赤霉酸分子印迹聚合物及印迹膜的制备与性能研究

以赤霉酸(GA3)为印迹分子,改变功能单体与致孔剂种类合成了四个分子印迹聚合物(MIP1-4)及两个分子印迹膜(MIM1-2).采用紫外光度法分别测定了印迹分子分别与功能单体丙烯酰胺(AM)和甲基丙烯酸(MAA)间的结合常数和化学计量比(n＝2).平衡结合实验研究表明,以AM为单体制备的MIP1对印迹分子GA3具有更高的结合量和良好的印迹效率.膜渗透及膜过滤实验表明,以AM为单体制备的MIM1对GA3分子具有一定的选择性分离性能.     

丙交酯-乙交酯共聚中的酯交换及共聚物结构和性质研究

以辛酸亚锡为催化剂 ,通过本体开环聚合合成了不同摩尔比的DL 丙交酯 乙交酯 (DL LA GA)共聚物 (PDL LGA) .1 H和1 3C NMR以及DSC结果表明 ,共聚物中GA结构单元的含量略高于按GA投料比计算的结果 ,聚合过程中存在二级酯交换反应 .当聚合温度为 16 0℃时 , GG 序列的平均长度 (lGG)随GA摩尔投料比增大而增长 ,而 LL 序列的平均长度 (lLL)则相反 .研究发现 ,随着GA摩尔投料比降低 , LL 单元的二级酯交换系数 (TⅡ[GLG])下降 ,至GA摩尔投料比达到为 5 0 %时最小 ,而后却逐渐增大 .L LA与GA在同样的条件下聚合 ,TⅡ[GLG]和lGG 都比DL LA与GA聚合的大 .聚合温度升高 ,TⅡ[GLG]增大 ,意味着二级酯交换反应加剧 ,但DL LA GA摩尔投料比较高 (75 2 5 )的共聚物的lGG 值有所下降 ,lLL值变化不大 ,而DL LA GA摩尔投料比较低 (5 0 5 0 )的共聚物的lGG值则变化不大 ,lLL值有所下降 ,说明聚合反应还受共聚单体的投料比和其它因素影响 .升高聚合温度比在较低温度下延长反应时间更有效改变共聚物的链结构 .在一定温度下聚合 ,共聚产物的Tg 随GA摩尔投料比增大而有规律降低和在氯仿中的溶解性下降 ;而DL LA GA摩尔投料比一定时 ,聚合温度对共聚物的Tg 的影响较为复杂 ,这与聚合温度对共聚物的链结构影响较大有关 .     

高效液相色谱法同时测定鸭梨种子中3种内源激素

建立了高效液相色谱同时测定鸭梨种子中3种内源激素赤霉素(GA3)、生长素(IAA)和脱落酸(ABA)含量的方法.采用C18反相色谱柱,柱温35 ℃,以甲醇-水(含1%乙酸)(4∶ 6, V/V)为流动相,流速为1 mL/min, 检测器波长开始用254 nm, 2.5 min时将波长切换至210 nm,至3.8 min,GA3出峰结束后,再次将波长切换回254 nm测定IAA和ABA.GA3、IAA和ABA的平均回收率分别为92.8%、91.6%和94.7%.为快速、准确分离和测定鸭梨种子内源激素提供了一种可靠方法.     

碳量子点/纳米金@碳纳米管修饰电极同时检测鸟嘌呤和腺嘌呤

制备了一种碳量子点(CQDs)/金纳米颗粒(AuNPs)@羟基化多壁碳纳米管(MWCNT-OHs)复合膜修饰电极用于鸟嘌呤(GA)和腺嘌呤(AE)的同时检测.与裸电极和其它修饰电极相比,复合膜修饰电极能显著提高GA和AE的氧化峰电流及峰电位差,能够对GA和AE同时高灵敏检测.研究了GA和AE在复合膜修饰电极上的电化学行为,结果表明,在0.2 mol/L PBS(pH 7.0)中,GA和AE的氧化峰电流与浓度分别在1～200 μmol/L和2～80μmol/L范围内呈良好的线性关系,检测限分别为0.9和1.8 μmol/L.将该修饰电极用于人体血清样品中GA和AE的同时电化学检测,加标回收率在90.4％～107.4％之间,证明了该修饰电极在生物样品分析领域的应用潜力.     

高效液相色谱法测定菌肥中赤霉素和吲哚乙酸含量方法研究

建立了一种高效液相色谱法分离测定赤霉素(GA3)和吲哚乙酸(IAA)的方法.采用Agilent ZORBA×300SB-C18(4.6 mm×250 mm)色谱柱,以甲醇∶水=35∶65,(V/V,含2%冰醋酸)为流动相,柱温为25℃,流速为0.5 mL/min.系统讨论了流动相组成及pH对分离的影响.本法测定GA3和IAA的线性范围分别为25.0~1 000μg/mL、2.5~50.0μg/mL.方法回收率分别为85.63%、90.21%.并将该方法成功应用于菌肥中GA3和IAA的含量测定,为该类产品的质量控制提供了快速有效的方法.     

