谈氧化——还原方程式配平类型及其解法

本文主要探究了在高中化学教学中,解决氧化—还原反应方程式配平的几种方法,提出在配平氧化——还原反应方程式中只抓住化合价的降升,任何一个反应都可以配平,从而达到突破难点掌握重点这一最终目的。     

自由基与衰老

体内的一些生理或病理过程往往与自由基反应有关。弱键均裂、单电子氧化还原反应、高能辐射及光分解都可产生自由基。自由基反应常以连锁反应的方式进行。自由基可使核酸的主链断裂、碱基降解和氢键破坏;使蛋白质交联或多肽链断裂;使透明质酸解聚;使脂类发生过氧化作用,分解生成丙二醛等物质而使生物大分子之间发生交联,聚合成异常的大分子,在溶酶体中堆积,形成脂褐素(老年色素)。抗氧化剂对机体有一定的保护作用。     

自由基与衰老

体内的一些生理或病理过程往往与自由基反应有关。弱键均裂、单电子氧化还原反应、高能辐射及光分解都可产生自由基。自由基反应常以连锁反应的方式进行。自由基可使核酸的主链断裂、碱基降解和氢键破坏;使蛋白质交联或多肽链断裂;使透明质酸解聚;使脂类发生过氧化作用,分解生成丙二醛等物质而使生物大分子之间发生交联,聚合成异常的大分子,在溶酶体中堆积,形成脂褐素 (老年色素)。抗氧化剂对机体有一定的保护作用。     

11-羟基甘草萜醇类化合物的制备及体外抗氧化活性研究

为提高甘草次酸(Ib)的抗氧化活性,对其化学结构进行修饰,制备11-羟基甘草萜醇类衍生物.各化合物的抗氧化活性由肝微粒体中的细胞色素P450/NADPH氧化系统做体外抗氧化实验模型进行测定.微粒体中的自由基由探针物DCFH-DA的氧化程度进行检测.维生素E作为阳性对照物.通过还原反应获得甘草萜醇类两种光学异构体--11α-羟基物(2)和11β-羟基物(3).这两种化合物显示出较强的抗氧化活性,以1.0 mg/mL浓度,分别抑制自由基浓度为50%和51%.相同条件下,先导物Ib和维生素E分别抑制31%和32%的自由基活性.以上结果显示,对先导物Ib的C11位羰基和C30位羧基进行还原修饰,可显著提高其抗氧化活性,这种修饰将能增强先导物对自由基损伤有关病理性病变(如AS)的防治潜能.     

不同种竹笋及笋壳提取物抗氧化活性的研究

采用醇提法,分别对毛竹、麻竹、雷竹的竹笋及笋壳进行醇提,并对醇提物进行抗氧化活性测定.对DPPH·、OH·、O2-·自由基的清除作用分别通过分光光度法、邻二氮菲法、邻苯三酚自氧化法进行测定,相对还原能力、总抗氧化能力的测定则采用普兰士蓝反应法和FRAP法.结果表明:不同种的竹笋及笋壳的醇提物含量与自由基清除能力、相对还...     

吡咯喹啉醌及其生理功能

吡咯喹啉醌（ＰＱＱ）──一种新的氧化还原酶辅基,存在于一些微生物、植物和动物组织中,参与催化生物体内氧化还原反应。研究表明ＰＱＱ具有一些重要生理功能：刺激某些植物发育及微生物和人体细胞生长;作为动物体生长发育的必需因子;清除自由基保护机体免受自由基损害;防治肝损伤;促进神经生长因子合成等。因此,ＰＱＱ具有一定的医药应用前景。     

生物催化立体选择性氧化还原中存在问题及其发展策略

以立体选择性氧化还原酶或其全细胞催化的不对称氧化还原反应已经成为转化光学活性手性醇及其他手性化合物的有效手段。然而,生物催化氧化还原反应体系存在着催化活性与专一性、反应体系与催化稳定性等生物催化剂所固有的局限性问题,而且,生物氧化还原反应必需辅酶及其再生问题也是限制该转化途径产业化应用的一个重要因素。围绕上述生物催化立体选择性氧化还原中存在的关键问题,现代分子生物技术及反应工程的不断突破和发展为改善生物催化立体选择性氧化还原在催化剂本身和反应工程方面的局限性提供了有效的发展策略,为其进一步大规模产业应用提供了发展基础。     

