以成分分析鑒別燕窩之真偽

Ching-hsin Tung; 董靜馨

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34117

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張鴻民(Hung-Min Chang),吳瑞碧(James Swi-Bea Wu)
dc.contributor.author	Ching-hsin Tung	en
dc.contributor.author	董靜馨	zh_TW
dc.date.accessioned	2021-06-13T05:54:53Z	-
dc.date.available	2011-07-12
dc.date.copyright	2006-07-12
dc.date.issued	2006
dc.date.submitted	2006-06-30
dc.identifier.citation	1.經濟部中央標準局。1986。食品中粗蛋白質之檢驗法。中國國家標準。總號 5035，類號N6116。 2.新文豐出版公司編輯（1981-1982）新編中藥大辭典，第4892-4893頁。 3.中國中藥資源志要。1994。中國藥材公司。科學出版社。北京。 4.藥材學。1960。南京藥學院藥材學教研組。人民衛生出版社。北京。 5.端木梁，李建雄，翁郁嘉，黃淑姿。2002。生物化學下冊（第二版）。藝軒圖書出版社印行。 6.黃蔭樨，翁鵬傑，彭俊明，陳玉燕，許碧蘭，黃東裕，盧虹佑。2000。哈伯氏生物化學上冊。藝軒圖書出版社印行。 7.王求淦。1991。燕窩的真偽鑒別。中國中藥雜誌。16（6）：398。 8.文惠玲，汪治，申欣。1996。3種偽品燕窩的鑒別。中國中藥雜誌。21（10）：586-587。 9.李曼。1996。三種偽品燕窩的鑒別。基層中藥雜誌。10（2）：15。 10.林麗華。2003。以化學和免疫化學的方法探討波羅蜜凝集素和燕窩蛋白的結合性質。長庚大學醫學院天然藥物研究所。碩士論文。 11.胡雅妮，李峰，康廷國。2003。燕窩的研究發展。中國中藥雜誌。28(11) : 1003-1005。 12.胡國昌，陳文銳，陳捷，郭長城。1996。燕窩及其制品的檢測方法。食品科學。17（11）：47-50。 13.黃又游。1999。燕窩及偽充品的鑒別。中藥材。22（8）：432。 14.張璐。1996。本經逢原。第1版：239。中國中醫藥發行。北京市。 15.游宜屏。2003。以毛細管電泳研究寡唾液酸的內酯化反應與水解反應。國防醫學院博士論文。 16.趙守訓，黃泰康，丁志遵。1997。中藥辭海(第三卷)。中國醫藥科技出版社。北京。 17.劉惠娟，徐璐珊，徐紀文。1991。燕窩及其摻偽品的鑑定研究。中草藥。22（9）：413-416。 18.蔣华嵩。2000。真假燕窩的鑒別。中草藥。31（1）：58。 19.謝宗萬，余友芩。1996。全國中草藥名鑒(下冊)。人民衛生出版社。北京。 20.Analysis of carbohydrates by high performance anion exchange chromatography with pulsed amperometric detection (HPAE-PAD). Dionex. Technical Note 20. 21.Angata T and Varki A. 2002. Chemical diversity in the sialic acids and related alpha-keto acids, an evolutionary perspective. Chem. Rev. 102: 439–469. 22.Beckerman primer。1999。 23.Charles J, Helen C and Baiming X. 2001. Determination of sialic acids by liquid chromatography–mass spectrometry. J. Chromatogr A. 913 :365– 370 24.Chen H, Wang Z, Sun Z, Kim EJ and Yarema KJ. 2004. Mammalian Glycosylation: An Overview of carbohydrate biosynthesis. Handbook of Carbohydrate Engineering. 25.Chou MY, Li SC and Li YT. 1996. Cloning and expression of sialidase L, a NeuAcalpha2→3Gal-specific sialidase from the leech, Macro- bdella decora. J. Biol. Chem. 271:19219.-19214. 26.Chou HH, Hayakawa T, Diaz S, Krings M, Indriati E, Leakey M, Paabo, S, Satta Y, Takahata N and Varki A. 2002. Inactivation of CMP–N-acetylneuraminic acid hydroxylase occurred prior to brain expansion during human evolution. Proc. Natl. Acad. Sci. USA 99, 11736–11741. 27.Chou SS, Su SC, Shiau HW, Hwang DF, Yu PC and Lee SC. 1998. Protein and amino acid profiles in natural and artificial shark fins using capillary alactrophoresis. J. Food Sci. 63:782-784. 