3’-大豆甙元磺酸钠的电化学行为及应用研究

采用线性扫描伏安法、循环伏安法和常规脉冲伏安法电化学手段详细研究了改 性药物3’-大豆甙元磺酸钠(3’-daidzein sulfonic sodium,Dss)在pHl．0—6． 2的水溶液中的电化学行为.在不同pH范围内得到了Das的三个还原波．研究证实， 在pH＜3．2条件下所获得的Pcl，Pc2波分别为质子化的Dss的单电子不可逆吸附还 原波及还原中间体自由基的单电子单质子不可逆吸附还原波；在3．2＜pH＜6.2条 件下所获得的Pc3波，属于Dss后随质子化的单电子不可逆吸附还原波，而还原中间 体自由基的单电子波被氢波掩盖．测得在单分子层饱和吸附的条件下，每一个Dss 分子所占汞电极面积为0.664nm^2.此外，通过邻苯三酚自氧化产生活性氧自由基再 还原，对Dss清除活性氧自由基能力进行了研究，从电化学角度对其药理机制进行 了探讨，研究证实Dss具有较强的抗氧化性，是一种有效的活性氧自由基清除剂．     

4',7-二甲氧基-3'-异黄酮磺酸钠的电化学行为研究

采用线性扫描伏安法和循环伏安法研究了4',7-二甲氧基-3'-异磺酮磺酸钠(Sodium 4',7-dimethoxy-3'-isoflavone sulfonate,SDIS)在pH=1.0～12.0的水溶液中的电化学行为.实验结果表明:在pH=1.0～5.0条件下所获得的Pc₁,Pc₂波分别为SDIS的单质子单电子不可逆还原波及还原中间体自由基的单电子单质子不可逆还原波;在5＜pH＜8条件下所获得的Pc₁波,仍属于SDIS单电子单质子不可逆还原波,而还原中间体自由基的单电子波被氢波掩盖;在pH＞8.0的O.2 mol·L^-1Britton-Robinson缓冲溶液中所获得的Pc₁,Pc₂波分别为质子化的SDIS单电子不可逆还原波及还原中间体自由基的单电子单质子不可逆还原波.     

4′，7-二甲氧基-3′-异黄酮磺酸钠的电化学行为研究

采用线性扫描伏安法和循环伏安法研究了 4′ ,7 二甲氧基 3′ 异磺酮磺酸钠 (Sodium 4′ ,7 dimethoxy 3′ isoflavonesulfonate ,SDIS)在pH =1.0～ 12 .0的水溶液中的电化学行为 .实验结果表明 :在pH =1.0～ 5 .0条件下所获得的Pc1 ,Pc2 波分别为SDIS的单质子单电子不可逆还原波及还原中间体自由基的单电子单质子不可逆还原波 ;在 5 8.0的 0 .2mol·L-1 Britton Robinson缓冲溶液中所获得的Pc1 ,Pc2 波分别为质子化的SDIS单电子不可逆还原波及还原中间体自由基的单电子单质子不可逆还原波     

3′-大豆甙元磺酸钠的电化学行为及应用研究

采用线性扫描伏安法、循环伏安法和常规脉冲伏安法电化学手段详细研究了改性药物 3′ 大豆甙元磺酸钠 ( 3′ daidzeinsulfonicsodium ,Dss)在pH 1 0～ 6 2的水溶液中的电化学行为 .在不同pH范围内得到了Dss的三个还原波 .研究证实 ,在pH <3 2条件下所获得的Pc1,Pc2 波分别为质子化的Dss的单电子不可逆吸附还原波及还原中间体自由基的单电子单质子不可逆吸附还原波 ;在 3 2 相似文献   