Photo-Fenton氧化法处理废水的原理及影响因素

Photo-Fenton高级氧化技术是处理难降解有毒有机废水的一种有效的方法。本文阐述了该氧化法的原理及其影响因素,photo-Fenton氧化法在反应中会产生大量羟自由基(·OH),它是一种非常活泼及非选择性物种,其氧化电位为2.8V,氧化能力很强,能够引发水溶液中大部分有机物的氧化还原反应。其优点是操作简便及无二次污染等,反应产物Fe³⁺可与OH反应形成Fe(OH)₃沉淀而对环境无害。缺点是反应必须在pH≤3条件下进行,且H₂O₂消耗量大而导致价格昂贵,处理成本较高等。     

蝶呤型钼辅因子生物合成、运输及组装——潜在的药物靶标

钼辅因子作为氧化还原反应中的重要分子,参与硫、氮、碳的氧化还原代谢.钼辅因子主要分为两类:以铁硫簇为基础的铁钼辅因子和以亚钼蝶呤为基础的钼辅因子.钼-二-亚钼蝶呤-鸟苷二核苷钼辅因子(Mo-bis-MGD)是蝶呤型钼辅因子的重要成员之一,是硝酸盐还原酶的重要辅因子.膜结合硝酸盐还原酶介导的硝酸盐还原为细菌提供了氮源和能...     

南瓜醇提物的体外抗氧化活性(英文)

采用化学体系模拟法体外测定南瓜醇提物((pumpkin ethanol extract,PEE)对1,1-二苯基-2-苦苯肼自由基(DPPH·)、超氧阴离子自由基(O2)和羟自由基(·OH)的清除能力,总还原力,对β-胡萝卜素/亚油酸自氧化体系的总抗氧化能力以及脂质过氧化的抑制能力.结果显示PEE对DPPH·、02-和·OH均有较强的清除能力,IC50值分别为18.8 mg/mL、29.0 ms/mL和44.9μg/mL,有显著的还原力和总抗氧化力,对脂质过氧化有一定的抑制作用.PEE的体外抗氧化活性均有良好的量效关系.上述结果为南瓜作为抗氧化的保健食品或功能食品开发利用提供了依据.     

A doubly amplified electrochemical immunoassay for carcinoembryonic antigen

An ultrasensitive electrochemical immunoassay (EIA) for the detection of carcinoembryonic antigen (CEA) is described in this report. The assay involves utilizing enzyme-catalyzed deposition of a redox polymer and electrocatalytic oxidation of ascorbic acid (AA) by the deposited redox polymer, a dual-amplification scheme to enhance analytical signals. Briefly, CEA capturing antibody and redox polymer anchoring agent were covalently immobilized on a gold electrode. After incubating with CEA, the electrode was treated in detection antibody-glucose oxidase conjugate solution. Thereafter, it was dipped into the redox polymer solution. Upon the addition of glucose, the redox polymer was enzymatically reduced and deposited on the electrode surface. The deposited redox polymer exhibits excellent electrocatalytic activity towards the oxidation of AA. Consequently, CEA could be quantified amperometrically. This electrochemical immunoassay combines the specificity of the immunological reaction with the sensitivity of the doubly amplified electrochemical detection.     

Electron-conducting redox hydrogels: Design, characteristics and synthesis

Redox hydrogels constitute the only electron-conducting phase in which water-soluble chemicals and biochemicals dissolve and diffuse. The combination of solubility and diffusion makes the electron-conducting gels permeable to water-soluble biochemicals and chemicals. The electron-conducting redox hydrogels serve to electrically connect the redox centers of enzymes to electrodes, enabling their use whenever leaching of electron-shuttling diffusional redox mediators must be avoided, which is the case in subcutaneously implanted biosensors for diabetes management and in miniature, potentially implantable, glucose-O2 biofuel cells. Because the hydrogels envelope the redox enzymes, they electrically wire the reaction centers to electrodes irrespective of spatial orientation and connect to electrode redox centers of multiple enzyme layers. Hence, the attained current densities of enzyme substrate electrooxidation or electroreduction are much higher than with enzyme monolayers packed onto electrode surfaces.     

The design and synthesis of artificial photosynthetic antennas,reaction centres and membranes

Artificial antenna systems and reaction centres synthesized in our laboratory are used to illustrate that structural and thermodynamic factors controlling energy and electron transfer in these constructs can be modified to optimize performance. Artificial reaction centres have been incorporated into liposomal membranes where they convert light energy to vectorial redox potential. This redox potential drives a Mitchellian, quinone-based, proton-transporting redox loop that generates a Deltamu H(+) of ca. 4.4 kcal mol(-1) comprising DeltapH ca. 2.1 and Deltapsi ca. 70 mV. In liposomes containing CF(0)F(1)-ATP synthase, this system drives ATP synthesis against an ATP chemical potential similar to that observed in natural systems.     

