Optimization of Enzymatic Extraction Process of Polysaccharides from Pseudostellaria heterophylla Fibrous Roots by Response Surface Methodology and Its Pilot Application

[Objectives]To study and optimize the process conditions of enzymatic hydrolysis technology for extracting polysaccharides from Pseudostellaria heterophylla fibrous roots and its application in workshop pilot tests.[Methods]P.heterophylla fibrous roots were taken as the matrix material,and Box Behnken design was used to analyze the extraction time,composite enzyme addition amount,and liquid-solid ratio for response surface optimization experiments,and then applied to the pilot extraction of P.heterophylla fibrous roots.[Results]Response surface analysis showed that all factors had a significant impact on the experimental indicators.The optimal extraction process conditions for polysaccharides from P.heterophylla fibrous roots were extraction time of 2.7 h,compound enzyme addition of 2.5%,and liquid-solid ratio of 32.The yield of polysaccharides from P.heterophylla fibrous roots was 4.83%.The water extraction process of P.heterophylla fibrous roots extraction pilot was used as the control group for response surface optimization of the pilot experiment.The optimization results showed that the extraction time was 3 h,the amount of composite enzyme added was 2.5%,and the liquid-solid ratio was 28.The polysaccharide yield was 4.75%,an increase of 4.63%compared to the control group.[Conclusions]This paper could provide feasibility for the innovation of enzy-matic hydrolysis technology for P.heterophylla fibrous roots and its workshop pilot practice application,as well as a reference for the industrial application of its medicinal resources.

Progress in Enzymatic Production of Trehalose

Trehalose is a non-reducing disaccharide, and widespread in nature. It is a typical stress metabolite that can protect macromolecules such as proteins in organisms under extreme conditions. Therefore, trehalose has been widely used in food, medicine and cosmetics. Trehalose is extracted from yeast or synthesized by chemical method. Due to the high cost of traditional methods, trehalose is mainly produced by enzymatic methods. There are mainly three pathways: TPS/TPP, TreY/TreZ and TreS. These enzymatic systems are expressed mainly through heterologous expression.

Enzymatic preparation of mono-and diacylglycerols:A review

Monoacylglycerols(MAGs) and diacylglycerols(DAGs) are partial glycerides widely used in food industry. They are safe and non-toxic food emulsifiers, especially for MAGs. MAGs account for approximately 75% of the total emulsifiers in food industry worldwide. DAGs are recognized as functional cooking oils, they can suppress body fat accumulation and postprandial serum triacylglycerols(TAGs) level. The traditional production of MAGs and DAGs is based on the chemical method, which requires high reaction temperature usually up to 200–260 ℃. Such high temperature is not suitable for oil containing heat sensitive polyunsaturated fatty acids. Enzymatic approach has been received increasing attentions. Enzymatic production of partial glycerides to replace chemical processes has been in industry, particularly for DAGs production as the products have been claimed as a functional and nutritional oil. Enzyme technology for the processing of oils and fats has been moved to industry step by step and case by case during the last 20 years. More and more applications are particularly moving into bulky oils and fats processing. At the same time, the cost of enzymes as a commercial product is reducing steadily. This review summarized the recent 15 years advances on the the enzymatic preparation of MAGs and DAGs. The critical process parameters under different reaction routes were presented and emphasized. The reaction media not only increased the homogeneity of the reaction system, but also shifted the reaction equilibrium towards the target product generation, and this part was stated in detail. In addition, the patent evaluation was included, and the application of MAGs and DAGs was covered.

Biodiesel Production by Enzymatic Catalysis Process Using Two Analytical Ways： Gas Chromatography and Total Glycerol Determination

Currently, biodiesel is presented as one of the best alternatives for gradually replacing the use of fossil fuels, but it has some factors that make it economically impractical if it does not have a government support. For this reason, research efforts focused on this area have been responsible for optimizing the process of biodiesel production by different catalytic routes to achieve greater efficiency at a lower cost. In this case, the biggest problem has been the high cost generated by an investigation, which in many occasions is the main factor to decide if an investigation could be carried out. Trying to reduce these costs, in the current study, we are using a technique of glycerol quantification by volumetric methods and comparing obtained results with the chromatographic method, which is conventionally used and comparatively much more expensive. Biodiesel employee was obtained by an enzymatic catalysis process varying one of three process variables：oil：alcohol molar ratio, temperature and proportion of catalyst. The numerical differences obtained between the two quantification methods generated relative errors lower than 10%, resulting in some occasions lower than 1%. By gas chromatography analysis the best yield was obtained at the same conditions of the volumetric method, a temperature of 45 ℃, an oil：alcohol ratio 1：4 and 8 wt.% of catalyst, but a yield of 95.5% and 97.1%, respectively. Due to the high precision of gas chromatography, this method is used to carry out a surface response analysis obtaining as ideal operating conditions a temperature of 43.5 ℃, 8.9 wt.%. of catalyst and an oil：alcohol ratio 1：4.

