酸法脱酰胺修饰对刺芹侧耳蛋白质消化性和功能特性的影响

为研究酸法脱酰胺修饰对刺芹侧耳蛋白质的功能特性和消化性的影响,本研究以刺芹侧耳粉为原料,通过碱提酸沉法提取刺芹侧耳蛋白质,并采用0.175mol/L盐酸、57.5℃改性,改性时间为121min 5s,制备出脱酰胺修饰蛋白质,探索脱酰胺改性对蛋白质的消化性及功能特性的影响。结果表明：脱酰胺修饰可提高刺芹侧耳蛋白质的溶解性、持油性、起泡性和乳化性,但对其持水性的改善作用不明显;同时脱酰胺修饰蛋白质表面疏水性和荧光强度增大,蛋白质巯基和二硫键含量变化不明显;体外消化率提高,消化产物的多肽含量降低,游离氨基酸含量增大。酸法脱酰胺修饰可在一定程度上有效改善蛋白质的功能特性和提高蛋白质的体外消化水平。     

四季豆幼苗中尿囊酸酰胺水解酶的一些特性

酰脲代谢在许多固氮豆科植物氮素代谢中起重要作用;尿囊酸的酰胺水解酶(EC3.5.3.9)分解尿囊酸成为脲基乙醇酸和CO2、NH3,脲基乙醇酸的酰胺水解酶进一步分解脲基乙醇酸产生乙醛酸和CO2、NH3.该文首次报告测定四季豆尿囊酸降解酶(分解尿囊酸的酶)的方法,酶反应基质需要盐酸苯肼存在.在四季豆干种子、幼苗根、茎和叶,均可测出尿囊酸降解酶活力.从四季豆幼苗分离出两个尿囊酸降解酶.一个分子量大于200 kD,另一个分子量为13.5 kD;小分子量的尿囊酸降解酶(没有脲基乙醇酸酰胺水解酶或脲酶活力)用于性质研究.酶反应产物分析表明,该酶是尿囊酸的酰胺水解酶.该酶反应的最适pH为8.5.Mn2 是该酶的金属辅助因子.Km为76μmol/L,Vmax为16.7 nKat/mg(=1 002 nmol min1mg1).乙醛酸和乙醇酸抑制该酶活力.赖氨酸残基和色氨酸残基是酶活力的必需基团;巯基和酪氨酸残基不是酶活力的必需基团.     

大肠杆菌青霉素酰胺酶高产菌株的选育

应用青霉素酰胺酶裂解青霉素制备半合成青霉素原料6-氨基青霉烷酸(简称6-APA),具有安全、节省费用等优点。为了提高青霉素酰胺酶活力,我们开展了大肠杆菌青霉素酰胺酶的菌种选育工作。     

木质纤维素稀酸水解糖液乙醇发酵研究进展

以木质纤维素为原料生产燃料乙醇,首先要对原料进行预处理得到可发酵糖,在稀酸水解木质纤维素得到的糖液中,除含有葡萄糖、木糖等六碳糖和五碳糖外,根据水解温度、酸浓度和时间的不同,还含有不同浓度的发酵抑制剂。因此,在研究木质纤维素稀酸水解糖液的乙醇发酵中,对代谢木糖成乙醇的菌种的研究、对耐/代谢发酵抑制剂微生物的研究、对稀酸水解糖液的脱毒方法的研究以及对稀酸水解糖液不同发酵方式的乙醇发酵研究等非常重要。重点介绍了以上几个方面近几年研究的进展。     

真养产碱杆菌112R4的二羧酸单酰胺酰胺水解酶

在一株具有环酰亚胺转化活性的真养产碱杆菌112R4中发现了一种特异性的二羧酸单酰胺酰胺水解酶（半酰胺酶）,它催化环酰亚胺代谢的第二步反应,将二羧酸单酰胺水解为二羧酸和氨。该酶的底物仅限于此代谢途径的第一个酶——酰亚胺酶的产物二羧酸单酰胺,而对其它的酰胺类化合物没有明显水解活性。真养产碱杆菌112R4中的半酰胺酶和酰亚胺酶在表达上具有相关性,环酰亚胺（如琥珀酰亚胺）和二羧酸单酰胺（如琥珀酰胺酸）对它们有正调控作用,游离氨离子显示出负调控作用,琥珀酸则在酶合成和活性两方面均表现出影响作用。对重组大肠杆菌中表达的半酰胺酶粗酶的部分性质进行了研究。钴离子对半酰胺酶的活性表现出促进作用,比活力提高到3.37倍,表明半酰胺酶可能是一种金属结合酶。     