Heme activates artemisinin more efficiently than hemin, inorganic iron, or hemoglobin

Artemisinin derivatives appear to mediate their anti-malarial through an initial redox-mediated reaction. Heme, inorganic iron, and hemoglobin have all been implicated as the key molecules that activate artemisinins. The reactions of artemisinin with different redox forms of heme, ferrous iron, and deoxygenated and oxygenated hemoglobin were analyzed under similar in vitro conditions. Heme reacted with artemisinin much more efficiently than the other iron-containing molecules, supporting the role of redox active heme as the primary activator of artemisinin.     

Corynebacterium diphtheriae Methionine Sulfoxide Reductase A Exploits a Unique Mycothiol Redox Relay Mechanism

Methionine sulfoxide reductases are conserved enzymes that reduce oxidized methionines in proteins and play a pivotal role in cellular redox signaling. We have unraveled the redox relay mechanisms of methionine sulfoxide reductase A of the pathogen Corynebacterium diphtheriae (Cd-MsrA) and shown that this enzyme is coupled to two independent redox relay pathways. Steady-state kinetics combined with mass spectrometry of Cd-MsrA mutants give a view of the essential cysteine residues for catalysis. Cd-MsrA combines a nucleophilic cysteine sulfenylation reaction with an intramolecular disulfide bond cascade linked to the thioredoxin pathway. Within this cascade, the oxidative equivalents are transferred to the surface of the protein while releasing the reduced substrate. Alternatively, MsrA catalyzes methionine sulfoxide reduction linked to the mycothiol/mycoredoxin-1 pathway. After the nucleophilic cysteine sulfenylation reaction, MsrA forms a mixed disulfide with mycothiol, which is transferred via a thiol disulfide relay mechanism to a second cysteine for reduction by mycoredoxin-1. With x-ray crystallography, we visualize two essential intermediates of the thioredoxin relay mechanism and a cacodylate molecule mimicking the substrate interactions in the active site. The interplay of both redox pathways in redox signaling regulation forms the basis for further research into the oxidative stress response of this pathogen.     

Quinone-Mediated Microbial Goethite Reduction and Transformation of Redox Mediator,Anthraquinone-2,6-Disulfonate (AQDS)

The aim of current study is to identify the kinetic characteristics and elucidate the possible transformation pathways of the interaction between the redox mediator (anthraquinone-2,6-disulfonate, AQDS) and goethite during the process of microbial goethite reduction by Shewanella putrefaciens, a dissimilatory iron reduction bacterium (DIRB). Speciations of both AQDS and microbially reduced ferrous iron are used to characterize the interaction process among S. putrefaciens, AQDS and goethite. Due to the complexities of the natural environment, two pre-incubation reaction systems of the “DIRB–goethite” and the “DIRB–AQDS” are introduced to investigate the dynamics of goethite reduction and redox transformation of AQDS. Results show that the characteristics of the microbial goethite reduction and the kinetic transformation between two species of the redox mediator are different in two pre-incubation reaction systems. Both abiotic and enzymatic reactions and their coupling regulate the kinetic process for “redox mediatoriron” interaction in the presence of DIRB. This study will help to understand the characteristics and mechanism of microbial reduction of the Fe(III) oxide and transformation of redox mediator.     

Reductive activation of mitomycins A and C by vitamin C

The anticancer drug mitomycin C produces cytotoxic effects after being converted to a highly reactive bis-electrophile by a reductive activation, a reaction that a number of 1-electron or 2-electron oxidoreductase enzymes can perform in cells. Several reports in the literature indicate that ascorbic acid can modulate the cytotoxic effects of mitomycin C, either potentiating or inhibiting its effects. As ascorbic acid is a reducing agent that is known to be able to reduce quinones, it could be possible that the observed modulatory effects are a consequence of a direct redox reduction between mitomycin C and ascorbate. To determine if this is the case, the reaction between mitomycin C and ascorbate was studied using UV/Vis spectroscopy and LC/MS. We also studied the reaction of ascorbate with mitomycin A, a highly toxic member of the mitomycin family with a higher redox potential than mitomycin C. We found that ascorbate is capable to reduce mitomycin A efficiently, but it reduces mitomycin C rather inefficiently. The mechanisms of activation have been elucidated based on the kinetics of the reduction and on the analysis of the mitosene derivatives formed after the reaction. We found that the activation occurs by the interplay of three different mechanisms that contribute differently, depending on the pH of the reaction. As the reduction of mitomycin C by ascorbate is rather inefficiently at physiologically relevant pH values we conclude that the modulatory effect of ascorbate on the cytotoxicity of mitomycin C is not the result of a direct redox reaction and therefore this modulation must be the consequence of other biochemical mechanisms.     