克拉霉素的电化学反应机理研究与应用

应用线性扫描伏安法、循环伏安法、常规脉冲伏安法等电化学手段并结合紫外吸收光谱研究了药物克拉霉素(clarithromycin, CAM)在pH 1.8～9.2 Britton-Robinson缓冲溶液和0.05 mol•L^－1 NaOH溶液中的电化学行为. 在所研究的pH范围, CAM分别产生P₁, P₂, P₃, P₄四个还原波, 其中P₁, P₂, P₄三个波均为其药效活性基团C-9位羰基的还原所产生. 实验结果表明: 在pH 1.8～5.7的B-R缓冲溶液条件下所获得的P₁波为两电子不可逆弱吸附还原波; 在6.0＜pH＜9.2的B-R缓冲溶液中, CAM产生P₂和P₃两个波, 其中P₂为两电子不可逆还原波, P₃为催化氢波. 在0.05 mol• L^－1 NaOH溶液中, CAM产生的P₄波是一个单电子的不可逆吸附还原波. 根据P₄波的峰电流i_P与CAM浓度的线性关系, 建立了CAM含量测定的新方法.     

黄连素-染料木素有机盐水合物的制备、晶体结构及溶解性

合成了黄连素和染料木素的有机盐水合物[C₂₀H₁₈NO₄]⁺·[C₁₅H₉O₅]^-·2.5H₂O·0.5(C₂H₅OH),并测定了其晶体结构。 解析结果表明,该有机盐水合物属于单斜晶系,P2₁/c空间群。 染料木素7取代位的羟基失去了质子变成了染料木素阴离子。 羟基阴离子与4'取代位上的羟基形成了O—H••••O^-氢键,产生了一维的氢键链状结构。 两个水分子通过氢键作用形成了链状结构,并与染料木素阴离子形成二维的氢键结构。 加热失去水分子后,有机盐水合物变成无定型状态。 在乙醇水溶液中悬浮后,无定型可以转变成结晶的水合物结构。 形成黄连素-染料木素有机盐水合物后,染料木素在水中的溶解度略有增加。     

依来铬红B的电还原

本文用普通极谱、脉冲极谱、循环伏安法研究了依来铬红B的电还原。随着pH不同,共可产生3个波(pH6.2—12.2)。总波高相当于—受扩散控制的不可逆2电子还原波;第一波和第三波分别为吸附前波和吸附后波。根据实验结果,提出—电还原机理。     

桑色素极谱行为的研究

研究了桑色素在pH=1～14的水溶液中的极谱行为. 于不同pH范翻内得列了四个还原波. 研究证实在pH<4条件下获得的P_1波为表面催化氢波. 其余三个波为不同形态桑色素的单电子吸附还原波, 并伴有随后化学反应过程. 测得在单分子层饱和吸附条件下, 每一个桑色素分子所占汞电极面积为1.36 nm.     

白藜芦醇的电化学行为及其与DNA的相互作用

采用电化学方法研究了白藜芦醇在pH=2~13的缓冲溶液中的电化学行为、抗氧化能力及其与DNA的相互作用. 研究结果表明， 在2.011的溶液中, 白藜芦醇产生的P4和P5波分别是其二价和三价阴离子的还原波. 在最佳实验条件下, 微分脉冲极谱图上IP3在8.0×10-8~2.0×10-6 mol/L范围内与白藜芦醇的浓度呈线性关系, 检出限为4×10-8 mol/L. 将该法用于中药虎杖中白藜芦醇含量的测定, 结果与高效液相色谱法一致.     

大豆素和染料木素的光氧化自由基反应动力学

具有共轭电子结构和多酚羟基官能团的类黄酮是天然抗氧化剂,其活性位点及其自由基稳定性是影响抗氧化效能的重要因素. 我们通过时间分辨光谱并结合量化计算对比研究了大豆素和染料木素两种异黄酮的脱质子形式由光氧化引发的自由基反应动力学. 结果表明,光氧化大豆素的酚氧阴离子先产生不稳定的中间态自由基,随后通过分子内电子转移反应生成相对稳定的自由基;异黄酮染料木素的酚氧阴离子光氧化后直接生成自旋密度在整个分子骨架上离域的稳定自由基;染料木素的5位羟基起到增强4’位酚羟基抗氧化活性的作用. 这些结果解释了染料木素远高于大豆素的抗氧化活性.     

