Enterobacter Cloacae Z0206细菌胞外富硒多糖的抗氧化活性

利用产多糖菌Enterobacter cloacae Z0206(E.cloacaeZ0206)的深层发酵法制备了E.cloacae Z0206细菌富硒多糖;测定了其还原能力和清除1,1-diphenyl-2-picrylhydrazyl(DPPH)自由基、超氧阴离子及羟自由基的能力.结果表明,通过深层富硒发酵、醇沉离心等制备富硒多糖SEPS的产量为9.28g/L,富硒量为2.314mg/g;E.cloacae Z0206富硒多糖对DPPH自由基和羟自由基具有较好的清除作用,在浓度为5g/L时对DPPH自由基和羟自由基的清除率分别为80.35%和84.26%,并具有较强的还原能力,但其对超氧阴离子自由基的清除能力较差.     

硒化合物与脂质过氧自由基作用的研究

本文以卵磷脂、亚油酸和脂质体作为生物膜模型, 鼠红细胞膜作为生物膜实例, 通过ESR研究, 观察到包括RSe和RSeSeR在内的硒化合物在模拟的和真实的生物膜体系中对脂质过氧自由基的清除作用, 使得硒作为自由基清除剂的假说在体外模型体系实验中被初步证实, 提示占体内总硒量约2/3的非GSH-Px硒可能是通过直接清除过氧自由基而发挥其生理功能, 研究表明, 其清除作用是针对生物膜磷脂分子上的不饱和脂肪酸过氧自由基, 其作用部位处于膜磷脂双分子层中部疏水区(脂相)中, 在体外实验的清除效果上, 有机硒优于无机硒, 某些有机硒化合物表面出“奇偶规律"。CNDO/2计算表明, 硒化合物清除脂质过氧自由基可能是通过硒中心自由基而起作用的。     

毛细管电泳法测定过氧化氢酶与天然抗氧化剂协同清除羟自由基作用

在抗坏血酸/Fe2+羟自由基产生体系中,以苯甲酸为羟自由基捕获剂,建立了羟自由基的毛细管电泳分析方法。优化了背景缓冲液的pH值、电解质浓度、表面活性剂浓度及分离电压。在最优的电泳条件下,研究了羟自由基产生体系中各底物浓度和反应时间对产物生成量的影响。本方法可在15 min内实现体系中的各物质的分离;产物间羟基苯甲酸的线性范围是5×10!6~1×10!3mol/L,检出限为2.8×10!7mol/L。将本方法用于血清基质中过氧化氢酶、原花青素和绿原酸对羟自由基IC50的测定,并研究了过氧化氢酶与原花青素及与绿原酸的协同清除羟自由基作用。结果表明,过氧化氢酶与原花青素及与绿原酸均存在协同清除羟自由基作用,在过氧化氢酶与原花青素的协同作用间还存在量效关系。     

富硒蛹虫草的抗氧化活性研究

采用现代分离技术从富硒蛹虫草中提取硒多糖,然后以苯酚-硫酸法、电感耦合等离子体质谱（ICP—MS）法对硒多糖中多糖含量和硒含量进行测定;在Fenton体系的最佳实验条件下,研究了硒多糖对羟自由基的清除作用及硒多糖对支撑磷脂双层膜（Supported Bilayer Lipid Membranes,s—BLM）的保护作用。结果表明：硒多糖清除羟自由基的效果比与之相同浓度的无机硒、多糖都要明显。其中硒多糖对羟自由基的最高清除率可达38．02％,硒多糖具有很强的抗脂质过氧化、保护支撑磷脂双层膜的作用。     

流动注射邻菲啰啉化学发光体系测定羟自由基

利用Vitc-CuSO4-H2O2产生的羟自由基,建立流动注射邻菲口罗啉化学发光体系测定羟自由基的产生及物质对羟自由基的清除能力。体系中各种物质浓度的最佳组合是:邻菲口罗啉1.0×10-3mol/L(pH 8.2硼砂-硼酸缓冲液配制、内含CTMAB浓度为5.0×10-3mol/L)、Cu2+1.5×10-3mol/L、H2O2体积分数0.6%、抗坏血酸1.5×10-3mol/L。硫脲清除羟自由基的量效关系Y=25.0009ln(x)+65.3120,r=0.9988,IC50=0.542 mmol/L。龙井茶水提液对羟自由基具有较强的清除作用。     

