國產甘藷之花青素組成及抗解澱粉製備之研究

Tzu-Min Wang; 王姿閔

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/22298

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	賴喜美(Hsi-Mei Lai)
dc.contributor.author	Tzu-Min Wang	en
dc.contributor.author	王姿閔	zh_TW
dc.date.accessioned	2021-06-08T04:15:07Z	-
dc.date.copyright	2010-08-17
dc.date.issued	2010
dc.date.submitted	2010-08-09
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/22298	-
dc.description.abstract	本研究分為三部分，第一部分針對兩種國產紫色甘藷(台農73號和芋心甘藷)，進行藷皮及藷肉花青素含量與DPPH自由基清除能力測定，並以HPLC/MS-MS進行花青素結構鑑定。第二部分以四種國產甘藷(台農31、66、73號及芋心甘藷)藷肉凍乾粉末為原料，將10%懸浮液先於40℃/5 min使內生性酵素(alpha及beta-amylase)對澱粉粒進行修飾，再以1、2或3次溫度循環(4℃/22h-30℃/2h)處理，使澱粉顆粒進行韌化作用，以提高甘藷粉之機能性。第三部分以國產甘藷澱粉為原料，先將澱粉糊化並以pullulanase去支鏈而得去支鏈澱粉(debranched starch, DS)，再對17% 去支鏈澱粉懸浮液進行韌化處理(121℃/15m-60℃/8h、121℃/15m-60℃/8h-4℃/16h-60℃/8h)，及80% 去支鏈澱粉懸浮液進行熱濕處理(121℃/2h)，以提高其抗解澱粉(resistant starch, RS)含量。第二及第三部分樣品，以體外消化試驗評估其消化情形及抗解澱粉含量，並進行澱粉膨潤力試驗及廣角度X-光繞射(X-ray diffraction, XRD)分析，以了解其內部結構之變化。芋心甘藷之藷皮與藷肉花青素含量皆高於台農73號，前者分別為93.0及514.5 mg/100 g (db)，後者則分別為46.3及121.2 mg/100 g (db)。甘藷中花青素含量與其DPPH自由基呈正相關性(R2=0.9971)。HPLC/MS-MS分析得到15種花青素結構，其配醣體皆為cyanidin或peonidin，再分別接上不同醣基所構成。經過多次溫度循環，澱粉結構趨於緊密、整齊，致使水分不易滲入，膨潤力下降，導致消化酵素較不易進入澱粉粒中進行水解，因此，雖然快速可獲得之葡萄糖量(rapid available glucose, RAG)不變，緩慢可獲得之葡萄糖量(slowly available glucose, SAG )下降，但相對之抗解醣量增加，而達到提高甘藷粉機能性之目的。但是經過濕熱處理之紫色甘藷凍乾粉末之花青素含量皆顯著降低。選用台農66號天然甘藷澱粉製備抗解澱粉，其天然澱粉及其去支鏈澱粉分別含有76及72%之抗解澱粉(resistant starch, RS)，再經韌化或熱濕處理後，其RS為59-82%。經韌化處理後之去支鏈澱粉由天然甘藷澱粉之C-type轉變成B-type，而濕熱處理者則為C-type。	zh_TW
dc.description.abstract	There are three parts in this thesis. First, the anthocyanin content and DPPH radical scavenging of two Taiwanese purple sweet potatoes (TN73 and Taro-sp) were determined, as well as the anthocyanins’ structures of flesh and skin were identified by using the HPLC/MS-MS. Second, the four Taiwanese freeze-dried sweet potato flesh flour were prepared to be 10% suspension and treated at 40℃/5 min for the modification with endogenous enzymes (alpha and beta-amylase), followed by the additional treatment with 1, 2 and 3 temperature cycles (4℃/22h-30℃/2h). The annealed starch and flour will improve the functionality of sweet potato flour. Third, the sweet potato starch isolated from Taiwanese sweet potatos were be gelatinized and debranched with pullulanase to obtain the debranched starch (DS). The 17% DS suspension was then annealed either at 121℃/15 m-60℃/8h or at 121℃/15 m-60℃/8h-4℃/16h-60℃/8h, and 80% DS suspension was heat-moist treated at 121℃/2h to increase its resistant starch (RS) content. The in vitro digestibility was performed to evaluate the slowly available glucose (SAG) and the RS in hydrothermal treated sweet potato flour and starch, respectively. In addition, the swelling power and wide angle X-ray diffraction (XRD) analysis were carried out to study the changes of flour and starch structures. The anthocyanins content in skin and flesh of Taro-sp (93.0 and 514.5 mg/100 g (db)) were higher than TN73 (46.3 and 121.2 mg/100 g (db)). The DPPH radical scavenging capacity was well correlated to the anthocyanins content (R2=0.9971). There are 15 anthocyanins’ structures well identified, the aglycon of the anthocyanins was cyanidin or peonidin. After the temperature