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酶法提取石榴皮多酚工艺研究 总被引:4,自引:0,他引:4
为研究酶法提取石榴皮中多酚的最佳工艺,采用单因素试验考察不同浓度的纤维素酶、果胶酶、复合酶(不同质量比的纤维素酶和果胶酶)、酶解时间、酶解温度及酶解液pH值对石榴皮多酚得率的影响,并运用二次通用旋转回归组合设计优化酶法提取石榴皮多酚的最佳工艺参数。试验结果表明,对石榴皮多酚得率影响次序依次为酶解时间>酶浓度>pH值>酶解温度。当复合酶(纤维素酶和果胶酶质量比为2:1)质量浓度为0.25mg/mL,酶解时间150min,酶解温度50℃,初始酶解液pH6.0时,多酚得率达(23.87±0.08)%(n=5),与理论计算值23.96%的相对误差仅0.376%。酶法提取石榴皮中多酚的提取率比溶剂浸提法高出16.84%。 相似文献
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石榴皮是一种易获得的、廉价的,但含有丰富多酚的废料。采用超声辅助提取法从石榴皮中提取多酚,优化工艺参数并利用高效液相色谱法(HPLC)测定石榴皮中多酚的成分和含量,同时研究了石榴皮表面在超声处理下的变化。研究结果表明,在超声条件下,用水作为溶剂有更高的多酚得率,比甲醇等有机溶剂提取效果更好。在优化条件,即液固比(mL∶g)为60∶1,超声功率为400 W和超声时间为25 min时,多酚的最佳得率为39.30 mg/g(以没食子酸为标准),高于传统溶剂提取法的得率(32.58 mg/g)。HPLC分析得到石榴皮多酚中安石榴苷含量最高,其次是石榴皮鞣素,并且超声处理能较大地强化提取效果。石榴皮表面显微观察证明,超声能够显著破坏石榴皮表面而影响植物组织完整性,使多酚更多地释放出来。 相似文献
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《食品与发酵工业》2016,(12):150-156
采用超声辅助双水相法提取石榴皮多酚,在单因素试验的基础上,选取超声时间、超声温度、(NH4)2SO4用量和液料比为自变量,石榴皮多酚得率为响应值,通过Box-Behnken试验设计及响应面分析法,研究各单因素及其交互作用对多酚得率的影响,优化石榴皮多酚的提取工艺条件。研究结果表明:最佳的提取工艺参数为,超声时间32 min、超声温度40℃、(NH4)2SO4用量0.36 g/m L、液料比为37∶1(m L∶g),在此条件下提取,多酚的得率为(10.63±0.28)%(n=3),与模型的预测值10.708 6%有较好的拟合性,表明超声辅助双水相提取石榴皮多酚的方法可行。 相似文献
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利用Raw264.7巨噬细胞源性泡沫细胞模型,阐明石榴皮多酚对高密度脂蛋白(High density lipoprotein,HDL)介导Raw264.7泡沫细胞胆固醇流出的调控作用,并采用蛋白质免疫印迹法(Western blotting,WB),分析石榴皮多酚对巨噬细胞胆固醇流出相关蛋白清道夫受体B1(Scavenger receptor B1,SR-B1)、酰基辅酶A1:胆固醇酰基转移酶(acyl-coenzyme A1:cholesterol acyltransferase,ACAT1)和胆固醇酯水解酶(cholesteryl ester hydrolase,nCEH)表达的影响,揭示细胞ACAT1和nCEH活性的变化。结果表明:石榴皮多酚可促进HDL介导的胆固醇流出,显著上调胆固醇流出相关蛋白SRB1的表达(P0.05);此外,石榴皮多酚对nCEH和ACAT1蛋白表达影响不显著(P0.05),但可显著降低ACAT1的酶活(P0.05),提高nCEH酶活性(P0.05),从而有利于细胞内胆固醇酯向游离胆固醇的转化和流出。 相似文献
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Pomegranate peel is a valuable byproduct for phenolic extraction. However, comprehensive analysis on novel extraction methods is lacking. In this study, free and bound phenolics, extracted by thermal (heating) and non-thermal methods (conventional solvent, high pressure, and ultrasound), were systematically compared by UHPLC-QTOF-MS and UPLC-QQQ-MS. The total content of free phenolics, approximately 10 times to that of bound phenolics, showed no significant difference across different extraction methods. The highest yield of bound phenolics was obtained by heating and high-pressure methods and the composition was closely dependent on the degree of alkaline hydrolysis. Many of bound phenolics obtained by thermal extraction were small molecules. Meanwhile, a greater proportion of larger compounds were obtained by high-pressure extraction, indicating that high pressure was gentler than thermal extraction. Genistin, nicotiflorin and myricetin-3-galactoside were first reported in pomegranate peel. This study provides a solid foundation for purposeful extraction of phenolics from pomegranate peels for industry. 相似文献
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Pomegranate peels are one of the most valuable by-products of the food industry in terms of polyphenols which are conventionally extracted from plant materials by organic solvents, especially with methanol. Pressurised water extraction was investigated for the extraction of polyphenols from pomegranate peels. The most important factors affecting the extraction results were found to be particle size, temperature, and static time. The results indicated that pressurised water extraction was as effective as conventional methanol extraction for the recovery of polyphenols from pomegranate peels. Total phenolic contents of pomegranate peels obtained by pressurised water extraction at optimised conditions and conventional solid–liquid methanol extraction were determined as 264.3 and 258.2 mg/g tannic acid equivalents, respectively. Hydrolyzable tannins were the predominant polyphenols of pomegranate peels corresponding to 262.7 mg/g tannic acid equivalents. Punicalagin content of pomegranate peels by pressurised water extraction was found to be 116.6 mg/g on dry matter basis. 相似文献