17-[3,6-二氧杂-8-N-(取代肉桂酰基)辛二胺]-17-去甲氧基格尔德霉素新颖衍生物的合成

格尔德霉素(geldanamycin,GA)是一个以热休克蛋白90(Hsp90)为靶点的高效抗肿瘤先导物,但其临床应用受到了肝脏毒性的限制.目前通常对其C-17位进行修饰,以保留活性和降低肝毒性.本研究提出了一种GA结构修饰的新思路,即在GA的C-17位引入烷胺基链,进而接入保肝基团肉桂酰基.报道了26个17-(3,6-二氧杂-8-N-(取代肉桂酰基)辛二胺)-17-去甲氧基GA新颖衍生物的合成;体外人乳腺癌细胞株MDA-MB-231生长抑制实验和靶点亲和实验结果表明,化合物3u有明显细胞毒性和靶点选择性(IC50=1.5μmol/L,Kd=1.14μmol/L);并对该类衍生物的构效关系进行了讨论,对深入开展GA结构修饰的相关研究有参考价值.     

超支化聚酯低压纳滤膜的制备与表征

通过超支化聚酯(HPE)末端的羟基与戊二醛(GA)之间的羟醛缩合反应,采用简单的浸涂-交联方法,制备了一种以聚砜超滤膜为支撑层,交联的HPE为活性分离层的复合纳滤膜.采用衰减全反射红外光谱(ATR-FTIR)、接触角测定、扫描电子显微镜(SEM)对纳滤膜的表面化学组成、亲水性和膜形貌进行了表征.考察了HPE溶液浓度、GA溶液浓度对膜分离和渗透性能的影响,优化的HPE和GA溶液浓度分别为9.8 g/L和7.4 g/L,此时在0.4 MPa下膜的水通量达69.6 L/(m2.h),对Na2SO4脱除率为93.2%,表现出低操作压力、高通量、高脱盐率的优异性能.纳滤膜对无机盐的截留顺序为Na2SO4>NaCl>MgSO4>MgCl2,呈现明显的荷负电特征.     

蜂窝状C3N4/CoSe2/GA复合光催化剂的制备及CO2还原性能

以六水金氯化钴、 硒粉和尿素为前驱体, 通过水热法合成C₃N₄/CoSe₂纳米粒子, 再将其锚定在石墨烯气凝胶（Graphene aerogel, GA）表面, 制备蜂窝状C₃N₄/CoSe₂/GA光催化剂. 采用X射线衍射(XRD)、 X射线光电子能谱(XPS)、 扫描电子显微镜(SEM)、 透射电子显微镜(TEM)和紫外-可见漫反射光谱(UV-Vis DRS)等手段对材料的结构、 形貌和光学性能进行表征. 同时以氙灯作为模拟可见光光源, 通过CO₂光催化还原为CO考察所制备纳米材料的光催化活性. 结果表明, 在C₃N₄纳米片表面引入了CoSe₂和GA并制备出蜂窝状结构 C₃N₄/CoSe₂/GA催化剂, 通过GA, CoSe₂与C₃N₄耦合可以显著提高光吸收密度以及扩展光响应范围, 呈现了更低的荧光强度和最大的电子转移速率. 在同种光催化下, C₃N₄/CoSe₂/GA对CO₂还原催化效率最大, CO产量达到5.75 μmol·g^-1·h^-1, 并且重复使用性能良好.     

Application of Genetic Algorithm to the QSAR Research of Pyrrolobenzothiazepinones and Pyrrolobenzoxazepinones-Novel and Specific Non-Nucleoside HIV-1 Reverse Transcription Inhibitors

Quantitativestructure-activityrelationship(QSAR)modelingprovidesarationalbasisforunderstandingmechanismsofbiologicalperformanceandformodifyingchemicalstfucturetoimProveperformancebyaltCringchemicalstIuctllre.Itiswellknownthatoneofthemostimportantanddiffcultproblemintraditionalquantitativestructure-activityrelationshipistheproperchoiceoftheadequatefeaturesforbuildingtheregressionmodels.Recentlysomereportssuggestthatgeneticalgorithms(GA)maybeusefulinQSARanalysis.WehavedevelopedaQSARprogra…     

Affinity Adsorption of Bilirubin on Cibacron Blue F3GA-modified Microporous Polytetrafluoroethylene Capillary

