名稱:綜合總膳食纖維檢測試劑盒 英文名:Integrated Total Dietary Fibre Kit 規(guī)格:100次(3瓶) 產(chǎn)地:愛爾蘭 在水中的溶解度:易溶 pH值:7.0 氣味:無 狀態(tài):液體 保質(zhì)期:十年或以上(冰箱內(nèi)) 成分 三玻璃瓶 名稱 CAS a-*(胰)酶 9014-71-5 1瓶(2g)(玻璃) 淀粉葡萄糖苷酶酶 9032-08-0 1瓶(6mL)(玻璃) 蛋白酶 9014-01-1 1瓶(10mL)(玻璃) 品牌:Megazyme 產(chǎn)品品名:綜合總膳食纖維檢測試劑盒 英文品名:Integrated Total Dietary Fibre Assay Kit 規(guī)格型號:100 assays per kit AOAC Method 2009.01 & 2011.25, AACC Method 32-45.01 & 32-50.01 INTRODUCTION: It is generally believed1-3 that an increased consumption of dietaryfibre (DF) will lead to a reduction in conditions such as constipation,diabetes, obesity, coronary heart disease and others. In the 1970’sTrowell had developed a definition of dietary fibre which evolved in19763 to: “Dietary fibre consists of the remnants of edible plant cells,polysaccharides, lignin, and associated substances resistant todigestion by the alimentary enzymes of humans.” This definition defines a macro constituent of foods which includescellulose, hemicellulose, lignin, gums, modified celluloses, mucilages,oligosaccharides, pectins and associated minor substances such as waxes,cutin, and suberin. On the basis of this definition3, appropriate methodology for themeasurement of DF was developed by a consortium of researchers in Europeand USA. This led to AOAC Official Method 985.29 (the Prosky method),4,5and to subsequent modifications of this method, including AOAC OfficialMethod 991.434 in which the buffers were changed. The aim of thesemethods was to give an accurate measurement of the content of totaldietary fibre in plant products and food materials. More specifically,the methodology aimed at hydrolysing and removing starch and protein.Fats were removed by the solvents employed to recover the non-hydrolysedmaterial. From the outset, it was realised that all protein was nothydrolysed, so each sample was then analysed in duplicate and residuesrecovered and weighed. One of these residues is analysed for ash contentand the other for protein. These weights are subtracted from the averageof the residue weights. It was also realised that, in the analyticalprocedure, starch also was not compley hydrolysed and removed. Thisin turn led to the discovery of so-called “resistant starch (RS)”. Thequestion then was, “should RS be measured and added to the total dietaryfibre value, or should it be analytically removed and ignored?” Since RSescapes digestion in the human small intestine, the general consensus isthat it should be accuray measured and included. Research in the1990’s showed that AOAC Official Method 991.43 underestimates RS, soalternative methods for the measurement of this component were developedand evaluated. While most of these new methods gave similar results fora range of RS containing samples, none of the methods survived therigours of interlaboratory evaluation except that of McCleary et al.6(AOAC Method 2002.02), which also gave results in line with thoseobtained from ileostomy patients. In the mid-1990’s it was generally agreed that dietary fibre shouldalso include non-digestible oligosaccharides (NDO), as these behavedphysiologically as dietary fibre. Specific methods were developed forfructan [and fructo-oligosaccharides (FOS)] (AOAC Methods 997.08 1 and 999.03)7,8, galacto-oligosaccharides (GOS) (AOAC Method 2001.03)9, resistant maltodextrins (RMD) (AOAC Method 2001.03)10 and Polydextrose? (AOAC Method 2000.11)11. The development of these methodologies was very useful for ingredient developers, food manufacturers and analysts measuring the specific component. However, for those interested in measuring the total dietary fibre content of a material, a problem was introduced. For many of these specific carbohydrates (including RS, inulin and resistant maltodextrins) a portion of the component is also measured by AOAC Official method 985.29 and 991.43. Thus if the value for a component determined using the specific method is added to the total dietary fibre value, some of the component is double counted. This is clearly depicted in Figure 1. Figure 1. Components measured, and not measured, by AOAC Official Methods 985.29 and 991.43. This problem of potential double counting led us to research and develop a procedure that allows the measurement of total dietary fibre, which includes RS and NDO. This integrated total dietary fibre (INTDF) procedure is depicted in Figure 2 and is modelled on AOAC Official Methods 2002.02 (resistant starch), 991.43 (total dietary fibre) and 2001.03 (resistant maltodextrins). The theory of this method is discussed in detail in McCleary (2007)12 and has been successfully subjected to an interlaboratory evaluation through AOAC International (AOAC Method 2009.01)13. A modified method for separay measuring insoluble dietary fibre (IDF), dietary fibre soluble in water but precipitated in 78% aqueous ethanol (SDFP), and dietary fibre soluble in water and not precipitated in 78% aqueous ethanol (SDFS) has also been successfully evaluated (AOAC Method 2011.25)14. SDFP was previously termed high molecular weight soluble dietary fibre (HMWSDF) and SDFS was previously termed low molecular weight soluble dietary fibre (LMWSDF) and is also referred to as non-digestible oligosaccharides (NDO). Several minor modifications to ensure complete measurement of FOS and complete removal of non-resistant maltodextrins are described Total Dietary Fibre (AOAC Method 985.29) (AOAC Method 991.43) Polydextrose Fibersol 2 Resistant Starch Cellulose Beta-Glucan Galactomannan Arabinoxylan Galacto-oligosaccharides Raffinose/Stachyose Pectin Arabinogalactan Inulin FOS Figure 2. Principle of the Integrated (Codex compliant) Total DietaryFibre assay procedure showing separate measurement of IDF, SDFP and SDFS. In November 2008, the Codex Committee on Nutrition and Foods forSpecial Dietary Uses (CCNFSDU) established a definition for dietaryfibre. This definition was accepted by the Codex Alimentarius Commission(CAC) in 2009 (FAO, 2009)16, marking the achievement of international consensus: “Dietary fiber consists of carbohydrate polymers with ten or moremonomeric units, which are not hydrolyzed by the endogenous enzymes inthe small intestine of humans and belong to the following categories:edible carbohydrate polymers naturally occurring in the food asconsumed; carbohydrate polymers which have been obtained from food rawmaterial by physical, enzymatic or chemical means and which have beenshown to have a physiological effect of benefit to health asdemonstrated by generally accepted scientific evidence to competentauthorities, and; synthetic carbohydrate polymers which have been shownto have a physiological effect of benefit to health as demonstrated bygenerally accepted scientific evidence to competent authorities. a) When derived from a plant origin, dietary fiber may includefractions of lignin and/or other compounds when associated withpolysaccharides in the plant cell walls and if these compounds arequantified by the AOAC gravimetric analytical method for dietary fibreanalysis: fractions of lignin and the other compounds (proteicfractions, phenolic compounds, by McCleary et al. (2013)15, as also are the problems in measurement ofRS4 (starch granules chemically cross-linked with phosphate groups). Sample (1.00 g) in sealed 250 mL bottle (in duplicate) Add Maleate buffer + pancreatic α-amylase (PAA) + AMG Add Trizma Base to adjust pH to ~ 8.2 Add Acetic acid (to adjust pH to ~ 4.3) + Sorbitol (Internal Standard) Add protease Remove 1 mL for Available CHO Determination Add 4 volumes of ethanol to precipitate SDFP SDFP (precipitate) SDFS (?ltrate) SDFP + SDFS in filtrate Filter through crucible with celite IDF residue Incubate in shaking water bath at 37°C for 16 h. Incubate at 100°C for 20 min. Cool to ~ 60°C. Incubate at 60°C for 30 min. Cool to room temperature. waxes, saponins, phytates, cutin, phytosterols, etc.) intimay“associated” with plant polysaccharides in the AOAC 991.43 method. b) Decision on whether to include carbohydrates of 3 to 9 monomericunits should be left up to national authorities.” The Integrated TDF method described in this booklet, as originallypublished in 200712, has been successfully subjected to interlaboratoryevaluation through AOAC International (Methods 2009.0113 and 2011.2514),and accepted by Codex Alimentarius as a Type I method (March, 2011). KITS: Kits suitable for performing 100 determinations of TDF (IntegratedProcedure) are available from Megazyme. The kits contain the full assaymethod plus: Bottle 1: Concentrated pancreatic α-amylase (E-PANAA); g, 150,000 Ceralpha Units/g. Stable for > 5 years stored dry at -20°C. Bottle 2: Amyloglucosidase (E-AMGDF) (20 mL, 3300 Units/mL). Stable for > 3 years at 4°C. Bottle 3: Puri?ed protease (E-BSPRT) (10 mL, 350 tyrosine units/mL). Stable for > 3 years at -20°C. Bottle 4: LC Retention Time Standard [maltodextrins plus maltose (4:1ratio), approx 5 g]. Stable for > 3 years when stored dry at room temperature. Bottle 5: D-Sorbitol (approx. 12 g, dry). Stable for > 3 years when stored dry at room temperature. Celite 545?, acid washed, in 100 g or 500 g packages (cat. no. G-CEL100, or cat. no. G-CEL500), Amberlite FPA53? (OH-) (cat. no. G-AMBOH, 2.5 Kg) and Ambersep 200? (H+) (cat. no. G-AMBH, 2.5 Kg) ion exchange resins are available separay from Megazyme 范圍: 適用于谷物,水果和蔬菜,谷物和水果 產(chǎn)品和食品。 酶的純度和標(biāo)準(zhǔn)化: 的有效性和純潔性Megazyme α -*,蛋白酶和 淀粉葡萄糖苷酶已經(jīng)評價(jià)的標(biāo)準(zhǔn)使用 建議AOAC方法985.29和991.43 ,和油菜 方法32-05 。 Megazyme耐高溫α -*(電子BLAAM )有一個(gè) 活動(dòng)3000 U / ml的( Ceralpha方法) ;蛋白酶是提供在 1concentration為50毫克/毫升( ? 350*單位/毫升) ;和 淀粉葡萄糖苷酶提供的濃度為200 U / ml的 (硝基苯β - maltoside基板) (或3300 U / ml的可溶性 淀粉) 。這種淀粉葡萄糖苷酶的活動(dòng)是150 %的濃度 傳統(tǒng)上用于華盈化驗(yàn),以便0.2毫升(而不是0.3毫升)是 用于試驗(yàn)。 Megazyme淀粉葡萄糖苷酶(電子AMGDF )基本上是缺乏 纖維素酶,而在其他準(zhǔn)備用于華盈決心, 纖維素酶污染可高達(dá)1 % 淀粉葡萄糖苷酶(對一項(xiàng)活動(dòng)的基礎(chǔ)上) 。這種程度的污染 導(dǎo)致低估的β -葡聚糖高達(dá)10-15 % 。 方法用于測量和標(biāo)準(zhǔn)化的Megazyme 酶,可以要求。