以釀酒酵母菌及米麴菌發酵仙鶴草生產具皮膚保健功能之產物

"Hsuan Ou-yang,"; 歐陽璇

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/15860

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔣丙煌(Been-Huang Chiang)
dc.contributor.author	"Hsuan Ou-yang,"	en
dc.contributor.author	歐陽璇	zh_TW
dc.date.accessioned	2021-06-07T17:53:53Z	-
dc.date.copyright	2012-08-27
dc.date.issued	2012
dc.date.submitted	2012-08-17
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/15860	-
dc.description.abstract	皮膚是人體最大的器官，包覆在人體的表面，因此當皮膚因老化而產生變化，最容易被觀察到。隨著預防老化觀念的提升，對於皮膚保健相關的化妝保養品市場也愈來愈興旺。本實驗室先前研究發現，在清酒的發酵過程中加入仙鶴草一起發酵，可以減低仙鶴草對於皮膚纖維母細胞的毒性，對於酪胺酸酶、基質金屬蛋白酶(matrix metalloproteinases，MMP)活性的抑制率雖較乙醇萃取物低，但仍有效果，且有促進type I procollagen生成之功效。唯發酵過程繁複不易生產。故本實驗乃利用清酒製造過程中所使用的兩株微生物Aspergillus oryzae及Saccharomyces cerevisiae發酵仙鶴草乙醇及熱水萃取物，期望能簡化發酵過程，同時，發酵產物對皮膚保健有相當或更好的效果。實驗結果發現，仙鶴草乙醇及熱水萃取物經發酵後在500 μg/ml下皆不具細胞毒性，還可促進纖維母細胞的增生及保護UVA對細胞的傷害，但對於type I procollagen的生成仍有抑制的作用。而在酵素的抑制上，以酵母菌發酵仙鶴草乙醇萃取物有較佳的效果，在500 μg/ml濃度下酪胺酸酶及彈力蛋白酶的抑制率分別為18-37%及13-30%；在400 μg/ml濃度下膠原蛋白酶和明膠蛋白酶抑制率分別為53-88%及56-73%。雖然酵母菌發酵仙鶴草乙醇萃取物對於酪胺酸酶及基質金屬蛋白酶都有不錯的抑制效果，但其發酵液同時也會抑制纖維母細胞type I procollagen生成，所以酵母菌發酵仙鶴草乙醇萃取物之發酵液尚不能作為全面性的皮膚保健產品，而簡化的發酵流程仍需進一步修正。	zh_TW
dc.description.abstract	Skin is the largest organ and outer covering of our body. So it can be easily observed when the aging process makes differents on skin. With the promotion of anti-aging concepts, the skin care related market blossoms. In our previous study we found that adding Agimonia pilosa during rice wine fermentation can reduce the cytotoxicity of skin fibroblasts and increase the production of type I procollagen. Although the inhibition of tyrosinase and matrix metalloproteinases (MMPs) is not very high, it still has some effects. The problem is the process of fermentation is too complicated and time consuming. Therefore, the objective of this research is to simplify fermentation process and to produce skin-care functional product by the fermentation of Agimonia pilosa using Saccharomyce cerevisiea and Aspergillus oryzae. Results show that at the dosage of 500 μg/ml, the skin fibroblast can proliferate by the treatment of either of the fermentation product utilizing ethanol or hot water extract of A. pilosa as cultivation medium, and they can also protect cells from UVA damage. However, the