基于果糖自氧化体系的抗氧化剂筛选方法

机体内果糖的自氧化过程中会产生多种自由基, 并最终转化为羟自由基, 苯甲酸钠可捕获羟自由基生成具有强荧光信号的羟基苯甲酸钠. 本文采用荧光光度法考察了影响果糖自氧化体系的各种因素, 建立了果糖自氧化产生羟自由基体系. 实验结果表明, 在果糖浓度为8.00 mmol/L, CuSO₄浓度为20.0 μmol/L, 苯甲酸钠浓度为24.0 mmol/L, pH=7.4, 温度为37℃及反应时间为24 h的条件下, 果糖自氧化体系最终可产生19.27 μmol/L的羟自由基. 抗氧化剂的存在可清除果糖自氧化过程中产生的自由基, 使最终生成的羟自由基的量减少, 从而导致生成的羟基苯甲酸钠减少, 荧光信号减弱, 由此建立了基于果糖自氧化体系的抗氧化剂筛选方法. 利用本评价体系考察了抗氧化剂盐酸小檗碱和阿魏酸的抗氧化能力, 实验结果表明, 中药标准品盐酸小檗碱和阿魏酸均能有效清除果糖自氧化体系产生的羟自由基, 其IC₅₀值分别为0.023和0.036 mmol/L.     

十二烷基磺基甜菜碱与铂电极支撑的磷脂双层膜作用的电化学研究

以铂电极支撑的磷脂双层膜(Supported Bilayer Lipid Membrane,s-BLM)作为生物膜的模型,以Fe(CN)36-和Fe(CN)64-为探针分子,利用循环伏安法(CV)和交流阻抗谱(EIS)研究两性表面活性剂十二烷基磺基甜菜碱(Dodecyl Sulfobetaine,DSB)对s-BLM相互作用。结果显示,DSB可以嵌入到s-BLM的疏水区,容易使其表面分子的排列发生变化,产生缺陷或孔洞,探针分子Fe(CN)63-和Fe(CN)64-可以通过这些微孔接近电极,产生氧化还原响应。并且作用时间、DSB的浓度以及胆固醇的存在与否对二者的相互作用有直接影响。此外作用后的双层膜在0.1mol/LKCl溶液中能够自我修复,这表明DSB与s-BLM的相互作用是可逆的。     

植物多糖清除羟自由基作用的研究

研究当归、黄芪、鬼臼和猫人参的多糖对羟自由基的清除作用.采用分光光度法测定羟自由基清除率,并计算出半数清除率(IC50).当归多糖、黄芪多糖、鬼臼多糖对羟自由基的IC50分别为1.38 mg/mL、0.485 mg/mL、0.1 mg/mL,猫人参的最大清除率仅为36.84%.其清除能力鬼臼多糖＞黄芪多糖＞当归多糖＞猫人参多糖.鬼臼多糖、黄芪多糖均具有较强的清除自由基作用,且清除能力与浓度呈明显的正相关.     

山药多糖的制备及其体外抗氧化活性

提取山药粗多糖并进行精制,分析了山药多糖的单糖组成,并研究了山药多糖的体外抗氧化活性.结果表明,山药精制多糖纯度较高,由鼠李糖、阿拉伯糖、甘露糖、葡萄糖和半乳糖组成.体外抗氧化活性测试结果表明,山药多糖具有一定的还原能力,对羟自由基具有较强的清除能力,并对小鼠肝匀浆自氧化有明显的抑制作用.因此,山药多糖具有较好的抗氧化活性,可作为潜在的抗氧化剂或抗衰老药物进行深入研究和开发.     

两种含氮类大豆苷元衍生物对人体红细胞的抗溶血作用（英文）

合成了2种含氮类大豆苷元衍生物,4,7-二((甘氨酸钠)羰基)甲氧基异黄酮(L1)和4′,7-二(肼羰基)甲氧基异黄酮(L2)并用元素分析、红外光谱和核磁共振氢谱对其进行了表征。研究了大豆苷元衍生物的抗氧化性能,评价了其对自由基、超氧阴离子自由基的吸附能力,以及对人体血红细胞抗氧化损伤的保护作用。实验结果表明,大豆苷元衍生物在生理pH条件下的抗氧化活性优于维生素C,特别是在清除羟自由基和抑制人血红细胞溶血方面,大豆苷元衍生物抗氧化能力表现更为突出。大豆苷元衍生物的羟自由基清除活性IC50值是维生素C的104倍。     

Synthesis and structure of hydroxyisoxazolidines and derivatives of hydroxylamine and alkenals

The reactions of N-substituted hydroxylamines with alkenals serve as a method for the synthesis of the corresponding 2-substituted 3(5)-hydroxyisoxazolidines. The reaction pathway is determined by the nature of the substituent attached to the nitrogen atom. Ring-chain isomerism has been detected in these newly obtained compoundsTranslated from Khimiya Geterotsiklicheskikh Soedinenii, No. 9, pp. 1270–1276, September, 1987.     