乙醇法提取桃花精油的工艺研究及桃花精油的成分分析

本文研究了用乙醇法提取桃花精油,通过正交试验的方法得到了乙醇抽提桃花精油的较优工艺条件,对其多酚和黄酮含量进行了测定,并对所得的桃花精油进行了气相色谱质谱(GC-MS)分析。结果表明,对乙醇提取桃花精油影响最大的因素是抽提时间,其次是料液比,影响最小的是桃花形态。乙醇抽提桃花精油的较优工艺条件是抽提时间为6h,料液比为1∶150(m∶V),桃花形态为粉末。此时,黄酮含量为0.24%,多酚含量为0.067%。桃花精油含有大量的酯、酸、酰胺和腈类化合物以及少量的酚、酮和多糖。     

沙柳原料高浓度底物酶解发酵乙醇工艺

为了提高沙柳生物转化过程的经济可行性,考察了沙柳原料经过蒸爆、超微粉碎+稀酸、超微粉碎+稀碱预处理后高浓度底物补料酶解的效果,并对其高浓度水解糖液进行了乙醇发酵。结果表明:蒸爆处理法水解效果最好,通过补料酶解,底物质量分数可以达到30%,酶解液中总糖质量浓度达到132 g/L,葡萄糖质量浓度105 g/L;超微粉碎+稀酸预处理原料底物质量分数可以达到22%,酶解液中总糖质量浓度达到123 g/L,葡萄糖质量浓度73 g/L;超微粉碎+稀碱预处理原料底物质量分数可以达到22%,酶解液中总糖质量浓度133 g/L,葡萄糖质量浓度77 g/L。3种预处理使沙柳原料的酶解糖液都可以较好地被酿酒酵母利用发酵产乙醇,蒸爆处理原料的酶解糖液乙醇发酵效果最好,乙醇质量浓度达到47 g/L。     

木质纤维素预处理技术研究进展

详细评述了木质纤维素的预处理工艺研究进展,特别是浓酸低温水解-酸回收工艺、稀酸二阶段水解工艺、金属离子在稀酸水解过程中的助催化作用以及水蒸汽爆裂、氨纤维爆裂、CO2爆裂、酶催化水解等方法的研究进展情况。木质纤维素原料预处理技术发展为发酵生产乙醇技术的研究开发奠定了坚实基础。     

紫锥菊单咖啡酰酒石酸和菊苣酸提取工艺优化

采用正交试验设计,选取乙醇体积浓度百分比、提取温度、提取时间、抗氧化剂用量等因素,优化紫锥菊Echinacea purpurea单咖啡酰酒石酸和菊苣酸的加热回流提取工艺,并考察加入抗氧化剂对提取效果的影响。结果表明,优化的提取条件是以25%乙醇,在80 ℃回流提取90 min。抗氧化剂用量对提取效果影响不显著。优化后的加热回流提取条件对紫锥菊单咖啡酰酒石酸和菊苣酸的提取均适用,提取中无需加入抗氧化剂。     

柚皮果胶提取的工艺优化

果胶是在食品、医药和其它工业中应用的重要多糖之一,具有良好的胶凝化和乳化稳定作用,其用途很广。而据数据统计,果胶约占整个柚子总果胶重量的40%左右。因此,本论文以柚子皮为原料,用单因素和正交试验对酸水解乙醇沉淀法提取果胶的工艺进行优化。结果表明果胶提取的最优条件为:酸度为pH=2,提取温度为90℃,提取时间为70min。     

Advanced material modelling in numerical simulation of primary acetabular press-fit cup stability

Primary stability of artificial acetabular cups, used for total hip arthroplasty, is required for the subsequent osteointegration and good long-term clinical results of the implant. Although closed-cell polymer foams represent an adequate bone substitute in experimental studies investigating primary stability, correct numerical modelling of this material depends on the parameter selection.

Material parameters necessary for crushable foam plasticity behaviour were originated from numerical simulations matched with experimental tests of the polymethacrylimide raw material. Experimental primary stability tests of acetabular press-fit cups consisting of static shell assembly with consecutively pull-out and lever-out testing were subsequently simulated using finite element analysis.

Identified and optimised parameters allowed the accurate numerical reproduction of the raw material tests. Correlation between experimental tests and the numerical simulation of primary implant stability depended on the value of interference fit. However, the validated material model provides the opportunity for subsequent parametric numerical studies.     