28.Corfield AP, Schauer R, 1982. Occurrence of sialic acids. In: Schauer, R. (Ed.), Sialic Acids—Chemistry, Metabolism and Function. Springer Verlag Wien, New York, pp. 5–50. 29.Daotian F and Roger A. 1995. Monosaccharide composition analysis of oligosaccharide and glycoproteins by High-performance liquide chromatography. Anal Biochem. 227:377-384. 30.Schauer R and Kamerling JP. 1997. Glycosylation:An overview of carbohydrate biosynthesis. Chemistry, biochemistry and biology of sialic acids. In: Montreuil J, Vliegenthart JFG, Schachter H. (Eds.), Glycoproteins II. Elsevier Science AV, Amsterdam pp. 243–402. 31.Grossmann PD, Colburn JC, Lauer HH, Nielsen RG, Riggin RM, Sittampalam GS and Rickard EC. 1989. Application of free-solution capillary electrophoresis to the analytical scale separation of proteins and peptides. Anal Chem. 61:1186-1194. 32.Hanisch FG and Uhlenbruck G. 1984. Structural studies on O- and N-glycosidically linked carbohydrate chains on Collcalia mucin. Hoppe-Setler’s Z. Physiol Chem. Bd.365:119-128. 33.Kathhan RK and Weeks DI. 1969. Structure studies of collocalia mucoid. Arch biochem biophys. 134:572-576. 34.Kakehi K and Honda S.1996. Analysis of glycoproteins, glycopeptides and glycoproteinderived oligosaccharides by high-performance capillary electrophoresis. J. Chromatogr., 720 : 377-393. 35.Kelm S and Schauer R. 1997. Sialic acids in molecular and cellular recognition. Int. Rev. Cytol. 175: 137–240. 36.Kilar F and Hjerten S. 1989. Separation of the human transferrin isoforms by carrier-free high-performance zone electrophoresis and isoelectric focusing. J Chromatogr. 480:351-357. 37.KÖttgen E, Fabricius H A, Stahn R and Gerok W. 1981. T-lymphocyte activation. Studies on the function of mediator proteins. Klin. Wochenschr. 59: 669-674. 38.Landers JP, Oda RP, Madden BJ and Spelsberg TC. 1992.High- performance capillary electrophoresis of glycoproteins: the use of modifiers of electroosmotic flow for analysis of microheterogeneity. Anal Biochem. 205:115-124. 39.Malykh YN, Schauer R, Shaw L. 2001a. N-Glycolylneuraminic acid in human tumours. Biochimie 83:623–634. 40.Muchmore EA. 2001. Chimpanzee models for human disease and immunobiology. Immunol. Rev. 183: 86–93. 41.Ng MH, Chan KH, Kong YC.1986. Potentiation of mitogenic response by extracts of the swiftlet’s (Collocalia) Nest. Biochem int. 13(3):521-531. 42.Negro, A., Garbisa, S., Gotte, L. and Spina, M. 1987. The use of reverse-phase high-performance liquid chromatography and precolumn derivatization with dansyl chloride for quantitation of specific amino acids in collagen and elastin. Anal. Biochem. 