Synthesis and characterization of triazenide and triazene complexes of ruthenium and osmium

Triazenide [M(eta2-1,3-ArNNNAr)P4]BPh4 [M = Ru, Os; Ar = Ph, p-tolyl; P = P(OMe)3, P(OEt)3, PPh(OEt)2] complexes were prepared by allowing triflate [M(kappa2-OTf)P4]OTf species to react first with 1,3-ArN=NN(H)Ar triazene and then with an excess of triethylamine. Alternatively, ruthenium triazenide [Ru(eta2-1,3-ArNNNAr)P4]BPh4 derivatives were obtained by reacting hydride [RuH(eta2-H2)P4]+ and RuH(kappa1-OTf)P4 compounds with 1,3-diaryltriazene. The complexes were characterized by spectroscopy and X-ray crystallography of the [Ru(eta2-1,3-PhNNNPh){P(OEt)3}4]BPh4 derivative. Hydride triazene [OsH(eta1-1,3-ArN=NN(H)Ar)P4]BPh4 [P = P(OEt)3, PPh(OEt)2; Ar = Ph, p-tolyl] and [RuH{eta1-1,3-p-tolyl-N=NN(H)-p-tolyl}{PPh(OEt)2}4]BPh4 derivatives were prepared by allowing kappa1-triflate MH(kappa1-OTf)P4 to react with 1,3-diaryltriazene. The [Os(kappa1-OTf){eta1-1,3-PhN=NN(H)Ph}{P(OEt)3}4]BPh4 intermediate was also obtained. Variable-temperature NMR studies were carried out using 15N-labeled triazene complexes prepared from the 1,3-Ph15N=N15N(H)Ph ligand. Osmium dihydrogen [OsH(eta2-H2)P4]BPh4 complexes [P = P(OEt)3, PPh(OEt)2] react with 1,3-ArN=NN(H)Ar triazene to give the hydride-diazene [OsH(ArN=NH)P4]BPh4 derivatives. The X-ray crystal structure determination of the [OsH(PhN=NH){PPh(OEt)2}4]BPh4 complex is reported. A reaction path to explain the formation of the diazene complexes is also reported.     

Mass and NMR spectra of haplophyllidine and perforine and of their derivatives

Conclusions The mass and NMR spectra of haplophyllidine, perforine, and their derivatives have been studied. The influence of the open and cyclic forms of the molecular ion on the nature of the fragmentation has been discussed. The main routes of fragmentation of the compounds considered are due to the presence of substituents at C₈ and C₄.Khimiya Prirodnykh Soedinenii, Vol. 5, No. 4, pp. 273–279, 1969     

Investigation of adhesion and mobility of polyurethane and epoxy-rubber glues and adhesives

The values of activation parameters in uncured and cured epoxy resins, rubbers, and blends thereof are investigated. The dependences of activation energy and adhesion strength of epoxy-rubber compositions on rubber content are determined. The correlation of adhesion and activation energy values for polyurethane rubber and epoxy-rubber compositions is shown.     

Crystal and molecular structure of aroyl- and acetylhydrazones of acet- and benzaldehydes

Aroyl- and acetylhydrazones of acet- (I) and benzaldehydes (IV) and benzoylhydrazones of acet- (II) and benzaldehydes (III) were studied by x-ray structural and quantum-chemical methods in order to establish their structures. Compund (I) was the EEZ structure in the crystal. Calculations and spectral data showed that the EEE form occurs in nonpolar solvents and in the gas phase. According to crystallographic data molecules (I)–(IV) are the E-isomers (relative to the N-N bond) and the hydrazone fragments are planar. Intermolecular N-H...O H-bonds from in the crystals. The data obtained suggest that the majority of acylhydrazones are conformationally rigid on dissolution although exceptions do occur. Apparently the reasons for the difference of acetyl- and benzoylhydrazones in electrocarboxylation reactions are electronic and not steric factors.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 1, pp. 75–81, January, 1991.     