Optimization on Pretreatment and Enzymatic Hydrolysis of Sugarcane Trash for Ethanol Production

The present study was conducted for the optimization of pretreatment and enzymatic hydrolysis of lignocellulosic biomass （sugarcane trash）, which is a renewable resource for the production of bioethanol. The pretreatment and enzymatic hydrolysis conditions including alkali （NaOH）/dilute acid （H2SO4）, substrate and chemical concentration for pretreatment, enzyme dosage, pH, temperature and substrate concentration for hydrolysis were varied and evaluated for sugar and ethanol production at the end. The optimum condition was accomplished using 15% w/v DS of 0-2 mm sugarcane trash in size of particle. It was pretreated with two steps of 2% w/v NaOH autoclaving followed by 2% w/v H2SO4 autoclaving with washing step after pretreatment. An enzymatic hydrolysis was then performed using 15% w/v DS pretreated substrate, hydrolyzed with cellulase 50 filter paper unit （FPU）/g DS at 50 ℃ and pH 5. After incubating at 160 r for 48 h, 117.16 g/L reducing sugar was obtained. The achieved sugar after enzymatic hydrolysis was finally fermented to ethanol by Saccharomyces cerevisiae TISTR 5596, with concentration of 48.17 g/L ethanol or yield 0.509 g/g reducing sugars which was equal to 99.81% of theoretical yield.

Conversion of Sugarcane Shoots and Leaves into Reducing Sugars by Pretreatment and Enzymatic Hydrolysis

Sugarcane shoots and leaves consist of 38% cellulose, 30.6% hemicellulose and 12.8% lignin on dry solid （DS） basis and have the potential to serve as low cost feedstocks for ethanol production. The pretreatment and enzymatic hydrolysis conditions include particle size, alkali （NaOH）/dilute acid （H2SO4） pretreatment, chemical and substrate concentrations, temperature, autoclaving time for pretreatment, enzyme concentration, pH and temperature for hydrolysis varied were evaluated for conversion of sugarcane shoots and leaves cellulose and hemicellulose to reducing sugar. The optimum conditions were accomplished by using 14% w/v DS of 0-10 mm sugarcane shoots and leaves in particle size, pretreated with 1.5% w/v of dilute sulfuric acid at 121℃, 15 lbs/in2 for 15 min and enzymatic saccharification using 40 FPU/g DS cellulose at 50℃ and pH 5, After incubating at 160 rpm for 12 hrs, 59 g/L or 386,38 mg/g DS of reducing sugar and 50.69% saccharification were obtained.

偶联剂对EP/APP体系燃烧和发烟性能的影响

研究了不同种类偶联剂对聚磷酸铵阻燃环氧树脂(EP/APP)体系拉伸强度、燃烧和发烟性能的影响规律。结果表明,钛酸酯和硅烷都能提高EP/APP体系的拉伸强度。从(EP/APP)体系阻燃性能的提高效果看,钛酸酯比硅烷更好,钛酸酯使EP/APP体系的氧指数从26.5提高到30.9,硅烷使EP/APP体系的氧指数从26.5提高到28.7。但硅烷对(EP/APP)体系的抑烟效果好,硅烷可使EP/APP体系的烟密度等级从76.84降到66.85,而钛酸酯使EP/APP体系发烟量加大,烟密度等级从76.84上升到86.41。研究结果表明,偶联剂在改善阻燃材料力学性能的同时,对体系的燃烧和发烟性能有重要影响。