Polarographic reduction of some potential antidiabetic compounds

The polarographic reduction of 4-arylhydrazone-N′-benzysulphonyl-3-methyl-2-pyrazoline-5-ones gave two, two-electron transfer, well defined, well separated, diffusion controlled, irreversible waves in B.R. buffers of pH range 7.0–11.0. In acidic medium the E_1/2 values of the two waves are so close that only one 4-electron transfer, well defined, diffusion controlled, irreversible waves is obtained. The reduction in these compounds takes place at the-NH-N=C-bond. The effect of substituents and its correlation with the Hammett substituent constant (σ) have also been studied.     

Investigation on property and mechanism of redox wave of methylhesperidine at Hg electrode

The voltammetric behaviors of methylhesperidine (MH) were studied by means of linear sweep voltammetry, cyclic voltammetry and normal pulse voltammetry. In the Brit-ton-Robinson buffer solutions with pH values from 2.05 to 6.37, MH could yield three reduction waves PC1,PC2 and PC3. PC1 wave is an adsorptive pre-wave. PC2 wave is an irreversible reduction of pre-protonated MH involving one electron and one proton. PC3 wave is an irreversible wave of reduction species radical of MH involving one electron.     

Electrochemical reduction of camphorquinone in DMF in the presence of a proton donor

The electroreduction of camphorquinone in DMF, at mercury electrodes, was investigated by a variety of techniques. In DMF, in the absence of proton donor, camphorquinone exhibits two one-electron waves: the first, a one-electron reversible wave to be due to a reversible charge transfer without a coupled chemical reaction. After the first charge transfer, the semidione anion radical is reduced to the dianion. The irreversibility of the second wave derives from a fast irreversible protonation of the dianion. A wide variety of changes in behaviour is observed in the reduction of camphorquinone as increasing amounts of benzoic acid are added: a new two-electron irreversible wave appears at a potential less negative than the original wave. A proton donor to substrate ratio of 2 is required to completely suppress the two original waves. A mechanism for the electroreduction of camphorquinone is proposed and discussed on the basis that the prewave current is controlled by the diffusion of the undissociated acid species and that the undissociated acid, rather than the solvated proton, takes part in the protonation, prior to the charge transfer.     

Influence des réactions chimiques préalables sur la forme des courbes de polarisation

Equations have been established for polarographic waves observed while a chemical reaction slowly takes place before the exchange of electrons.The method of calculation is analogous to that already used by one of the authors in the case of polarisation curves relative to the reversible or irreversible systems.The variation of the two half-wave potentials and the limiting densities of current have been deduced. The results have been verified by means of the experimental results of R. brdicka concerning pyruvic and phenylglyoxylic acids.     

Electrochemical Behavior of Thalidomide at a Glassy Carbon Electrode

Thalidomide is an oral drug marketed in the 1950s as a sedative and an anti‐emetic during pregnancy that was removed from the market when its teratogenic side effects appeared in new born children due to inadequate tests to assess the drug's safety. Recent studies evaluating the use of thalidomide in cancer and HIV diseases have sparked renewed interest. The electrochemical behavior of thalidomide on a glassy carbon electrode has been investigated using cyclic, differential and square‐wave voltammetry in aqueous media at different pHs. The oxidation mechanism of thalidomide is an irreversible, adsorption‐controlled process, pH dependent up to values close to the pK_a and occurs in two consecutive charge transfer reactions. A mechanism of oxidation of thalidomide involving one electron and one proton to produce a cation radical, which reacts with water and yields a final hydroxylated product is proposed. The reduction of thalidomide is also a pH dependent, irreversible process and occurs in a single step, with the same number of electrons and protons transferred. The reduction mechanism involves the protonation of the nitrogen that bridges the two cyclic groups, and the product of the protonation reaction causes irreversible dissociation. Both thalidomide and the non electroactive oxidation and reduction products are strongly adsorbed on the glassy carbon electrode surface.     