160: 39-46. 43.Rudd PM, Scragg IG, Coghill E and Dwek RA. 1992. Separation and analysis of the glycoform populations of ribonuclease B using capillary electrophoresis. Glycoconj J. 9:86-91. 44.Rudd PM, Joao HC, Coghill E, Saunders MR, Opdenakker G and Dwek RA. 1994. Glycoforms modify the dynamic stability and functional activity of an enzyme. Biochemistry, 33:17-22. 45.Schauer R.1982. Sialic acids: chemistry, metabolism and function, Cell Biology Monographs, vol. 10, Springer-Verlag, New York. 46.Schauer R. 1985. Sialic acids and their role as biological masks. Trends Biochem. Sci. 10: 357-360. 47.Schauer R, Kelm S, Reuter G, Roggentin P and Shaw L. 1995 Biochemistry and role of sialic acids. In: Biology of the Sialic Aicds, (Rosenberg, A. ed.), pp. 7-67, Plenum: New York. 48.Schauer R and Kamerling JP. 1997.Chemistry, Biochemistry and Biology of Sialic Acids, in Montreuil, J., Vliegenthart, J. F. G. and Schachter, H. (Eds.), Glycoproteins II, in Neuberger A van Deenen LL M. (Eds.). New Comprehensive Biochemistry. 29B. Elsevier, Amsterdam. 243-402. 49.Schauer, R., 2000. Achievements and challenges of sialic acid research. Glycoconjugate J. 17, 485–499. 50.Schauer R.2004. Sialic acids: fascinating sugars in higher animals and man. Zoology. 107: 49–64. 51.Schultze B, Krempl C, Ballesteros ML, Shaw L, Schauer R, Enjuanes L and Herrler G. 1996. Transmissible gastroenteritis coronavirus, but not the related porcine respiratory coronavirus has a sialic acid (N-glycolylneuraminic acid) binding activity. J. Virol. 70: 5634–5637. 52.Strecker G, Wieruszeski JM, Cuvillier O, Michalski JC and Montreuil J. 1992. 1H and 13C-NMR assignments for sialylated oligosaccharide- alditols to mucins. Study of thirteen components from hen ovomucin and sallow nest mucin. Chichim. 74:39-52. 53.Su SC, Yu PC, Liu CH, Shiau HW, Lee SC, Chou SS.1998. Application of capillary electrophoresis for identification of the authenticity of bird's nests. J Food Drug Anal. 6:455-464. 54.Tangvoranuntakul P, Gagneux P, Diaz S, Bardor M, Varki N, Varki A and Muchmore E. 2003. Human uptake and incorporation of an immuno- genic nonhuman dietary sialic acid. Proc. Natl. Acad. Sci. USA 100, 12045–12050. 55.Tran A, Park S, Lisi PJ, Huynh OT, Ryall RR and Lane PA.1991. Separation of carbohydrate-mediated microheterogeneity of recombinant human erythropoietin by free solution capillary electrophoresis. Effects of pH, buffer type and organic additives. J Chromatogr. 