Advanced material modelling in numerical simulation of primary acetabular press-fit cup stability

Primary stability of artificial acetabular cups, used for total hip arthroplasty, is required for the subsequent osteointegration and good long-term clinical results of the implant. Although closed-cell polymer foams represent an adequate bone substitute in experimental studies investigating primary stability, correct numerical modelling of this material depends on the parameter selection. Material parameters necessary for crushable foam plasticity behaviour were originated from numerical simulations matched with experimental tests of the polymethacrylimide raw material. Experimental primary stability tests of acetabular press-fit cups consisting of static shell assembly with consecutively pull-out and lever-out testing were subsequently simulated using finite element analysis. Identified and optimised parameters allowed the accurate numerical reproduction of the raw material tests. Correlation between experimental tests and the numerical simulation of primary implant stability depended on the value of interference fit. However, the validated material model provides the opportunity for subsequent parametric numerical studies.     

Features of the mechanical treatment of rice husk for the performance of the solid-phase reaction of silicon dioxide with polyphenols

The distinguishing features of rice husk are high strength properties, chemical stability, high ash content, and low nutritional value, which are determined by the composition and structure of this type of raw material. The goal of the study was to determine optimal methods of mechanical treatment for the performance of a solid-phase reaction of silicon dioxide from rice husk with polyphenol compounds. Different regimes of the treatment of plant raw material have been compared. It has been shown that, for the solid-phase reaction of silicon dioxide from plant raw material with polyphenol compounds to occur, both the destruction of the supramolecular complex of silicon dioxide with the lignocellulose matrix, which is accomplished by fine grinding, and the plastic deformation of the silicon dioxide phase with the formation of reaction centers are necessary. These operations can be brought about using grinders with the attrition and shear modes of operation, including roller mills. It is preferable that silicon dioxide is in the composition of plant raw material since the reaction between silicon dioxide and polyphenols with the formation of surface complexes requires the presence of silanol groups. If silicon dioxide is derived from rice husk by conventional methods, most hydroxyl groups are eliminated, which significantly decreases the reactivity.     

Mechanism investigation for poloxamer 188 raw material variation in cell culture

Variability in poloxamer 188 (P188) raw material, which is routinely used in cell culture media to protect cells from hydrodynamic forces, plays an important role in the process performance. Even though tremendous efforts have been spent to understand the mechanism of poloxamer's protection, the root cause for lot‐to‐lot variation was not clear. A recent study reported that the low performance was not due to toxicity but inefficiency to protect cells (Peng et al., Biotechnol Prog. 2014;30:1411–1418). In this study, it was demonstrated for the first time that the addition of other surfactants even at a very low level can interfere with P188 resulting in a loss of efficiency. It was also found that the performance of P188 lots correlated well with its foam stability. Foam generated from low performing lots in baffled shaker flask lasts longer, which suggests that the components in the foam layers are different. The spiking of foam generated from a low performing lot into the media containing a high performance lot resulted in cell damage and low growth. Analytical studies using size exclusion chromatography (SEC) identified differences in high molecular weight (HMW) species present in the P188 lots. These differences are much clearer when comparing the HMW region of the SEC chromatogram of foam vs. bulk liquid samples. This study shows that low performing lots have enriched HMW species in foam samples due to high hydrophobicity, which can be potentially used as a screening assay. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:767–775, 2016     

Filtration, haze and foam characteristics of fermented wort mediated by yeast strain

AIMS: To investigate the influence of the choice of yeast strain on the haze, shelf life, filterability and foam quality characteristics of fermented products. METHODS AND RESULTS: Twelve strains were used to ferment a chemically defined wort and hopped ale or stout wort. Fermented products were assessed for foam using the Rudin apparatus, and filterability and haze characteristics using the European Brewing Convention methods, to reveal differences in these parameters as a consequence of the choice of yeast strain and growth medium. CONCLUSIONS: Under the conditions used, the choice of strain of Saccharomyces cerevisiae effecting the primary fermentation has an impact on all of the parameters investigated, most notably when the fermentation medium is devoid of macromolecular material. SIGNIFICANCE AND IMPACT OF THE STUDY: The filtration of fermented products has a large cost implication for many brewers and wine makers, and the haze of the resulting filtrate is a key quality criterion. Also of importance to the quality of beer and some wines is the foaming and head retention of these beverages. The foam characteristics, filterability and potential for haze formation in a fermented product have long been known to be dependant on the raw materials used, as well as other production parameters. The choice of Saccharomyces cerevisiae strain used to ferment has itself been shown here to influence these parameters.     