A hybrid-type approach with MD and DFT calculations for evaluation of redox potential of molecules

A simple calculation method to evaluate the redox potential of molecules by using a hybrid-type calculation with molecular dynamics (MD) and density functional theory calculations is presented with discussions of the difference of the redox potential. In our hybrid method, the standard Gibbs free energy of the molecules, acetone and 3-pentanone, in the redox reaction, is estimated from the average of ionisation free energy and the excess chemical potentials of the reduced and oxidised molecules according to the Born–Haber cycle by sampled configurations from the MD simulation. The difference of the redox potentials between the two molecules is in agreement with the experimental data within the standard deviation.     

A transition state analogue for two pyruvate metabolizing enzymes, lactate dehydrogenase and alanine dehydrogenase.

The synthesis of 5-(2-oxalylethyl)-NADH, a reduced nicotinamide adenine dinucleotide (NADH) derivate with pyruvate covalently attached to the 5 position of the dihydronicotinamide ring over an additional methylene group has been described previously (Trommer, W.E., Blume, H., and Kapmeyer, H. (1976) Justus Liebigs Ann. Chem., 848). In the presence of lactate dehydrogenase, the dihydropyridine ring of this coenzyme-substrate analogue is oxidized and the carbonyl function of the side chain is reduced to the corresponding L-hydroxy derivative with a maximum velocity of 1/3000 of the natural reaction. This reaction is intramolecular as shown by competition experiments with pyruvate. 5-(2-oxalylethyl)-NADH (pyr-NADH) appears to be a true transition state analogue, proving its postulated structure. Pyr-NADH is high specific for this enzyme as demonstrated by the facts that (1) D-lactate dehydrogenase does not catalyze the intramolecular redox reaction, although the substrate moiety of pyr-NADH is reduced in the presence of NADH; (2) when tested with malate dehydrogenase, alcohol dehydrogenase, glyceraldehyde phosphate dehydrogenase,glycerate dehydrogenase, and glycerol dehydrogenase pyr-NADH is not even oxidized in the presence of the corresponding substrates. However, a great similarity between the transition states of the reduction of pyruvate catalyzed by lactate dehydrogenase and alanine dehydrogenase could be shown. Alanine dehydrogenase catalyzes the intramolecular redox reaction as well. In the presence of ammonium ions, pyr-NADH is transformed to 5-(3-carboxyl-3-aminopropyl)-NAD+.     

Heterologous expression and mechanistic investigation of a fungal cytochrome P450 (CYP5150A2): involvement of alternative redox partners

A fungal cytochrome P450 monooxygenase (CYP5150A2) from the white-rot basidiomycete Phanerochaete chrysosporium was heterologously expressed in Escherichia coli and purified as an active form. The purified CYP5150A2 was capable of hydroxylating 4-propylbenzoic acid (PBA) with NADPH-dependent cytochrome P450 oxidoreductase (CPR) as the single redox partner; the reaction efficiency was improved by the addition of electron transfer protein cytochrome b5 (Cyt-b5). Furthermore, CYP5150A2 exhibited substantial activity with redox partners Cyt-b5 and NADH-dependent Cyt-b5 reductase (CB5R) even in the absence of CPR. These results indicated that a combination of CB5R and Cyt-b5 may be capable of donating both the first and the second electrons required for the monooxygenation reaction. Under reaction conditions in which the redox system was associated with the CB5R-dependent Cyt-b5 reduction system, the exogenous addition of CPR and NADPH had no effect on the PBA hydroxylation rate or on coupling efficiency, indicating that the transfer of the second electron from Cyt-b5 was the rate-limiting step in the monooxygenase system. In addition, the rate of PBA hydroxylation was significantly dependent on Cyt-b5 concentration, exhibiting Michaelis-Menten kinetics. This study provides indubitable evidence that the combination of CB5R and Cyt-b5 is an alternative redox partner facilitating the monooxygenase reaction catalyzed by CYP5150A2.