542: 459-471. 56.Varki, A. 1992. Diversity in the sialic acids. Glycobiology 2: 25–40. 57.Varki NM, Cheriyan M. Brinkman-Van der Linden ECM, Gagneux P and Varki A. 2001. Upregulation of epithelial and erythrocyte cell surface expression of a2-6 linked sialic acids was a specific change during human evolution. Glycobiology 11: 883. 58.Watson E and Yao F. 1993. Capillary electrophoretic separation of human recombinant erythropoietin (r-HuEPO) glycoforms. Anal. Biochem. 210(2):389-393. 59.Wieruszeski JM, Michalski JC, Montreuil J and Strecker G. 1987. Struture of the monosialyl oligosaccharides derivel from salivary gland mucin glycoproteins of Chinese Swiftlet.(Genus Collcalia). Biol.Chem. 259:9051-9058. 60.Wu SL, Teshima G, Cacial J. and Hancock WS. 1990. Use of high-performance capillary electrophoresis to monitor charge heterogeneity in recombinant-DNA derived proteins. J Chromatogr. 516:115-122. 61.Zanetta JP, Pons A, Iwersen M, Mariller C, Leroy Y, Timmerman Pand Schauer R. 2001. Diversity of sialic acids revealed using gas chromato- graphy/mass spectrometry of heptafluorobutyrate derivatives. Glycobiology 11: 663–676.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34117	-
dc.description.abstract	為瞭解市售燕窩品質，本研究利用燕窩成分特性鑒別燕窩之真偽。以顯微鏡鑒別燕窩形態，發現燕窩在顯微鏡下呈現無色透明、長方形或不規則的碎片，在表面及斷面處有細密的平行紋理，有的表面密佈細小圓孔或細顆粒狀物。市售乾品燕窩，粗蛋白質含量介於 52.1∼63.4%。燕窩乾燥粉末經酸水解，dansyl chloride 衍生化後，以毛細管電泳分析燕窩胺基酸組成。燕窩乾燥粉末以10％ tetramethyl- ammonium hydroxide 溶液70℃ 加熱溶解，以毛細管電泳分析燕窩及其摻偽品豬皮及魚膘的蛋白質指紋圖譜，乾品燕窩在15-23分鐘遷移時間區間含有六根特定波峰，與燕窩之摻偽品豬皮及魚膘有明顯不同，可有效鑒別燕窩真偽。利用 SDS 膠體電泳分析蛋白質分子量，以Bio-safe Coomassie stain 及PAS (periodic acid stain) 醣蛋白染色法進行染色，發現燕窩在SDS 膠體電泳呈現6∼7條譜帶，而且幾乎均是醣蛋白。燕窩乾燥粉末以三氟醋酸（trifluoroacetic acid）將唾液酸、中性糖及糖胺水解後，以高效離子液相層析儀-脈衝式電流檢出器(High performance ion liquid chromatography with pulsed amperometric detector, HPAE-PAD) 分析燕窩中醣類的組成，燕窩醣蛋白之醣類組成平均含量， Fuc 0.44%， Rha 0.20%， GalN 4.2%， GlcN 5.3%， Gal 5.0% ，Man 0.75% 及 N-acetylnuraminic acid (Neu5Ac) 11.4%。本研究利用唾液酸換算冰糖燕窩產品中燕窩的含量，以Neu5Ac/GalN比值表示冰糖燕窩產品的品質。對照組乾品燕窩之 Neu5Ac/GalN比值為2.3-3.0，20件冰糖燕窩產品之Neu5Ac/GalN比值為0.03∼3.0。	zh_TW
dc.description.abstract	In order to gain insights into the qualities of bird’s nests found in local market nowadays, the components of various bird’s nest samples were used in this study to determine their authenticity. Optical microscopy of various types of dried bird’s nest samples showed that they are colorless and transparent, and their shapes are rectangular or irregular fragments. The cross-section profile of bird’s nets