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中国精品科技期刊2020
刘鑫,陈香玉,郭锐,等. 碧螺春多糖的超声辅助酶提取工艺优化、分离纯化及性质分析[J]. 华体会体育,2021,42(16):138−146. doi: 10.13386/j.issn1002-0306.2020110007.
引用本文: 刘鑫,陈香玉,郭锐,等. 碧螺春多糖的超声辅助酶提取工艺优化、分离纯化及性质分析[J]. 华体会体育,2021,42(16):138−146. doi: 10.13386/j.issn1002-0306.2020110007.
LIU Xin, CHEN Xiangyu, GUO Rui, et al. Process Optimization of Ultrasound-assisted Enzyme Extraction of Biluochun Polysaccharide and Its Separation, Purification and Property Analysis[J]. Science and Technology of Food Industry, 2021, 42(16): 138−146. (in Chinese with English abstract). doi: 10.13386/j.issn1002-0306.2020110007.
Citation: LIU Xin, CHEN Xiangyu, GUO Rui, et al. Process Optimization of Ultrasound-assisted Enzyme Extraction of Biluochun Polysaccharide and Its Separation, Purification and Property Analysis[J]. Science and Technology of Food Industry, 2021, 42(16): 138−146. (in Chinese with English abstract). doi: 10.13386/j.issn1002-0306.2020110007.

碧螺春多糖的超声辅助酶提取工艺优化、分离纯化及性质分析

Process Optimization of Ultrasound-assisted Enzyme Extraction of Biluochun Polysaccharide and Its Separation, Purification and Property Analysis

  • 摘要: 以碧螺春粗老茶为原料,采用复合酶法进行酶解处理,利用响应面试验对超声辅助提取碧螺春多糖(BTP)的工艺进行了优化,利用阴离子柱和凝胶柱进行分离纯化,通过傅里叶红外变换光谱(FT-IR)、紫外光谱扫描、高效体积排阻色谱(HPSEC)测定了分离后各组分的理化组成、官能团组成、相对分子质量和分子构象等性质。试验表明最佳提取工艺为超声功率200 W,超声温度45 ℃,料液比40:1 mL/g,超声时间35 min,碧螺春多糖(BTP)得率为26.74%。BTP经DEAE-Sepharose阴离子交换柱层析获得BTPA1,BTPA1经Sepharose CL-6B凝胶柱层析获得BTPA11和BTPA12。BTP、BTPA1、BTPA11和BTPA12的中性糖含量分别为59.39%、66.86%、77.43%和62.61%,糖醛酸含量分别为51.06%、53.53%、54.45%和65.39%。经光谱解析和相对分子质量分析,四种碧螺春多糖组分均含有酸性糖和吡喃环结构;BTPA11和BTPA12为相对分子质量分布均一的多糖,且相对分子质量分别为1604.2和353.7 kDa,构型斜率分别为0.12和0.15,二者均可能是紧凑卷曲的高支化球形结构。超声辅助酶提取碧螺春多糖得率较高,对各组分的性质分析将有利于精细结构研究和活性功能开发利用。

     

    Abstract: After the compound enzymatic hydrolysis of Biluochun tea powder, the ultrasonic-assisted extraction process of Biluochun polysaccharide (BTP) was optimized by response surface experiment. The anion column and gel column were used for separation and purification. The physicochemical composition, functional group composition, relative molecular mass and molecular conformation of each component were determined by Fourier transform infrared spectroscopy (FT-IR), ultraviolet spectrum scanning and high performance volume exclusion chromatography (HPSEC). The experiments showed that the best extraction process was ultrasonic power 200 W, ultrasonic temperature 45 ℃, material-to-liquid ratio 40:1 mL/g, ultrasonic time 35 min, and the yield of Biluochun polysaccharides was 26.74%. BTPA1 was obtained from BTP by DEAE-Sepharose anion exchange column chromatography, and BTPA1 was separated by Sepharose CL-6B gel column chromatography to obtain BTPA11 and BTPA12. The neutral sugar content of BTP, BTPA1, BTPA11 and BTPA12 were 59.39%, 66.86%, 77.43% and 62.61%, and the uronic acid content was 51.06%, 53.53%, 54.45% and 65.39%, respectively. After spectral and relative molecular mass analysis, the four Biluochun polysaccharide components all contained acid sugars and pyran ring structures; BTPA11 and BTPA12 were polysaccharides with uniform relative molecular mass distribution, and their relative molecular masses were 1604.2 kDa and 353.7 kDa; The slopes of the configuration of BTPA11 and BTPA12 were 0.12 and 0.15, and both might be high-branched spherical structures. The ultrasound-assisted enzyme extraction of Biluochun polysaccharide had a higher yield, and the analysis of the properties of each component would facilitate the study of fine structure and the development and utilization of active functions.

     

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