Determination of elastomeric foam parameters for simulations of complex loading

BACKGROUND: Finite element (FE) analysis has shown promise for the evaluation of elastomeric foam personal protection devices. Although appropriate representation of foam materials is necessary in order to obtain realistic simulation results, material definitions used in the literature vary widely and often fail to account for the multi-mode loading experienced by these devices. This study aims to provide a library of elastomeric foam material parameters that can be used in FE simulations of complex loading scenarios. METHOD OF APPROACH: Twelve foam materials used in footwear were tested in uni-axial compression, simple shear and volumetric compression. For each material, parameters for a common compressible hyperelastic material model used in FE analysis were determined using: (a) compression; (b) compression and shear data; and (c) data from all three tests. RESULTS: Material parameters and Drucker stability limits for the best fits are provided with their associated errors. The material model was able to reproduce deformation modes for which data was provided during parameter determination but was unable to predict behavior in other deformation modes. CONCLUSIONS: Simulation results were found to be highly dependent on the extent of the test data used to determine the parameters in the material definition. This finding calls into question the many published results of simulations of complex loading that use foam material parameters obtained from a single mode of testing. The library of foam parameters developed here presents associated errors in three deformation modes that should provide for a more informed selection of material parameters.     

Effects of jet-fuel microbial isolates on a polyurethane foam

Jet-fuel microbial isolates were studied for effects on a polyurethane foam material that has been proposed as a baffling material for use in aircraft fuel tanks. Evidence was found that a polyesterurethane foam gave increased cell counts and oxygen uptake with a bacterial isolate, and extensive matting with fragmentation and decreases in tensile strength of the foam with a fungal isolate. The polyurethane foam was affected by activity of the jet-fuel microbial isolates to an extent that would cause serious microbiological problems in the fuel tanks of jet aircraft.     

L-酪氨酸苄酯的合成及其影响因素研究

以L-酪氨酸和苯甲醇为原料合成一种新型的L-酪氨酸衍生物——L-酪氨酸苄酯。首先用苯甲醇与氯化亚砜反应生成氯化亚硫酸酯,合成物再与L-酪氨酸发生酯化反应得到L-酪氨酸苄酯,其结构经质谱(MS)分析法确证。在此基础上研究了影响该合成工艺的主要因素,即原料配比、反应温度、反应时间、pH值。结果显示合成L-酪氨酸苄酯的较佳工艺条件为:物料摩尔比mol(SOCl2)∶mol(L-酪氨酸)=1.3∶1.0,室温下反应3h,120℃下反应2h,后处理溶液pH为7.5。本工艺适宜于工业化大规模生产。     

Determination of elastomeric foam parameters for simulations of complex loading

Background: Finite element (FE) analysis has shown promise for the evaluation of elastomeric foam personal protection devices. Although appropriate representation of foam materials is necessary in order to obtain realistic simulation results, material definitions used in the literature vary widely and often fail to account for the multi-mode loading experienced by these devices. This study aims to provide a library of elastomeric foam material parameters that can be used in FE simulations of complex loading scenarios.

Method of Approach: Twelve foam materials used in footwear were tested in uni-axial compression, simple shear and volumetric compression. For each material, parameters for a common compressible hyperelastic material model used in FE analysis were determined using: (a) compression; (b) compression and shear data; and (c) data from all three tests.

Results: Material parameters and Drucker stability limits for the best fits are provided with their associated errors. The material model was able to reproduce deformation modes for which data was provided during parameter determination but was unable to predict behavior in other deformation modes.

Conclusions: Simulation results were found to be highly dependent on the extent of the test data used to determine the parameters in the material definition. This finding calls into question the many published results of simulations of complex loading that use foam material parameters obtained from a single mode of testing. The library of foam parameters developed here presents associated errors in three deformation modes that should provide for a more informed selection of material parameters.     

Contribution of Disulfide Bonds to the Characteristics of Casein Micelles

Drainage in foam was analyzed by the capillary model proposed by Haas and Johnson. Foam was produced by introducing air into an ovalbumin solution through a spinneret. The electric conductivity at selected positions in the foam and the drained liquid height below the foam were measured at constant intervals. The measured electric conductivity was converted to the liquid volume fraction by Prager’s equation. The capillary model described well not only the liquid leakage rate from foam but also the liquid volume fraction in foam. The ratio of the liquid volume fraction in foam to the volume fraction of the Plateau border was much larger than the value estimated from Haas and Johnson’s result. It was confirmed that a time constant, T, involved in the model was suitable for estimating foam stability only by one parameter. However, T is affected not only by material characteristics but also by the foam height. On the other hand, since the ratio of the liquid volume fraction in foam to the volume fraction of the Plateau border reflects the material characteristics, it may be used for comparing the foam stability between materials with the same viscosity and density.