Bilirubin removal from human plasma was obtained via an affinity microporous polytetrafluoroethylene(MPTFE) capillary.The new adsorbent comprised grafted glycidyl methacrylate(GMA) via radiation-induced polymerization as hydrophilic coating and reactive sites;ethylenediamine(EDA) as a spacer arm;Cibacron Blue F3GA(CB F3GA) as an affinity ligand;MPTFE capillary as the supporting matrix.The average density of CB F3GA attachment to MPTFE capillaries was found to be 136.5 μmol/g.The capacity of bilirubin adsorbed on affinity MPTFE capillaries is 76.1 mg bilirubin/g polymer(at 25°C).This new adsorbent has advantages over both membrane and traditional micro-column,and this system is stable and easy to operate.The results of blood tests suggest the CB F3GA affinity capillary has good blood compatibility.     

Immobilization of glucoamylase onto novel porous polymer supports of vinylene carbonate and 2-hydroxyethyl methacrylate

Glucoamylase was immobilized onto novel porous polymer supports. The properties of immobilized glucoamylase and the relationship between the activity of immobilized enzyme and the properties of porous polymer supports were investigated. Compared with the native enzyme, the temperature profile of immobilized glucoamylase was widened, and the optimum pH was also changed. The optimum substrate concentration of immobilized glucoamylase was higher than that of native enzyme. After storage for 23 d, the immobilized glucoamylase still maintained about 84% of its initial activity, whereas the native enzyme only maintained about 58% of the initial activity. Moreover, after using repeatedly seven times, the immobilized enzyme maintained about 85% of its initial activity. Furthermore, the properties of porous polymer supports had an effect on the activity of the immobilized glucoamylase.     

Investigations of stabilities,pH, and temperature profiles and kinetic parameters of glucoamylase immobilized on plastic supports

The covalent immobilization of glucoamylase on new epoxide-, isocyanate-, acid chloride-, and carboxylic acid-activated plastic supports shows the viability of such supports for immobilizing enzymes (especially those reacting with 1,6-diaminohexane and glutaraldehyde) for producing side arms. The operational stability of immobilized glucoamylase could be extended by crosslinking the enzyme, by increasing the substrate concentration, or by extending the support’s side arm. The pH curves for the immobilized enzyme were in general not found to be shifted from the pH optimum of the soluble enzyme. However, the immobilized enzyme’s temperature activity profiles were shifted to a lower temperature range when compared to the soluble enzyme. The immobilized glucoamylase Michaelis constants increased, and the maximum rates and specific activities decreased with respect to the soluble enzyme kinetic parameters.     

壳聚糖–精氨酸树脂固定化胰凝乳蛋白酶及其性质

以自制的多孔、具柔性亲水手臂的壳聚糖–精氨酸树脂为载体,戊二醛为交联剂固定胰凝乳蛋白酶,确定了酶与载体的最佳比例为20 mg酶/g湿树脂,交联剂的最佳用量为10 mL 1.0%戊二醛/1.5 g湿树脂,交联时间为60 min,所得固定化酶的活力回收率达68.95%。固定化胰凝乳蛋白酶的Km为8.36 mg/mL,比游离酶增大1.52倍,其酶促反应10 min达到最大速率,具有接近游离酶的催化时间进程曲线;其最适温度为70 ℃,比游离酶升高10 ℃;其最适pH值为5.92,比游离酶酸性偏移2个pH值。此外,固定化胰凝乳蛋白酶具有良好的热稳定性和贮存稳定性,75 ℃时的半衰期为8 h,4 ℃时的半衰期为46天。     

重氮法固定化糖化酶活力和稳定性

本文以苯氨基磺酸型多孔聚苯乙烯为载体，重氮化活化其苯氨基与糖化酶上的氨基反应。在固定化酶过程中，随反应时间的延长，不但固定化酶总活力增加，而且其比活和热稳定性也随之升高，最终可得活力为２００００Ｕ／ｇ干胶，比活为５００的高活力固定化酶，该固定化酶在ｐＨ４．５，６０℃无底物下保温，其半寿期是天然酶的５倍。以麦芽糖，糊精（分子量为１５００）和可溶性淀粉为底物测定该固定化酶活力表明：对某种孔度一定的载体     

Enzymes immobilized on montmorillonite: comparison of performance in batch and packed-bed reactors

Summary The enzymes a-amylase, invertase and glucoamylase were immobilized on acid activated montmorillonite using two techniques, viz. adsorption and covalent binding, and their activities were tested in a batch and packed-bed reactor and were compared. The packed-bed reactor showed an improved performance for all immobilized enzymes, which was attributed to lowering of diffusional restrictions to mass transfer. Lower activity in case of batch reactor for immobilized invertase was due to a combined effect of loss of native conformation of enzyme on account of immobilization and mass transfer resistances due to improper diffusion of substrate to the active site of enzyme. For immobilized glucoamylase, the packed-bed reactor demonstrated exceptionally high activity that was very close to the free enzyme. Covalently bound glucoamylase showed higher activity than the free enzyme.     