Electrochemical Behaviour of Isoflavones Genistein and Biochanin A at a Glassy Carbon Electrode

The electrochemical behaviour of genistein and biochanin A was studied at a glassy carbon electrode by cyclic, differential pulse and square wave voltammetry. Genistein undergoes three irreversible, pH dependent oxidation reactions with the transfer of one electron and one proton from each hydroxyl group. The formation of two electroactive products that undergo reversible redox reactions was observed. Biochanin A undergoes two irreversible, pH dependent reactions due to the oxidation of the two hydroxyl groups. The electrochemical behaviour of the chemical analogue daidzein was also investigated. The electroactive centres of genistein and biochanin A were identified and their oxidation mechanisms discussed.     

Spectrometric and Voltammetric Characterization of Obidoxime in Aqueous Solutions

Obidoxime is a pharmacologically active compound used as an acetylcholinesterase reactivator. The scope of this study was to establish correlations between its acid–base and redox equilibria and its mechanism as an acetylcholinesterase reactivator. The obidoxime dicationic structure is modified by the pH of the solvating medium due to tautomeric isomerizations. The possibility of stabilizing its structure as a dicationic, monocationic, and a neutral species was studied by ultraviolet–visible spectrometry and cyclic and differential pulse voltammetry. Spectrometric and voltammetric studies were performed across a large pH interval (2.00–9.80) of the solvating medium. Absorption measurements revealed the existence of three species involved in two tautomeric equilibria implying oxime and nitroso groups. The structure bearing nitroso groups, stabilized at higher pH, is more likely to behave as a nucleophilic agent than the structure with oxime groups, explaining thus its acetylcholinesterase reactivation. The obidoxime voltammetric behavior at a glassy carbon electrode is complex. Both its oxidation and reduction are diffusion-controlled processes. Anodic signals were obtained only at pH values above 6.50 and the oxidation occurs at the anion oxime group involving two electrons and one proton. The obidoxime reduction is pH dependent only for neutral or alkaline media, giving rise to two or even four signals (for pH higher than 7.50) depending on pH. The peak at less positive potentials was always well defined.     

The mechanism of the electrochemical oxidation of thiourea

Cyclic voltammetry and potentiostatic coulometry were used to study the electrochemical oxidation of thiourea in aqueous solutions of nitric acid, nitric acid—ammonium nitrate, and ammonium nitrate—ammonium hydroxide and in acetonitrile. These studies were carried out at glassy carbon and/or platinum working electrodes. In acetonitrile, the cyclic voltammograms show one oxidation peak at + 0.6 V and a reduction peak at —0.1 V. In aqueous solutions up to about pH 6, there is a second oxidation peak at 1.3 V which is irreversible and its height is sensitive to acidity. These experiments have confirmed that in acidic and neutral solutions the oxidation of thiourea proceeds via a slow 1-e transfer reaction producing a radical [(NH₂)₂—C—S]⁺. Further direct oxidation of this radical takes place only at higher potentials (ca. 1.2 V) and involves hydration and protontransfer equilibria. Otherwise, C,C'-dithiodiformamidinium ion is formed by a fast dimerization reaction. Coulometric and chronopotentiometric measurements have shown that in strong acid the second oxidation step involves one electron, while at lower acidities the further oxidation involving three (and possibly five) electrons proceeds in two (or three) steps of very similar potential.     

Polarographische Untersuchungen an Solochromviolett RS in Pufferlösungen in Abwesenheit und in Gegenwart oberflächenaktiver Stoffe (SAS)

The polarographic behaviour of solochrome violet RS is investigated in buffer solutions of varying pH in the absence and presence of surfactants (triton 100-X and dodecylbenzene-sulphonate). The reduction proceeds irreversibly along a single wave in acid solutions and two waves in alkaline ones. The electrode reaction corresponds to four electrons in media of pH<2.5 and pH>8.0; in media of pH 4 5.5 two electrons are consumed. In solution of pH 2.5 4 or 5.5–8.0, both reactions contribute in varying magnitudes. The addition ofSAS causes the inhibition of reduction beyond the 2-electrons stage in acid solutions; the polarograms comprise one wave in case ofDBS and two waves of equal height in presence of triton. In alkaline media the polarogram comprises three waves due to the splitting of the main reduction wave. The kinetic parameters of the electrode reaction are also determined.