samples derived from ethanol or hot water extract of A. pilosa would inhibit the production of type I procollagen. Compared with all samples on the inhibition of skin related enzymes, fermentations of ethanol extract of Agrimoina pilosa by Saccharomyces cerevisiae (ES samples) show the best result. The inhibition of tyrosinase and elastase are 18-37% and 13-30% under the concentration of 500 μg/ml, and the inhibition of collagenase and gelatinase are 53-88% and 56-73% under the concentration of 400 μg/ml. Although the ES samples have tyrosinase and MMPs inhibition and antioxidative activity, they can also inhibit type I procollagen production. Because of failure on promoting type I procollagen, the fermentations can not be omnibearing skin-care products. And the procedures of fermenttion should be further improved.	en
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dc.description.tableofcontents	目錄中文摘要 I 圖次 V 表次 VI 第一章緒論 1 第二章文獻回顧 2 一、人類皮膚 2 (一)人類皮膚的功能與結構 2 (二)皮膚老化 4 (三)黑色素生成的機制 10 二、仙鶴草 12 (一)仙鶴草簡介 12 (二)仙鶴草成分 12 (三)仙鶴草的生理活性 13 (四)仙鶴草與皮膚保健相關活性成分 14 三、中草藥發酵 15 四、發酵菌種 15 (一)米麴菌 15 (二)酵母菌 16 第三章實驗目的與架構 17 一、研究目的 17 二、實驗架構 18 (一)以Saccharomyces cerevisiae及Aspergillus oryzae 發酵仙鶴草萃取物 18 (二)發酵仙鶴草萃取物皮膚保健效果分析 19 第四章材料與方法 20 一、實驗材料 20 (一)實驗原料 20 (二)實驗菌種 20 (三)實驗細胞株 20 (四)實驗藥品與試劑 20 (五)實驗器材與儀器 22 二、實驗方法 23 (一)仙鶴草萃取 23 (二)微生物發酵 23 (三)細胞實驗 24 (四)酵素活性抑制能力分析 29 (五)清除抗氧化能力分析 31 (六)成分分析 31 (七)統計分析 32 第五章結果與討論 33 一、成分分析 33 (一)總多酚含量分析 33 (二)總類黃酮含量分析 33 二、酵素活性抑制能力分析 34 (一)酪胺酸酶活性抑制分析 34 (二)基質金屬蛋白酶活性抑制分析 35 三、細胞實驗 38 (一)皮膚纖維母細胞(CCD-966SK)毒性及增生試驗 38 (二)第一型原膠原蛋白( type I procollagne, PIP)含量分析 39 (三)清除細胞內由UVA誘導產生ROS之能力分析 41 四、抗氧化能力分析 42 清除DPPH能力分析 42 第六章結論 96 第七章參考文獻 98 圖次圖2- 1、皮膚構造圖 2 圖2- 2、為自然老化及光老化的可能機制圖。 5 圖2- 3、UV照射對於皮膚的影響 7 圖2- 4、光老化下皺紋的形成 8 圖2- 5、MMPs在皮膚老化中的角色 10 圖2- 6、黑色素的生成途徑 11 表次圖5- 1 30℃下發酵仙鶴草萃取物總多酚含量 44 圖5- 2 30℃下發酵仙鶴草萃取物總類黃酮含量 45 圖5- 3釀酒酵母發酵仙鶴草水萃物對酪胺酸酶的抑制能力 46 圖5- 4 米麴菌發酵仙鶴水萃物對酪胺酸酶的抑制能力 47 圖5- 5釀酒酵母和米麴菌共發酵仙鶴水萃物對酪胺酸酶的抑制能力 48 圖5- 6釀酒酵母發酵仙鶴乙醇萃取物對酪胺酸酶的抑制能力 49 圖5- 7米麴菌發酵仙鶴乙醇萃取物對酪胺酸酶的抑制能力 50 圖5- 8釀酒酵母和米麴菌共發酵仙鶴乙醇萃取物對酪胺酸酶的抑制能力 51 圖5- 9釀酒酵母發酵仙鶴草水萃物對明膠蛋白酶的抑制能力 52 圖5- 10米麴菌發酵仙鶴水萃物對明膠蛋白酶的抑制能力 53 圖5- 11釀酒酵母和米麴菌共發酵仙鶴水萃物對明膠蛋白酶的抑制能力 54 圖5- 12釀酒酵母發酵仙鶴乙醇萃取物對明膠蛋白酶的抑制能力 55 圖5- 13米麴菌發酵仙鶴乙醇萃取物對明膠蛋白酶的抑制能力 56 圖5- 14釀酒酵母和米麴菌共發酵仙鶴乙醇萃取物對明膠蛋白酶的抑制能力 57 圖5- 15釀酒酵母發酵仙鶴草水萃物對膠原蛋白酶的抑制能力 58 