cycles treatment, the starch structure is getting to compact and order, resulting in the slow diffusion rate of water which restricts the amylase acting on the starch molecules. Although the amount of rapidly available glucose (RAG) did not change and SAG did decrease, as a result, the resistant carbohydrates were relatively increased. Through these processes, the functionality of sweet potato flour was improved. However, the anthocyanins were not stable during these processes. The RS% of TN66 native sweet potato starch, DS, and hydrothermal treated DS were 76, 72 and 59-82%, respectively. The annealed sweet potato starch had B-type crystal structure, while the native and heat-moist treated starch had C-type crystal structure.	en
dc.description.provenance	Made available in DSpace on 2021-06-08T04:15:07Z (GMT). No. of bitstreams: 1 ntu-99-R97623026-1.pdf: 2867414 bytes, checksum: 2e74f79fc901e8f744ea1db2ce7b31a4 (MD5) Previous issue date: 2010	en
dc.description.tableofcontents	目錄中文摘要 Ⅰ Abstract Ⅱ 目錄 Ⅲ 表目錄 Ⅶ 圖目錄 Ⅷ 第一章、前言 1 第二章、文獻整理 3 一、甘藷 3 （一）簡介 3 1.台農31號 3 2.台農66號 4 3.台農73號 4 4.芋心甘藷 4 （二）內生性酵素-澱粉酶 4 1. alpha-amylase 5 2. beta-amylase 6 （三）甘藷澱粉 7 1. 顆粒大小與外觀形態 7 2. 澱粉組成 7 3. 澱粉結構 8 4. 澱粉熱性質 9 5. 澱粉膨潤力 9 （四）營養價值 9 二、花青素 9 （一）簡介 9 （二）結構 10 （三）萃取與分析 11 （四）花青素之功能性 12 （五）生理活性 12 （六）抗氧化 12 （七）花青素的安定性 13 （八）飲食、吸收與代謝 13 三、快速消化、緩慢消化及抗解澱粉 14 （一）簡介與定義 14 1. 第一型抗解澱粉 14 2. 第二型抗解澱粉 15 3. 第三型抗解澱粉 15 4. 第四型抗解澱粉 15 （二）生成抗解澱粉之影響因子 15 （三）製備抗解澱粉之方法 16 1. 濕熱處理 16 2. 酵素處理 17 （四）生理活性 17 （五）應用 17 第三章、材料與方法 18 一、材料與試劑 18 （一）甘藷原料 18 （二）分析試劑 18 二、樣品製備 18 （一）甘藷粉之製備 18 （二）分離甘藷澱粉 18 （三）甘藷粉之濕熱處理 20 （四）去支鏈澱粉之製備 20 （五）去支鏈澱粉之濕熱處理 20 三、測定方法 20 （一）甘藷粉及澱粉之一般成分分析 20 1. 水分含量測定 21 2. 灰分測定 21 3. 粗脂肪含量 21 4. 粗蛋白含量 21 5. 膳食纖維含量 21 （二）總澱粉含量測定 22 （三）alpha-amylase含量測定 22 （四）beta-amylase含量測定 23 （五）糊液黏度測定 23 （六）花青素含量測定 24 （七）DPPH自由基清除能力 24 （八）花青素結構分析 24 （九）體外消化試驗(In vitro digestibility) 25 （十）膨潤力試驗 26 （十一）熱性質分析 26 （十二）掃描式電子顯微鏡觀察 26 （十三）直鏈澱粉含量測定 26 （十四）支鏈澱粉之鏈長分布 27 （十五）X-ray 繞射分析 27 （十六）澱粉顆粒之粒徑分布 27 （十七）麥芽糖測定 28 （十八）統計分析 28 第四章、結果與討論 29 一、兩種紫色苷藷之花青素含量和結構分析 29 （一）花青素含量與DPPH自由基清除能力 29 （二）花青素結構 30 二、四種國產苷藷之成分與性質比較 35 （一）甘藷塊根性質 35 （二）一般成分分析 36 （三）內生性酵素(alpha and beta-amylase)活性分析 38 （四）糊液黏度性質 39 （五）顯微結構 41 三、四種國產苷藷澱粉性質與結構比較 43 （一）澱粉顆粒之粒徑分布 43 （二）澱粉顆粒之外觀形態 44 （三）直鏈澱粉含量 46 （四）糊液黏度性質 46 （五）熱性質 47 （六）支鏈澱粉之鏈長分布 48 （七）X-ray 繞射分析結果 50 四、濕熱處理對甘藷藷肉凍乾粉末之影響 51 （一）麥芽糖含量變化 51 （二）體外消化(In vitro digestibility)試驗 52 （三）膨潤力變化 53 （四）花青素含量變化 53 五、濕熱處理對甘藷澱粉之影響 54 （一）體外消化(In vitro digestibility)試驗 54 （二）X-ray繞射分析 56 第五章、結論 58 第六章、參考文獻 60
dc.language.iso	zh-TW
dc.title	國產甘藷之花青素組成及抗解澱粉製備之研究	zh_TW
dc.title	Anthocyanins Analysis and Resistant Starch Preparation of Taiwanese Sweet Potatoes (Ipomoea batatas)	en
dc.type	Thesis
dc.date.schoolyear	98-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	李敏雄(Min-Hsiung Lee),林子清,賴麗旭,鄭統隆
dc.subject.keyword	甘藷(Ipomoea batatas),澱粉,抗解澱粉,濕熱處理,體外消化試驗,花青素,DPPH自由基清除能力,	zh_TW
dc.subject.keyword	sweet potato (Ipomoea batatas),starch,hydrothermal treatment,in vitro digestibility,resistant starch,anthocyanins,DPPH radical scavenging capacity,	en
dc.relation.page	64
dc.rights.note	未授權
dc.date.accepted	2010-08-10
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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