不同冷冻介质与EPS泡沫箱在模拟冷藏运输中的效果研究

为探究冷冻介质和EPS泡沫箱在模拟冷藏运输中保温效果,分别研究了不同环境温度下,EPS泡沫箱的保温时长变化规律,EPS泡沫箱的厚度和内表面积对保温效果的影响,6种蓄冷介质在EPS泡沫箱中的保温效果。结果表明,在10~35℃的环境温度范围内,EPS泡沫箱的保温时长(Y)与外界温度(X)呈显著负相关,符合拟合方程:Y=73.788e-0.299X(R^2=0.9973)。EPS箱的保温时长与内表面积和厚度符合傅立叶方程式,但是保温时长与二者并不成简单的线性关系。根据保温性能综合比较,保鲜冰袋保温效果最优,其次为水冰瓶和注水冰袋;根据释冷特征,推荐保鲜冰袋与注水冰袋联合使用。研究为各种食品、药品、鲜活水产品在特定情况下运用泡沫箱保活、保鲜运输提供科学依据与实践指导。

俄罗斯某铜厂烟气制酸项目的EPS工程实践

介绍了俄罗斯某铜厂800 kt/a铜冶炼烟气制酸装置的EPS工程实践。详述了该项目的冶炼烟气特点、制酸工艺方案选择及主要设备选型。该装置采用"3+1"二转二吸、ⅢⅠ-ⅣⅡ换热流程,核心设备为内置换热器的转化器,一吸塔和二吸塔共用1台吸收酸循环槽。投入运行后SO2转化率大于或等于99.90%,SO_3吸收率大于99.99%,尾气排放φ(SO_2)小于或等于0.013%。

青海牧区57份自制牦牛乳制品中产EPS乳酸菌的分离鉴定及特性研究

目的从青海牧区牧民家庭自制牦牛乳制品(酸奶、曲拉)中分离产EPS乳酸菌,得到青海地区产EPS乳酸菌种群系统发育树,并鉴定高产EPS乳酸菌,为后期产EPS乳酸菌在乳品工业中的开发及利用提供理论基础。方法随机采集样本,乳酸菌采用Ca CO3的MRS平板法分离,以形态结合生化实验初筛,用分子生物学方法即16s r DNA序列测定、NCBI数据库BLAST比对,构建系统进化树,最终确定乳酸菌种属;用苯酚–硫酸法对乳酸菌进行多糖产量定量分析;用琼脂扩散法行抑菌试验。模拟体外胃肠道环境完成生长实验。结果从57份样品中分离出纯菌种86株,生化试验结合16s r DNA分析确定乳酸菌菌株52株,归属于5个菌属,分别是嗜热乳酸链球菌(33株)、粪肠球菌(6株)、侧孢短芽孢杆菌(4株)、干酪乳杆菌(5株)、嗜酸乳杆菌(4株);产EPS菌株为31株,以嗜热链球菌为主,EPS浓度为(16.09±5.39)mg/L,最高浓度达28.83 mg/L,产量最高的是嗜热链球菌,来自果洛州;抑菌试验中的52株乳酸菌菌株对四种致病菌均有抑制作用,排除强酸和H2O2干扰后,有部分菌株无抑菌圈,且所有菌株抑制病原菌生长的能力较弱。模拟胃肠道生存实验中,不同时间生存率有差异,χ2=247.87(秩和检验值=卡方值),P<0.01,存活率中位数(四分位数间距,%)为:模拟胃液3 h为92.70(91.75,93.54)、肠液3 h为88.54(87.99,89.18)、肠液6 h为84.36(83.21,86.28)、肠液12 h为76.02(74.42,77.21)、肠液24 h为65.43(64.32,66.94),存活率随时间的延长而降低。结论青海传统牦牛发酵乳中主要的优势乳酸菌为嗜热链球菌,其次为粪肠球菌和干酪乳杆菌;青海牧区传统牦牛发酵乳中乳酸菌产EPS产量相对较低;乳酸菌对四种肠道病原菌的抑制作用较弱,其中对大肠杆菌抑制作用最强;乳酸菌抵抗胃酸生长能力较强;在不同胃肠道生长环境(模拟)中乳酸菌存活率有差异;不同菌株间存活率不完全相同。