圖5- 16米麴菌發酵仙鶴水萃物對膠原蛋白酶的抑制能力 59 圖5- 17釀酒酵母和米麴菌共發酵仙鶴水萃物對膠原蛋白酶的抑制能力 60 圖5- 18釀酒酵母發酵仙鶴乙醇萃取物對膠原蛋白酶的抑制能力 61 圖5- 19米麴菌發酵仙鶴乙醇萃取物對膠原蛋白酶的抑制能力 62 圖5- 20釀酒酵母和米麴菌共發酵仙鶴乙醇萃取物對膠原蛋白酶的抑制能力 63 圖5- 21釀酒酵母發酵仙鶴草水萃物對彈力蛋白酶的抑制能力 64 圖5- 22米麴菌發酵仙鶴水萃物對彈力蛋白酶的抑制能力 65 圖5- 23釀酒酵母和米麴菌共發酵仙鶴水萃物對彈力蛋白酶的抑制能力 66 圖5- 24釀酒酵母發酵仙鶴乙醇萃取物對彈力蛋白酶的抑制能力 67 圖5- 25米麴菌發酵仙鶴乙醇萃取物對彈力蛋白酶的抑制能力 68 圖5- 26釀酒酵母和米麴菌共發酵仙鶴乙醇萃取物對彈力蛋白酶的抑制能力 69 圖5- 27釀酒酵母發酵仙鶴草水萃取物對人類纖維母細胞之毒性測試 70 圖5- 28米麴菌發酵仙鶴草水萃取物對人類纖維母細胞之毒性測試 71 圖5- 29釀酒酵母和米麴菌共發酵仙鶴草水萃取物對人類纖維母細胞之毒性測試 72 圖5- 30釀酒酵母發酵仙鶴草乙醇萃取物對人類纖維母細胞之毒性測試 73 圖5- 31米麴菌發酵仙鶴草乙醇萃取物對人類纖維母細胞之毒性測試 74 圖5- 32釀酒酵母和米麴菌共發酵仙鶴草乙醇萃取物對人類纖維母細胞之毒性測試 75 圖5- 33釀酒酵母發酵仙鶴草水萃物對人類纖維母細胞生成type I procollagen之能力 76 圖5- 34米麴菌發酵仙鶴草水萃物對人類纖維母細胞生成type I procollagen之能力 77 圖5- 35釀酒酵母和米麴菌共發酵仙鶴草水萃物對人類纖維母細胞生成type I procollagen之能力 78 圖5- 36釀酒酵母發酵仙鶴草乙醇萃取物對人類纖維母細胞生成type I procollagen之能力 79 圖5- 37米麴菌發酵仙鶴草乙醇萃取物對人類纖維母細胞生成type I procollagen之能力 80 圖5- 38釀酒酵母和米麴菌共發酵仙鶴草乙醇萃取物對人類纖維母細胞生成type I procollagen之能力 81 圖5- 39釀酒酵母發酵仙鶴草水萃物對人類纖維母細胞照射UVA後之細胞存活測試 82 圖5- 40米麴菌發酵仙鶴水萃物對人類纖維母細胞照射UVA後之細胞存活測試 83 圖5- 41釀酒酵母和米麴菌共發酵仙鶴水萃物對人類纖維母細胞照射UVA後之細胞存活測試 84 圖5- 42釀酒酵母發酵仙鶴乙醇萃取物對人類纖維母細胞照射UVA後之細胞存活測試 85 圖5- 43米麴菌發酵仙鶴乙醇萃取物對人類纖維母細胞照射UV後之細胞存活測試 86 圖5- 44釀酒酵母和米麴菌共發酵仙鶴乙醇萃取物對人類纖維母細胞照射UV後之細胞存活測試 87 圖5- 45釀酒酵母發酵仙鶴水萃物對人類纖維母細胞照射UVA後之ROS生成量 88 圖5- 46米麴菌發酵仙鶴水萃物對人類纖維母細胞照射UVA後之ROS生成量 89 圖5- 47釀酒酵母和米麴菌共發酵仙鶴水萃物對人類纖維母細胞照射UVA後之ROS生成量 90 圖5- 48釀酒酵母發酵仙鶴乙醇萃取物對人類纖維母細胞照射UV後之ROS生成量 91 圖5- 49米麴菌發酵仙鶴乙醇萃取物對人類纖維母細胞照射UV後之ROS生成量 92 圖5- 50釀酒酵母和米麴菌共發酵仙鶴乙醇萃取物對人類纖維母細胞照射UV後之ROS生成量 93 圖5- 51發酵仙鶴草水萃物清除DPPH能力 94 圖5- 52發酵仙鶴乙醇萃取物清除DPPH能力 95
dc.language.iso	zh-TW
dc.title	以釀酒酵母菌及米麴菌發酵仙鶴草生產具皮膚保健功能之產物	zh_TW
dc.title	Fermentation of Agrimonia pilosa by Saccharomyces cerevisiea and Aspergillus oryzae to manufacture functional products for human skin	en
dc.type	Thesis
dc.date.schoolyear	100-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	潘子明(TZU-MING PAN),吳瑞碧
dc.subject.keyword	仙鶴草,發酵,釀酒酵母,米麴菌,纖維母細胞,Type I procollagen,酪胺酸&#37238,基質金屬蛋白&#37238,	zh_TW
dc.subject.keyword	Agrimonia pilosa,fermentation,Saccharomyces cerevisiae,Aspergillus oryzae,fibroblast,Type I procollagen,tyrosinase,MMPs,	en
dc.relation.page	102
dc.rights.note	未授權
dc.date.accepted	2012-08-17
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	食品科技研究所	zh_TW
顯示於系所單位：	食品科技研究所

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