Preparation and characterization of diarylphosphazene and diarylphosphinohydrazide complexes of titanium, tungsten and ruthenium and phosphorylketimido complexes of rhenium

Reaction of the proligand Ph2PN(SiMe3)2 (L1) with WCl6 gives the oligomeric phosphazene complex [WCl4(NPPh2)]n, 1 and subsequent reaction with PMe2Ph or NBu4Cl gives [WCl4(NPPh2)(PMe2Ph)] (2) or [WCl5(NPPh2)][NBu4] (3), respectively. DF calculations on [WCl5(NPPh2)][NBu4] show a W=N double bond (1.756 A) and a P-N bond distance of 1.701 A, which combined with the geometry about the P atom suggests, there is no P-N multiple bonding. Reaction of L1 with [ReOX3(PPh3)2] in MeCN (X = Cl or Br) gives [ReX2(NC(CH3)P(O)Ph2)(MeCN)(PPh3)](X = Cl, 4, X = Br, 5) which contains the new phosphorylketimido ligand. It is bound to the rhenium centre with a virtually linear Re-N-C arrangement (Re-N-C angle = 176.6 degrees, when X = Cl) and there is multiple bonding between Re and N (Re-N = 1.809(7) A when X = Cl). The proligand Ph2PNHNMe2(L2H) reacts with [(C5H5)TiCl3] to give [(C5H5)TiCl2(Me2NNPPh2)] (6). An X-ray crystal structure of the complex shows the ligand (L2) is bound by both nitrogen atoms. Reaction of the proligands Ph2PNHNR2[R2 = Me2 (L2H), -(CH2CH2)2NCH3 (L3H), (CH2CH2)2CH2 (L4H)] with [{RuCl(mu-Cl)(eta6-p-MeC6H4iPr)}2] gave [RuCl2(eta6-p-MeC6H4iPr)L] {L = L2H (7), L3H (8), L4H (9)}. The X-ray crystal structures of 7-9 confirmed that the phosphinohydrazine ligand is neutral and bound via the phosphorus only. Reaction of complexes 7-9 with AgBF4 resulted in chloride ion abstraction and the formation of the cationic species [RuCl(6-p-MeC6H4iPr)(L)]+ BF4- {(L = L2H (10), L3H (11), L4H (12)}. Finally, reaction of complex 6 with [{RuCl(mu-Cl)(eta6-p-MeC6H4iPr)}2] gave the binuclear species [(eta6-p-MeC6H4iPr)Cl2Ru(mu2,eta3-Ph2PNNMe2)TiCl2(C5H5)], 13.     

Ti-V基储氢合金及其氢化物的物相结构与组分优化设计

Ti-V基储氢合金在室温、常压下即可表现出良好的储氢特性,且质量储氢容量明显高于传统AB₅型储氢合金,从而在氢气的精制和回收、运输和储存及热泵等方面有较早的应用。 此外,在混合气体分离、核反应堆中处理氢的同位素、镍氢电池及燃料电池负极材料等方面也得到了广泛的研究与关注。 基于目前Ti-V基储氢合金的研究现状,概述了该类合金的优势、限制性因素(包括成因)及改性手段。 此外,为了进一步理解Ti-V基合金储氢机理、构建合金组分与储氢特性之间的对应关系,本工作重点围绕Ti-V基储氢合金及其氢化物的结构、组分优化设计展开综述,并对其未来研究方向做出展望。     

Kinetics and mechanisms of chlorine dioxide and chlorite oxidations of cysteine and glutathione

Chlorine dioxide oxidation of cysteine (CSH) is investigated under pseudo-first-order conditions (with excess CSH) in buffered aqueous solutions, p[H+] 2.7-9.5 at 25.0 degrees C. The rates of chlorine dioxide decay are first order in both ClO2 and CSH concentrations and increase rapidly as the pH increases. The proposed mechanism is an electron transfer from CS- to ClO2 (1.03 x 10(8) M(-1) s(-1)) with a subsequent rapid reaction of the CS* radical and a second ClO2 to form a cysteinyl-ClO2 adduct (CSOClO). This highly reactive adduct decays via two pathways. In acidic solutions, it hydrolyzes to give CSO(2)H (sulfinic acid) and HOCl, which in turn rapidly react to form CSO3H (cysteic acid) and Cl-. As the pH increases, the (CSOClO) adduct reacts with CS- by a second pathway to form cystine (CSSC) and chlorite ion (ClO2-). The reaction stoichiometry changes from 6 ClO2:5 CSH at low pH to 2 ClO2:10 CSH at high pH. The ClO2 oxidation of glutathione anion (GS-) is also rapid with a second-order rate constant of 1.40 x 10(8) M(-1) s(-1). The reaction of ClO2 with CSSC is 7 orders of magnitude slower than the corresponding reaction with cysteinyl anion (CS-) at pH 6.7. Chlorite ion reacts with CSH; however, at p[H+] 6.7, the observed rate of this reaction is slower than the ClO2/CSH reaction by 6 orders of magnitude. Chlorite ion oxidizes CSH while being reduced to HOCl, which in turn reacts rapidly with CSH to form Cl-. The reaction products are CSSC and CSO3H with a pH-dependent distribution similar to the ClO2/CSH system.