一种利用EPS平台的道路纵横断面全自动加桩方法

道路纵横断面测量是道路工程测量中定测的主要任务之一,依据《工程测量规范》,道路中线应根据竖曲线的变化适当加桩,因此道路中线与坎、斜坡等地形变化相交处应予加桩。通常在地形复杂度不高的道路工程测量中,自动加桩与人工加桩效率相差不大,若在道路距离较长、地形复杂的条件下,人工加桩不仅工作量大、复杂,而且可能存在一定程度上的遗漏。针对此问题,本文提出了一种在EPS平台下的道路纵横断面全自动加桩方法,将此方法运用到实际项目中,有效地提高了作业人员的生产效率。

EPS加工企业火灾防控探析

近年来,随着EPS相关产业迅速发展,该类场所的火灾发生率也呈逐年上升趋势。由于EPS泡沫塑料属于可燃物质,其表面易积聚静电,在生产过程中,稍有疏忽,容易引发火灾事故。分析归纳了该场所火灾的成因,就该类场所如何消除火灾隐患,防患于未然,提出了相关建议。

Study on the Technologic Optimization for Hydrolysis of Silver carp By-products

The hydrolysis process for Silver carp by-products was studied. Protein hydrolysate was prepared with proteolytic enzyme, Alcalase. Hydrolysis conditions were optimized by the regression model of three factors five levels quadratic rotation perpendicular regressive design. The optimum hydrolysis conditions of hydrolyzing the protein of Silver carp by-products were determined to be concentration of enzyme (E/S) 3.33%, pH 8.54, hydrolyzing temperature 58 ℃, reaction time 90 min, concentration of substrate 8%. Nitrogen recovery was more than 75%.

关于EPS企业职业危害因素分析与讨论

对某EPS企业生产岗位或工种存在的粉尘、毒物、噪声、工频电场等职业病危害因素进行现场调查和检测,通过对其工艺流程及相关设备的操作过程进行分析,确认生产过程中的职业病危害因素产生的原因及分布。通过对检测结果数据进行分析与讨论,找到EPS企业职业病危害因素来源,了解其职业病危害控制效果,确认EPS企业职业病危害因素关键控制点,为在建或已建EPS企业提供职业危害因素预防措施。

香荚兰浸膏的制备和酶促生香工艺优化

为探究香荚兰浸膏的酶促生香工艺,对香荚兰浸膏进行β-葡萄糖苷酶酶解并对酶解条件进行研究。以香荚兰豆荚为试材,采用乙醇为提取溶剂,索式提取法制备香荚兰浸膏。在单因素试验的基础上,采用正交试验优化酶促生香工艺,提取物中香兰素含量以高效液相色谱法(HPLC)测得。结果表明,最佳酶促生香工艺条件为:加酶量62.5 U/g,酶解温度35℃,酶解时间26 h,料液比1∶8(g/mL),该工艺条件下香荚兰浸膏中香兰素含量最高。上述结果表明酶促生香工艺可明显提高香荚兰浸膏中香兰素的含量,具有潜在的生产应用价值。

鱿鱼加工副产物酶解液美拉德反应工艺优化

鱿鱼加工过程中会产生20%左右的副产物,其中富含蛋白质、氨基酸等多种营养成分和呈味成分。本研究采用双酶酶解工艺制备了鱿鱼加工副产物酶解液,以感官评分为指标,通过单因素和正交试验优化了鱿鱼加工副产物酶解液与大豆多糖-葡萄糖美拉德反应工艺。实验结果表明:在pH值8.0、温度110℃、葡萄糖-多糖添加量4%(ω(葡萄糖)∶ω(大豆多糖)=3∶1)、时间60 min的条件下,酶解液的感官评分值最高,反应产物具有明显的鱿鱼香气,口味鲜美。电子舌结果显示,美拉德处理前后的酶解液风味变化明显,表明美拉德反应可以改善酶解液的味道。本研究为鱿鱼加工副产物的综合利用和水产调味料的开发提供了思路。

褐藻胶的酶法降解及其产物的体外免疫活性

本研究以褐藻胶为底物,探究其在褐藻胶酶法降解过程中的分子质量变化以及酶法降解制备褐藻胶低聚糖的工艺参数,并在此基础上,评价了不同分子质量褐藻胶酶解产物的体外免疫活性。结果表明,褐藻胶经褐藻胶裂解酶降解后分子质量显著下降,通过乙醇分级分离可获得3种不同分子质量的降解产物,其重均分子质量分别为13.4、5.73kDa和3.85kDa。单因素试验优化获得酶法制备褐藻胶低聚糖的最适工艺参数为pH7.0、褐藻胶裂解酶用量15U/g(底物质量计)、酶解时间24h,此时,褐藻胶低聚糖得率为28.05%。利用小鼠巨噬细胞模型对褐藻胶及其3种分子质量降解产物的体外免疫活性进行评价,发现褐藻胶及其酶解产物均具有一定的免疫增强活性,且重均分子质量为5.73kDa的酶解组分免疫增强活性最好,优于褐藻胶低聚糖。同时,通过添加巨噬细胞受体蛋白Toll样受体4(Toll-like receptor 4,TLR4)的阻断剂(TAK-242),验证了褐藻胶酶解产物通过诱导巨噬细胞TLR4的分泌,引起级联反应,增加NO、肿瘤坏死因子-α和白细胞介素6的分泌,从而调节巨噬细胞免疫活性。研究结果可为褐藻胶高值化利用提供理论依据。

三叶木通果汁饮料加工工艺研究

为丰富果汁饮料的类型,以三叶木通果实为原料,经过热烫、酶解等工艺得到三叶木通果汁,调配得到三叶木通果汁饮料;采用正交试验,以感官评分为评价指标,优化果汁饮料的配方,并对饮料的稳定性及营养成分进行测定。结果表明,三叶木通果汁提取工艺为果胶酶∶纤维素酶=1∶1,加酶量0.05%,酶解温度45℃,酶解时间40 min,此时果汁具有较高的可溶性固形物含量;在亲水胶体添加总量0.12%,黄原胶∶瓜尔豆胶∶刺槐豆胶=2∶2∶1,均质压力30 MPa,处理一次时,果汁具有较好的稳定性。通过正交优化实验得到饮料最佳配方为果汁添加量25%,柠檬酸添加量0.1%,木糖醇添加量5%;营养成分分析得出三叶木通果汁饮料营养丰富,果糖、钾等含量较高,为三叶木通果汁的开发提供参考。

添加不同分子量酶解魔芋葡甘聚糖的冻藏肌原纤维蛋白氧化和结构特性变化

该研究比较了添加三种分子量分别为149.03、118.75和36.48 ku的魔芋葡甘聚糖酶解产物EK1、EK2和EK3对草鱼肌原纤维蛋白在-18℃冻藏过程中物理、化学和结构特性的变化,通过盐溶性蛋白含量、Ca^(2+)-ATPase活性、总巯基、表面疏水性、粒径、Zeta电位、SDS-PAGE、紫外和荧光光谱分析其变化特征。研究结果表明,与空白对照组、商业抗冻剂、EK1和EK2相比,冻藏20 d,EK3组的盐溶性蛋白浓度和总巯基含量最大,分别为1.51 mg/mL和19.76×10^(-5)mol/g。与此同时,冻藏30 d,EK3组的Ca^(2+)-ATPase活性含量最大,且表面疏水性和Zeta电位最小,分别为1.31μmol Pi(/mg prot·h)、8689.07和-13.35 mV。冻藏30 d,SDS-PAGE结果表明EK3组的肌球蛋白和肌动蛋白降解程度最小,有利于抑制肌原纤维蛋白的氧化。冻藏30 d,紫外和荧光光谱结果表明EK3组的色氨酸和酪氨酸残基的暴露程度减小,有利于维持蛋白空间结构稳定性。因此,该实验添加小分子量的魔芋葡甘聚糖酶解产物EK3(36.48 ku)对肌原纤维蛋白冷冻保护作用最佳,这为水产品冷冻过程中使用小分子多糖作为抗冻剂提供了理论支持。

饲用木聚糖酶的生物学功能及其在畜禽生产中的应用

饲用木聚糖酶是能够分解植物性饲料原料细胞壁中木聚糖的一类酶,可通过水解木糖苷键,降解饲料中的木聚糖,削弱其抗营养作用,在提高营养物质的消化率、改善肠道健康、增强免疫功能、改善畜禽生产性能等方面发挥着积极作用,是一类绿色、高效的饲料添加剂。然而,木聚糖酶也可能在消化过程中带来负面影响,如过量添加可能导致食糜黏度升高。本文综述了饲用木聚糖酶的生物学功能及木聚糖酶在畜禽生产中的应用,以期为木聚糖酶的研究和应用提供理论依据。