Effects of reaction parameters on the formation of α-Dicarbonyl compounds in Glucose-Glycine Maillard chemical model system
-
摘要: 采用邻苯二胺(OPD)衍生和HPLC定性定量考察了反应条件(温度、p H、时间和底物浓度比)对葡萄糖-甘氨酸模拟美拉德反应体系中三种α-二羰基化合物3-葡萄糖醛酮(3-DG)、乙二醛(GO)和丙酮醛(MGO)生成的影响。结果表明:在80140℃范围内温度的升高会促进体系中MGO和GO的生成,而3-DG在温度达到110℃时达到峰值,随后则开始下降。p H在59范围内对三种物质的影响趋势和温度类似,MGO和GO的生成随p H的升高而不断增加,而3-DG在p H为6时含量达到最高,随后急剧降低。3-DG和GO生成的速率随着时间的延长逐渐降低,而在2 h内MGO的生成速率则趋于恒定。葡萄糖的相对含量升高有利于3-DG的生成,而当甘氨酸的相对含量较高时则会促进MGO和GO的生成。本研究能够为美拉德反应中以α-二羰基化合物为中间产物的风味物质的生成机制研究提供一定的实验依据。Abstract: Derivatization with o-phenylenediamine(OPD) as well as qualitative and quantitative analysis with HPLC were employed to investigate the effects of reaction conditions(temperature,p H,duration and reactant ratio) on the formation of three α-dicarbonyl compounds including 3-deoxyglucosone(3-DG),glyoxal(GO)and methylglyoxal(MGO) in glucose-glycine maillard chemical model systems. The results showed thatthe increasing of temperature promoted the generation of MGO and GO within 80~140 ℃,while the level of 3-DG increased to the highest at 110 ℃,and decreased subsequently. The effects of p H value within 5 ~9 were similar to that of the temperature:the formation of GO and MGO increased with the increasing of p H values,while the levels of 3-DG increased to the maximum as p H vaue of 6. The rate of 3-DG and GO formation decreased as the extension of duration,but it tended to be constant for MGO within 2 h. In terms of the substrate ratio,the formation of 3-DG could be enhanced by the increasing of relative content of glucose,while increasing of glycine levels could promote GO and MGO formation. The results may provide experimental basis to certain extent for flavor compounds with α-dicarbonyl compounds as intermediate products.
-
Keywords:
- α-dicarbonyl compounds /
- glucose /
- glycine /
- HPLC /
- reaction condition
-
[1] 刘立国.美拉德反应产物研究进展[J].中国食品添加剂,2003(z1):102-105. [2] Daglia M,Amoroso A,Rossi D,et al.Identification and quantification ofα-dicarbonyl compounds in balsamic and traditional balsamic vinegars and their cytotoxicity against human cells[J].Journal of Food Composition and Analysis,2013,31(1):67-74.
[3] Papetti A,Mascherpa D,Gazzani G.Freeα-dicarbonyl compounds in coffee,barley coffee and soy sauce and effects of in vitro digestion[J].Food chemistry,2014,164:259-265.
[4] Degen J,Hellwig M,Henle T.1,2-Dicarbonyl compounds in commonly consumed foods[J].Journal of agricultural and food chemistry,2012,60(28):7071-7079.
[5] Hellwig M,Degen J,Henle T.3-Deoxygalactosone,a“new”1,2-dicarbonyl compound in milk products[J].Journal of agricultural and food chemistry,2010,58(19):10752-10760.
[6] Kocadagˇl覦T,G觟kmen V.Investigation ofα-dicarbonyl compounds in baby foods by high-performance liquid chromatography coupled with electrospray ionization mass spectrometry[J].Journal of Agricultural and Food Chemistry,2014,62(31):7714-7720. [7] De Revel G,Pripis-Nicolau L,Barbe J C,et al.The detection ofα-dicarbonyl compounds in wine by formation of quinoxaline derivatives[J].Journal of the Science of Food and Agriculture,2000,80(1):102-108.
[8] Cui-Cui M U,Yan-Li F,Jin-Qing Z,et al.Determination of Dicarbonyl Compounds in Ambient Fine Particles by Liquid Chromatography after 2,4-Dinitrophenylhydrazine Derivative[J].Chinese Journal of Analytical Chemistry,2010,38(11):1573-1577.
[9] Gobert J,Glomb M A.Degradation of glucose:Reinvestigation of reactiveα-dicarbonyl compounds[J].Journal of Agricultural and Food Chemistry,2009,57(18):8591-8597.
[10] Chen X M,Kitts D D.Identification and quantification ofα-dicarbonyl compounds produced in different sugar-amino acid Maillard reaction model systems[J].Food research international,2011,44(9):2775-2782.
[11] Hollnagel A,Kroh L W.Degradation of oligosaccharides in nonenzymatic browning by formation ofα-dicarbonyl compounds via a“peeling off”mechanism[J].Journal of Agricultural and Food Chemistry,2000,48(12):6219-6226.
[12] 李伶俐.美拉德反应体系中影响烤肉风味形成的因素研究[D].无锡:江南大学,2011. [13] Yu A N,Zhang A D.The effect of p H on the formation of aroma compounds produced by heating a model system containing L-ascorbic acid with L-threonine/L-serine[J].Food Chemistry,2010,119(1):214-219.
[14] 吕梦莎,曾永青,黄雪松.反应条件对美拉德反应模拟体系中的α-二羰基化合物的影响[J].食品科学,2013,34(24):50-56. [15] Weenen H.Reactive intermediates and carbohydrate fragmentation in Maillard chemistry[J].Food Chemistry,1998,62(4):393-401.
[16] Martins SIFS,Van Boekel MAJS.A kinetic model for the glucose/glycine Maillard reaction pathways[J].Food Chemistry,2005,90(1-2):257-269.
[17] Martins SIFS,Marcelis ATM,van Boekel MAJS.Kinetic modelling of Amadori N-(1-deoxy-D-fructos-1-yl)-glycine degradation pathways.Part I—Reaction mechanism[J].Carbohydrate Research,2003,338(16):1651-1663.
[18] Arribas-Lorenzo G,Morales FJ.Analysis,distribution,and dietary exposure of glyoxal and methylglyoxal in cookies and their relationship with other heat-induced contaminants[J].Journal of Agricultural and Food Chemistry,2010,58(5):2966-2972.
[19] Nursten HE.The Maillard reaction:chemistry,biochemistry and implications[M].Royal Society of Chemistry,2005.
[20] Hollnagel A,Kroh L W.Degradation of oligosaccharides in nonenzymatic browning by formation ofα-dicarbonyl compounds via a“peeling off”mechanism[J].Journal of Agricultural and Food Chemistry,2000,48(12):6219-6226.
[21] Hollnagel A,Kroh L W.3-Deoxypentosulose:anα-dicarbonyl compound predominating in nonenzymatic browning of oligosaccharides in aqueous solution[J].Journal of Agricultural and Food Chemistry,2002,50(6):1659-1664.
计量
- 文章访问数: 260
- HTML全文浏览量: 21
- PDF下载量: 471
下载:
