水酶法从巴旦木中提油及水解蛋白的研究

食品科学 ›› 2013, Vol. 34 ›› Issue (2): 72-77.

水酶法从巴旦木中提油及水解蛋白的研究

孙月娥

徐州工程学院食品学院

收稿日期:2012-06-23 修回日期:2012-12-27 出版日期:2013-01-25 发布日期:2013-01-15
通讯作者: 孙月娥 E-mail:sunyuee416@yahoo.com.cn

Aqueous enzymatic extraction of badanmu oil and protein hydrolysate

Received:2012-06-23 Revised:2012-12-27 Online:2013-01-25 Published:2013-01-15

摘要/Abstract

摘要： 采用水酶法从巴旦木中同时提取油与水解蛋白。依次使用复合细胞壁多糖水解酶（纤素酶:果胶酶=1:2）和碱性蛋白酶水解巴旦木浆，并对酶解工艺条件进行优化。通过单因素试验及正交试验，确定了水酶法提取巴旦木油的最佳工艺条件：料液比1:5、粒径40目、复合细胞壁多糖水解酶用量3.5%、酶解温度40℃、酶解时间4h、碱提pH 9.0、蛋白酶用量1.5%、酶解温度50℃、酶解时间2h；水酶法提取巴旦木水解蛋白的最佳工艺：料液比1:5、粒径30目、细胞多糖水解酶用量3%、提取温度50℃、提取时间3h、碱提pH 8.5、蛋白酶用量1.5%、酶解温度50℃、酶解时间2.5h。在此最佳条件下进行试验验证，总的巴旦木游离油和水解蛋白得率分别为68.74% 和 74.39%。

Abstract: The aqueous enzymatic process of simultaneously preparing oil and protein hydrolysates from BaDanMu was introduced. Badanmu slurry was treated with complex cell-wall polysaccharides degrading enzymes (cellulase:pectinase = 1:2) and Alcalase sequentially, and the optimal conditions for enzymatic hydrolysis were investigated. Through single factor experiment and the orthogonal experiment, the optimum conditions for extraction of badanmu oil are as follows: solid-liquid ratio is 1:5, particle size 30 mesh, cell polysaccharide hydrolysis enzyme content is 3.5%, extraction temperature 40 ℃, extracting time 4 h, alkali extraction pH 9, protease content is 1.5%, 50 ℃ temperature enzyme solution, enzymatic hydrolysis time 2 h；the optimum conditions for extraction of badanmu hydrolyzed protein: solid-liquid ratio is 1:5, particle size 30 mesh, cell polysaccharide hydrolysis enzyme content is 3%, 50 ℃, extraction temperature extracting time 3 h, alkali mention pH 8.5, protease content is 1.5%, 50 ℃ temperature enzyme solution, enzymatic hydrolysis time 2.5 h. Under the optimum conditions, the total extraction rates of free oil and protein hydrolysates are 68.74% and 74.39%, respectively.

中图分类号:

TS201.1

孙月娥. 水酶法从巴旦木中提油及水解蛋白的研究[J]. 食品科学, 2013, 34(2): 72-77.

参考文献

[1] 朱琼林. 新疆巴丹杏[M]. 新疆人民出版社, 1984.
[2] 刘金荣, 但建明, 赵文彬, 等. 维药巴旦杏的微量元素分析[J]. 微量元素与健康研究, 2002, 19(1): 29-30.
[3] 李述刚, 侯旭杰, 张娜, 等. 发酵型巴旦杏、花生复合酸乳冰淇淋的研制[J]. 食品科学, 2007, 28(1): 381-383.
[4] 熊素英, 朱丽霞, 张娜. 巴旦杏乳酸发酵酸乳的研制[J]. 食品科学, 2008, 29(2): 497-499.
[5] 赵婷, 岳琳, 李勇. 巴旦木仁油中脂肪酸成分分析[J]. 中国油脂, 2009, 34(2): 78-79.
[6] 李颖, 易晓华, 李庆典. 新疆巴旦姆种仁高级脂肪酸与氨基酸营养评价[J]. 中国食品学报, 2004, 4(4): 64-70.
[7] Sakanaka S, Tachibana Y, Ishihara N, et al. Antioxidant properties of casein calcium peptides and their effects on lipid oxidation in beef homogenates[J]. Journal of agricultural and food chemistry, 2005, 53(2): 464-468.
[8] 张君惠, 张晖, 王兴国, 等. 抗氧化肽的研究进展[J]. 中国粮油学报, 2008, 23(6): 227–233.
[9] Korhonen H, Pihlanto-Lepp La A, Rantam Ki P, et al. Impact of processing on bioactive proteins and peptides[J]. Trends in food science & Technology, 1998, 9(8-9): 307-319.
[10] Li Y H, Jiang B, Zhang T, et al. Antioxidant and free radical scavenging activities of chickpea protein hydrolysate (CPH)[J]. Food Chemistry, 2008, 106: 444-450.
[11] 谭春兰, 袁永俊. 水酶法在植物油脂中提取的应用[J]. 食品研究与开发, 2006, 27(7): 128-129.
[12] 王文侠, 任健. 植物油水酶法浸提工艺研究进展[J]. 现代食品科技, 2005(2): 182-184.
[13] 大连轻工业学院, 华南理工大学, 西北轻工业学院, 等. 食品分析[M]. 北京:中国轻工业出版社, 1994.
[14] 冷玉娴, 许时婴, 王璋, 等. 水酶法提取葵花籽油的工艺[J]. 食品与发酵工业, 2006, 32(10): 127-130.
[15] 盛小娜, 王璋, 许时婴. 水酶法提取甜杏仁油及水解蛋白的研究[J]. 中国油脂, 2007, 32(11): 26:-30.