has closely-spaced parallel texture, and some have densely-distributed tiny round holes or tiny granulates on their surface. Commercially available dried bird’s nests typically contain 52.1~63.4% of crude protein. Dried bird’s nest powder was easily hydrolyzed in acid. The protein hydrolysate were then derivatized with dansyl chloride, and analyzed by capillary eletrophoresis (CE). Dried bird’s nest powder was dissolved in 10% tetramethyl- ammonium hydroxide solution, heated at 70℃, and analyzed by CE. Six characteristic peaks of major protein components of bird’s nest were found in the interval of 15-23 min migration time, whereas the adulterant pork skin and isinglass did not show these six peaks. Thus, CE analysis of protein profile was found to be an efficient technique to determine the bird’s nest authenticity. Protein molecular weight was analyzed by using SDS PAGE, where gels were stained by the Bio-safe Coomassie stain and PAS (periodic acid stain). There were found 6~7 bands in the SDS PAGE for bird’s nests; moreover, most of them were glycoproteins. Trifluoroacetic acid was used to hydrolyze sialic acid, neutralsugars and aminosugars of bird’s nests, and then the hydrolysates were analyzed by high performance ion liquid chromatography with pulsed amperometric detector (HPAE-PAD). The results showed that the glycoproteins of bird’s nests contain 0.44% of fucose, 0.2% rhamnose, 4.2% galactosamine, 5.3% glucosamine, 5.0% galactose, 0.75% mannose and 11.4% N-acetylnuraminic acid(Neu5Ac). In this research, bird’s nest content of “bird’s nest in rock sugar syrup” products was assessed by converting it into its sialic acid equivalent. The Neu5Ac/GalN ratio signifies quality of the “bird’s nest in rock sugar syrup” products. The Neu5Ac/GalN ratio of control bird’s nest was 2.3-3.0, while for 20 specimens of “bird’s nests in rock sugar syrup”, Neu5Ac/GalN ratios ranged from 0.03 to 3.0.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T05:54:53Z (GMT). No. of bitstreams: 1 ntu-95-R93641035-1.pdf: 4775338 bytes, checksum: c14f4cf58e2d19e492e5ce0a482c50c7 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	中文摘要 ……………………………………………………………Ⅰ 英文摘要 ……………………………………………………………Ⅱ. 