取率。目前大部份的研究報告中所建立的定量方法，主要都是針對大豆中全部12種異黃酮，針對12種個別異黃酮進行分析定量相當耗時且不經濟，在本研究並建立一種異黃酮總量的快速定量方法。此方法之優點為不需準備全部12種大豆異黃酮的標準品且可以縮短分析所需的時間。根據本研究，此方法係使用1.0 M sodium methylate在60℃下與樣品中之acetylglycoside、malonylglycoside反應20分鐘，將其轉化為7-O-glycoside，反應完成後以2.5N鹽酸水溶液中和，調整溶液為80%甲醇溶液並在60℃下繼續萃取30分鐘然後進行HPLC分析；由於僅需要分析兩種形式的大豆異黃酮化合物（aglycones及7-O-glycosides），因此可以有效地縮短分析時間至30分鐘以內。本研究中所提出之總異黃酮含量的定量方法為目前相關研究中最迅速的定量方式。由於malonylglycoside、acetylglycoside無法被人體有效吸收，且不能被微生物代謝轉化，因此研究之另一目的為探討將這類型的大豆異黃酮化合物轉化為生物可利用性較高之7-O-glycosides、aglycones的方法。結果發現在加熱的情況下會造成12種大豆異黃酮的組成改變，於40℃作為加工條件時，alycone為組成份中主要的形式，約佔大豆異黃酮總含量的67%；於90℃的加熱時，則以glycoside為主要的形式，佔總量的69%。	zh_TW
dc.description.abstract	Soybean and soy products are the main sources of isoflavones, a well-studied group of phytoestrogens with numerous biological effects. Several methods have bean published to quantify soy isoflavones in food samples. The aqueous acetonitrile solutions are the most frequently used solvent for isoflavone extraction. However, for some reasons, the extraction should be concentrated to almost dryness by vacuum evaporation at a temperature not higher than 30℃, and then re-dissolved in a different solvent rather than the primary extraction solvent. No doubt, the complicated extraction process is time-consuming, and will cause underestimation as well as a quite large standard deviation. In this study, we developed a rapid and simple method for the quantification of isoflavones in soybean foods. The method includes the extraction of isoflavones from soybean foods by using 65% aqueous methanol containing a chromatographically suitable and chemically stable internal standard (benzoic acid and/or fluorescein) as the extraction solvent, and clarifying an aliquot of extract by microcentrifugation , followed by injection of the supernatant for HPLC analysis. The solvent has a high efficiency for isoflavone extraction, and it reached the maximum extraction yield of isoflavones in one hour. The standard deviation is very small due to the simplicity of extraction process before HPLC analysis. Several methods have been published to quantify all 12 kinds of isoflavone compounds in soybean or soy foods. However, it is time-consuming, and needs many kinds of authentic isoflavone compounds who do not need to collect information about the conjugate pattern in soy samples. Besides building up the extraction method for all 12 forms of isoflavones, in this study, I developed a new quantitative method for determination of total amount of isoflavones. According to our method, we can quantify the total amount of isoflavone more rapid and conventiently without preparing all 12 kinds of standards.In this study, acetyl- and malonyl- glycosides were converted to 7-O-glycosides by reacting with 1M methanolic sodium methylate at 60℃ for 20 min. Then, the solution was neutralized with 2.5N HCL and extracted for further 30 min at 60℃. Aglycones and 7-O-glycosides were then analysed by HPLC. The total analytical