超声辅助湿法糖基化改性核桃粕蛋白的制备及性能分析OA
Preparation and Performance Analysis of Walnut Meal Protein Modified by Ultrasound-assisted Wet Glycosylation
为开发功能性核桃粕蛋白-多糖复合物,以提升核桃粕蛋白的资源利用率并扩大其应用.本文以核桃粕与黑木耳多糖为原料,采用超声辅助湿法糖基化对核桃粕蛋白进行改性,首先考察超声功率、pH、超声时间、核桃粕蛋白与黑木耳多糖质量比对核桃粕蛋白接枝度与褐变程度的影响,并进行响应面试验以确定最佳制备工艺,随后对改性后的核桃粕蛋白进行性能研究.结果表明:核桃粕蛋白与黑木耳多糖质量比为 1:2,反应温度 80℃,pH9.60、超声功率 295 W、超声时间 9.6 min时,接枝度为 48.60%,与预测值相差不大.由聚丙烯酰胺电泳分析得知,通过超声辅助湿法美拉德反应成功制备核桃粕蛋白糖基化产物.扫描电镜表明,改性后核桃粕蛋白粒径尺寸减小,呈现球状微粒形态.超声辅助湿法糖基化改性核桃粕蛋白溶解度、持水性、乳化性分别是未改性蛋白的1.61倍、2.25倍、1.62倍.超声辅助湿法糖基化改性核桃粕蛋白溶解度与持水性分别是湿法糖基化改性核桃粕蛋白的 1.12倍、1.65倍,乳化稳定性略高(P<0.05).该实验为提高核桃粕蛋白资源利用率,拓展其应用提供一定参考.
To develop a functional walnut meal protein-polysaccharide complex for improving the resource utilization of walnut meal protein and expanding its applications,this study focused on the modification of walnut meal protein via ultra-sound-assisted wet glycosylation.And the walnut meal and black fungus polysaccharid were used as raw material,the effects of key process parameters—including ultrasound power,pH,ultrasound duration,and the mass ratio of walnut meal protein to black fungus polysaccharide—on the grafting degree and browning level of walnut meal protein were first inves-tigated,response surface methodology(RSM)was then employed to optimize the preparation process and determine the optimal conditions.Subsequently,the functional properties of the modified walnut meal protein were systematically deter-mined.The results showed that under the optimal conditions—mass ratio of walnut meal protein to black fungus polysac-charide of 1:2,reaction temperature of 80℃,pH of 9.60,ultrasound power of 295 W,and ultrasound time of 9.6 min—the grafting degree reached 48.60%,which was in close agreement with the predicted value.Polyacrylamide gel electrophore-sis(PAGE)analysis confirmed the successful preparation of walnut meal protein glycosylation products via ultrasound-assisted wet Maillard reaction.Scanning electron microscopy(SEM)observations revealed that the modified walnut meal protein exhibited a reduced particle size and a spherical micro-particle morphology.Functional property assays showed that the solubility,water-holding capacity,and emulsifying activity of the ultrasound-assisted wet glycosylation-modified wal-nut meal protein were 1.61-fold,2.25-fold,and 1.62-fold those of the unmodified protein,respectively.Compared with the wet glycosylation-modified counterpart,the ultrasound-assisted modified protein displayed 1.12-fold higher solubility,1.65-fold higher water-holding capacity,and slightly improved emulsifying stability(P<0.05).This study provides a theoretical and technical reference for improving the resource utilization of walnut meal protein and broadening its indus-trial applications.
张天宇;谢焕;李春梅;周雨亭;刘曼丽
新疆理工学院食品安全与营养实验教学示范中心,新疆 阿克苏 843100新疆理工学院食品安全与营养实验教学示范中心,新疆 阿克苏 843100新疆理工学院食品安全与营养实验教学示范中心,新疆 阿克苏 843100新疆黑木耳工程技术研究中心,新疆 阿克苏 843100新疆理工学院食品安全与营养实验教学示范中心,新疆 阿克苏 843100||新疆黑木耳工程技术研究中心,新疆 阿克苏 843100
轻工纺织
核桃粕蛋白黑木耳多糖超声糖基化功能特性结构表征
walnut meal proteinblack fungus polysaccharideultrasoundglycosylationfunctional propertiesstructural characterization
《食品工业科技》 2026 (12)
46-55,10
新疆维吾尔自治区教育厅高校科研项目(XJEDU2023P153).
评论