目錄 …………………………………………………………………Ⅳ 表次 …………………………………………………………………Ⅶ 圖次 …………………………………………………………………ⅠⅩ 常用縮寫 …………………………………………………………… ⅩⅠⅠ 第一章文獻整理 ……………………………………………………1 壹、燕窩……………………………………………………………1 一、燕窩之醫藥性 ……………………………………………1 二、燕窩產地來源 ……………………………………………2 三、商品規格 …………………………………………………4 四、燕窩醣蛋白的末端寡醣結構分析 ………………………6 五、燕窩攙偽品 ………………………………………………8 貳、醣蛋白 ………………………………………………………10 一、醣蛋白的功能………………………………………… 10 二、醣蛋白所含有糖的種類…………………………………12 三、醣蛋白的分類……………………………………………15 參、唾液酸 ………………………………………………………23 一、唾液酸的多樣性…………………………………………23 二、唾液酸在生理上的意義…………………………………25 三、唾液酸的代謝 …………………………………………26 四、人類與其他動物唾液酸表現的不同 …………………28 肆、醣蛋白分析 …………………………………………………30 一、毛細管區帶電泳法………………………………………31 二、微胞電動毛細管層析法…………………………………31 三、毛細管凝膠電泳法………………………………………32 四、毛細管等電聚焦法………………………………………32 五、以毛細管電泳分析蛋白質指紋圖譜……………………33 六、唾液酸的定量分析………………………………………35 研究目的 ……………………………………………………………36 第二章、材料與方法………………………………………………37 壹、實驗材料 ……………………………………………………37 貳、化學試藥及器材 ……………………………………………37 一、顯微鏡鑑別………………………………………………37 二、粗蛋白質分析……………………………………………37 三、胺基酸分析………………………………………………37 四、毛細管電泳分析蛋白質指紋圖譜………………………38 五、 SDS膠體電泳分析 ………………………………………38 六、糖類含量之測定…………………………………………39 參、實驗方法 ……………………………………………………41 一、檢體前處理 ……………………………………………41 二、顯微鏡鑑別 ……………………………………………41 三、粗蛋白質分析 …………………………………………41 四、胺基酸分析 ……………………………………………42 五、毛細管電泳分析蛋白質指紋圖譜 ……………………45 六、 SDS膠體電泳分析 ……………………………………46 七、 HPAE-PAD測定中性糖及糖胺含量……………………51 八、唾液酸測定……………………………………………53 第三章、結果與討論………………………………………………55 壹、顯微鏡鑑別…………………………………………………55 貳、粗蛋白質分析………………………………………………56 參、胺基酸分析…………………………………………………57 肆、毛細管電泳分析蛋白質指紋圖譜…………………………59 伍、 SDS 膠體電泳………………………………………………60 陸、中性糖及糖胺的含量測定…………………………………62 柒、唾液酸測定…………………………………………………64 捌、冰糖燕窩中燕窩含量計算…………………………………65 第四章、結論 ……………………………………………………66 第五章、參考文獻…………………………………………………116 表次表1-1常見燕窩的來源之金絲燕之品種……………………………3 表1-2 醣蛋白的功能 …………………………………………………11 表1-3 醣蛋白的寡醣鏈所具有的功能 ………………………………12 表1-4 出現於人體醣蛋白的主要單醣 ………………………………13 表1-5 醣蛋白的分類 …………………………………………………15 表1-6 參與單醣進程與碳水化合物組合之酵素 ……………………19 表1-7 毛細管電泳之應用模式 ………………………………………30 表1-8 以毛細管電泳分離醣蛋白之條件一覽表 ……………………34 表2-1 12件乾品燕窩來源 …………………………………………68 表2-1 20件冰糖燕窩來源 …………………………………………69 表3-1燕窩及摻偽品的顯微鏡鑑別……………………………………70 表3-2 比較乾品燕窩粗蛋白質之含量 ………………………………71 表3-3比較冰糖燕窩粗蛋白質之含量…………………………………72 表3-4 冰糖燕窩的總固形物、粗蛋白質、價格及真偽…………………73 表3-5 以Dansyl chloride 衍生化胺基酸在毛細管電泳下遷移時間 74 表3-6 乾品燕窩、木耳和豬皮中粗蛋白含量與Val, Pro, Phe, Tyr及 Hyp比值 …………………………………………………………75 表 3-7 燕窩蛋白質在毛細管電泳下遷移時間(214 nm) ………………76 表 3-8 燕窩蛋白質在毛細管電泳下遷移時間(280 nm) ………………76 表 3-9 乾品燕窩之中性糖及糖胺含量比較 ……………………………77 表 3-10 摻偽品之中性糖及糖胺含量比較………………………………78 表 3-11 冰糖燕窩之中性糖及糖胺含量比較……………………………79 表 3-12乾品燕窩之唾液酸含量比較 ……………………………… 80 表 3-13冰糖燕窩之唾液酸含量比較 ……………………………… 81 表 4-1燕窩成分的各種檢驗方法之特性比較 …………………… 82 圖次圖1-1常見燕窩商品規格.