time of this method is shorter than any other published quantitative methods. Because the malonyl- and acetyl- glycoside could not bean absorbed by human or metabolized by microorganism. We decided to convert those kinds of isoflavone compounds to more bioavailble forms like 7-O-glycosides or aglycones. I treated the processing temperature on the conversion of isoflavones. In this sudy, I found that the composition of 12 forms of isoflavones was changed during heating in water bath. When processing at 40℃, the isoflavones were mainly composed by aglycones (67%). Besides it, the glycosidic forms are the main composition (56%) when processing at 80℃.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T03:27:56Z (GMT). No. of bitstreams: 1 ntu-95-R93623025-1.pdf: 5000388 bytes, checksum: faec1ace0f525a1f920b5d5c51ede905 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	中文摘要 2 Abstract 4 表次 8 圖次 9 第一章序言 11 第二章文獻整理 13 第一節大豆異黃酮的發現 13 第二節大豆異黃酮的生理益處 16 1. 大豆異黃酮與癌症。 18 2. 大豆異黃酮與心血管循環器官疾病 19 3. 大豆異黃酮與骨質疏鬆症 21 第三節大豆異黃酮的生物可利用性 21 1. 人體對於不同形式之大豆異黃酮的生物可利用性 21 2. 食品中的其他成分對於人體之大豆異黃酮生物可利用率的影響 22 3. 大豆異黃酮的代謝與吸收 23 第四節大豆異黃酮的分析方法 29 1. 全部12種大豆異黃酮化合物之分析技術 29 2. 大豆異黃酮的萃取 29 第五節總大豆異黃酮含量的快速檢測法 30 第三章材料與方法 33 第一節試藥、材料及儀器設備 33 1. 材料 33 2. 試藥 33 3. 儀器設備 34 第二節 HPLC梯度流洗條件 35 第三節方法 – 全部12種大豆異黃酮萃取方法建立 37 1. 萃取溶劑對全部12種大豆異黃酮萃取效率的影響 37 2. 萃取時最適溶劑量和樣品之比率的探討 38 3. 最適萃取時間的探討 38 4. 利用添加已知含量的大豆異黃酮標準品（standard Spiked Test）驗證本研究建議之萃取方法的準確性（accuracy） 43 5. 大豆異黃酮含量計算方式 47 第四節方法 - 針對大豆食品中總異黃酮含量之快速分析 48 1. 使malonylglycoside和acetylglycoside完全反應條件探討 49 2. 反應溫度探討 49 3. 反應時間探討 50 4. 萃取時間的探討 50 第五節方法 – 熱處理加工方式使大豆異黃酮化合物轉變之研究 53 1. 熱處理加工對大豆異黃酮化合物轉變的影響 53 2. 加工完成後之大豆樣品中的大豆異黃酮成分分析 54 第六節數據處理 54 第四章結果與討論 55 第一節全部12種大豆異黃酮萃取方法的建立 55 1. 內標準品安定性 55 2. 溶劑對大豆粉中的大豆異黃酮的萃取效率 55 3. 溶劑體積對大豆異黃酮萃取效率的影響 57 4. 萃取時間對大豆異黃酮萃取效率的影響 57 5. 利用標準添加的實驗來驗證萃取方法的準確性 57 6. 探討不同溶劑對脫脂大豆、傳統硬豆腐、以及盒裝軟豆腐中大豆異黃酮成分萃取的影響 58 7. 探討不同溶劑對發酵大豆製品（味增、醬油粕）中大豆異黃酮成分的萃取效率 59 第二節食品中總大豆異黃酮含量之快速定量法建立 75 1. 使用sodium methylate讓凍乾大豆粉中之malonylglycosides、acetylglycosides完全轉變為7-O-glycosides之條件探討 75 2. 反應過程中最適反應溫度的探討 76 3. 使malonylglycoside、acetylglycoside轉化為7-O-glycosides之最適sodium methylate時間的探討 77 4. 萃取時間對轉化反應完成後之大豆異黃酮樣品的影響 77 5. 探討改變梯度流洗條件對轉化反應完成後樣品之大豆異黃酮成分分析 78 第三節熱處理加工對大豆異黃酮的影響 87 1. 使大豆異黃酮化合物組成改變成aglycone型式為主的熱處理加工條件 87 2. 使大豆異黃酮化合物組成改變成7-O-glycoside型式為主的熱處理加工條件 88 3. 最適加工條件的探討 88 第五章結論 105 第六章參考文獻 110
dc.language.iso	zh-TW
dc.title	大豆異黃酮定量方法之改良及加工方式對大豆異黃酮種類轉換之研究	zh_TW
dc.title	Research on Improvement of the Analysis of Soybean Isoflavones and Effect of Processing on the Conversion of Soybean Isoflavones	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	林子清,王苑春,高馥君,蘇南維(Nan-Wei Su)
dc.subject.keyword	大豆異黃酮,大豆,豆腐,萃取,定量,內標準品,高效率液相層析,	zh_TW
dc.subject.keyword	Isoflavones,soybean,tofu,extraction,quantification,internal standard,HPLC,	en
dc.relation.page	114
dc.rights.note	有償授權
dc.date.accepted	2006-07-28
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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