有序大孔二氧化硅孔壁聚合物功能化修饰及葡萄糖淀粉酶固载化

介绍了一种简易的制备方法用于制备功能化有序大孔氧化硅@聚合物材料,并将其用作固载酶的新型载体。     

Affinity Covalent Immobilization of Glucoamylase onto ρ-Benzoquinone-Activated Alginate Beads: II. Enzyme Immobilization and Characterization

A novel affinity covalent immobilization technique of glucoamylase enzyme onto ρ-benzoquinone-activated alginate beads was presented and compared with traditional entrapment one. Factors affecting the immobilization process such as enzyme concentration, alginate concentration, calcium chloride concentration, cross-linking time, and temperature were studied. No shift in the optimum temperature and pH of immobilized enzymes was observed. In addition, K _m values of free and entrapped glucoamylase were found to be almost identical, while the covalently immobilized enzyme shows the lowest affinity for substrate. In accordance, V _m value of covalently immobilized enzyme was found lowest among free and immobilized counter parts. On the other hand, the retained activity of covalently immobilized glucoamylase has been improved and was found higher than that of entrapped one. Finally, the industrial applicability of covalently immobilized glucoamylase has been investigated through monitoring both shelf and operational stability characters. The covalently immobilized enzyme kept its activity over 36 days of shelf storage and after 30 repeated use runs. Drying the catalytic beads greatly reduced its activity in the beginning but recovered its lost part during use. In general, the newly developed affinity covalent immobilization technique of glucoamylase onto ρ-benzoquinone-activated alginate carrier is simple yet effective and could be used for the immobilization of some other enzymes especially amylases.     

Affinity Covalent Immobilization of Glucoamylase onto ρ-Benzoquinone Activated Alginate Beads: I. Beads Preparation and Characterization

ρ-Benzoquinone-activated alginate beads were presented as a new carrier for affinity covalent immobilization of glucoamylase enzyme. Evidences of alginate modification were extracted from FT-IR and thermal gravimetric analysis and supported by morphological changes recognized through SEM examination. Factors affecting the modification process such as ρ-benzoquinone (PBQ) concentration, reaction time, reaction temperature, reaction pH and finally alginate concentration, have been studied. Its influence on the amount of coupled PBQ was consequently correlated to the changes of the catalytic activity and the retained activity of immobilized enzyme, the main parameters judging the success of the immobilization process. The immobilized glucoamylase was found kept almost 80% of its native activity giving proof of non-significant substrate, starch, diffusion limitation. The proposed affinity covalent immobilizing technique would rank among the potential strategies for efficient immobilization of glucoamylase enzyme.     

含环氧基亲水性固定化青霉素酰化酶共聚载体的合成与性能研究

环氧基团可以在温和条件下与酶分子的氨基反应使其固定于载体表面.选用含有活性环氧基团的甲基丙烯酸缩水甘油酯(GMA)和亲水性的N-乙烯吡咯烷酮(NVP)两种单体,以N,N′-亚甲基双丙烯酰胺(MBAA)为交联剂,甲醇水溶液作致孔剂,液体石蜡为主介质,通过反相悬浮聚合技术成功地合成了亲水性大孔GMA-NVP-MBAA三元共聚物载体(GNM).通过调节交联剂的用量和单体NVP与GMA的比例,可以调节载体的孔径、比表面积及在水中的溶胀性能.将巨大芽孢杆菌青霉素酰化酶共价偶联于平均孔径为16.5nm、表面环氧基含量为0.906mmol/g的GNM共聚物载体,制成固定化酰化酶,其表观活性高达625U/g,水解青霉素G钾盐的最适宜温度为50℃,pH值为8.0.固定化酶在4℃保存40d,活性保持不变.经3次使用后,活性达到稳定值(601U/g左右),再经12次使用,活性几乎保持不变.     

Characterization of glucoamylase immobilized on celite

Immobilization of glucoamylase (EC 3.2.1.3) on Celite R649 bio-catalyst carrier for hydrolysis of maltose and maltodextrin has been investigated in both packed bed and recirculated batch reactors. The kinetics parameters on the hydrolysis of maltose were estimated from the packed bed reactor. It is found that this immobilized enzyme is as efficient as the soluble enzyme in catalyzing hydrolysis of maltose. However, it is less efficient than the soluble enzyme in hydrolyzing 30% (w/v) maltodextrin, giving a maximum dextrose equivalent (DE) value of 96.0% instead of 98.2%.