………………………………………………5 圖1-2 金絲燕屬黏蛋白寡醣-醛糖醇結構 ……………………………6 圖1-3 哺乳動物的醣蛋白中常見單醣的化學結構 …………………14 圖 1-4 O-連醣蛋白生合成 “核心結構” 之途徑 ………………17 圖 1-5 N-連醣蛋白生合成途徑………………………………………18 圖 1-6 自然產生的唾液酸家族………………………………………25 圖 1-7 唾液酸生合成簡圖……………………………………………26 圖3-1 乾品燕窩在顯微鏡下的形態(BN.1) …………………………83 圖3-2乾品燕窩在顯微鏡下的形態(BN.4) …………………………83 圖3-3乾品燕窩在顯微鏡下的形態(BN.5) …………………………84 圖3-4乾品燕窩在顯微鏡下的形態(CP.2) …………………………84 圖3-5 豬皮在顯微鏡下的形態 ………………………………………85 圖3-6 魚膘在顯微鏡下的形態 ………………………………………85 圖3-7 木耳在顯微鏡下的形態 ………………………………………86 圖3-8 洋菜在顯微鏡下的形態 ………………………………………86 圖3-9海藻酸鈉在顯微鏡下的形態……………………………………87 圖3-10燕石在顯微鏡下的形態 ………………………………………87 圖3-11 冰糖燕窩在顯微鏡下的形態(S.1) …………………………88 圖3-12 冰糖燕窩在顯微鏡下的形態(S.2) …………………………88 圖3-13 冰糖燕窩在顯微鏡下的形態(S.5) …………………………89 圖3-14 Dansyl chloride 衍生化胺基酸之毛細管電泳圖譜……90 圖3-15 水解乾品燕窩經Dansyl chloride 衍生化胺基酸之毛細管電泳圖譜（BN.1） …………………………………………………………91 圖3-16 水解豬皮經Dansyl chloride衍生化胺基酸之毛細管電泳圖譜 ……………………………………………………………………92 圖3-17 水解魚膘經Dansyl chloride衍生化胺基酸之毛細管電泳圖譜 …………………………………………………………………………93 圖3-18 水解木耳經Dansyl chloride衍生化胺基酸之毛細管電泳圖譜 …………………………………………………………………………94 圖3-19 Dansyl chloride 衍生化胺基酸之毛細管電泳圖譜(A)洋菜(B)海藻酸鈉(C)冰糖燕窩（S.3） …………………………………95 圖3-20 Dansyl chloride 衍生化胺基酸之毛細管電泳圖譜(A)乾品燕窩（BN.1）(B)冰糖燕窩（S.1）…………………………………96 圖3-21 Dansyl chloride 衍生化胺基酸之毛細管電泳圖譜(A)豬皮(B)冰糖燕窩（S.5）…………………………………………………97 圖3-22 Dansyl chloride 衍生化胺基酸之毛細管電泳圖譜(A)木耳(B)冰糖燕窩（S.15） ………………………………………………98 圖3-23 乾品燕窩蛋白質之毛細管電泳圖譜（BN.1）(214 nm) …99 圖3-24蛋白質之毛細管電泳圖譜(A)乾品燕窩（BN.1）(B) 魚膘(C) 豬皮(214 nm) ………………………………………………………100 圖3-25乾品燕窩蛋白質之毛細管電泳圖譜(BN.1) (280 nm) ……101 圖3-26蛋白質之毛細管電泳圖譜(A)乾品燕窩（BN.1）(B) 魚膘(C) 豬皮 (280 nm)………………………………………………………102 圖3-27蛋白質之毛細管電泳圖譜(A)乾品燕窩（BN.1）(B)冰糖燕窩（S.2） ………………………………………………………………………103 圖3-28蛋白質之毛細管電泳圖譜(A) 魚膘(B) 豬皮(C)冰糖燕窩（S.5）(214 nm) ……………………………………………………104 圖3-29 乾品燕窩蛋白質以10％ SDS膠體電泳分析圖譜，Bio-safe Coomassie 染色。……………………………………………………105 圖3-30 乾品燕窩蛋白質以10％ SDS膠體電泳分析圖譜，Bio-safe Coomassie 染色。……………………………………………………106 圖3-31 乾品燕窩蛋白質以10％ SDS膠體電泳分析圖譜，PAS 糖染色法。 …………………………………………………………………107 圖3-32 以HPAE-PAD 分析中性糖及糖胺……………………………108 圖3-33 以HPAE-PAD 分析解離自乾品燕窩（BN.6）之中性糖及糖胺109 圖3-34 以HPAE-PAD 分析解離自冰糖燕窩（S.12）之中性糖及糖胺110 圖3-35 以HPAE-PAD 分析解離自乾品燕窩（BN.1）之唾液酸……111 圖3-36 以HPAE-PAD 分析解離自冰糖燕窩燕窩（S.11）之唾液酸112 圖 3-37冰糖燕窩產品之唾液酸含量比較 …………………………113 圖 3-38 (A)以HPAE-PAD 分析解離自冰糖燕窩（S.12）之中性糖及糖胺 (B)75%酒精處理 ………………………………………………114 圖 4-1燕窩分析流程圖 ……………………………………………115
dc.language.iso	zh-TW
dc.title	以成分分析鑒別燕窩之真偽	zh_TW
dc.title	Authenticity Determination of Bird’s Nests by Component Analyses	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.advisor-orcid	,吳瑞碧(JsbWu@ntu.edu.tw)
dc.contributor.oralexamcommittee	呂廷璋,潘子明(Tzu-Ming Pan),周薰修(Shin-Shou Chou),張為憲
dc.subject.keyword	燕窩,	zh_TW
dc.subject.keyword	NULL	en
dc.relation.page	121
dc.rights.note	有償授權
dc.date.accepted	2006-06-30
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

文件中的檔案：

檔案	大小	格式
ntu-95-1.pdf 目前未授權公開取用	4.66 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。