Glutathione Peroxidase-Like Activity of Simple Selenium Compounds. Peroxides and the Heterocyclic N-Oxide Resazurin Acting as O-Atom Donors

Selenite and selenocystamine [(CyaSe)2] efficiently activate the decomposition of H2O2 y GSH and by other thiols, as demonstrated using a leuco crystal violet POD-based H2O2 assay which is applicable (unlike other assays) also in presence of thiols. The GPx-like activities were estimated to be 3.6 and 2.7 μmol H2O2/min per μmol SeO32- and (CyaSe)2, respectively. Both selenium compounds also activate reduction of the heterocyclic N-oxide resazurin (RN→O) to resorufin (RN) by GSH; H2O2 competes with reduction of this dye. GSSeH and CyaSeH, formed by interaction of GSH with SeO32- and (CyaSe)2, respectively, are likely to be the active reductants. CyaSeH, generated γ-radiolytically from (CyaSe)2, exhibits an absorption peak at 243 nm and is removed by H2O2 with a rate constant of 9.7x102 ᴍ-1 s-1, and slightly slower by hydroperoxides. We have no evidence for one-electron interactions between GSSeH or CyaSeH and H2O2, with formation of free radical intermediates, as previously proposed in the case of selenium-activated reduction of cytochrome c by GSH (Levander et al., Biochemistry 23, 4591-4595 (1973)). Our results can be explained by O-atom transfer from the substrate to the active selenol group. RSeH + H2O2 (RN→O)→RSeOH + H2O (RN), and recycling of RSeOH to RSeH (+ H2O) by GSH, analogous to the selenenic acid pathway of GPx. The substrate specificity appears to be different, however, in that GPx is unable to catalyse RN→O reduction, and GSSeH hardly catalyses the decomposition of cumene- or t-butyl-hydroperoxide; CyaSeH, on the other hand, is active also with the hydroperoxides. RN→O is reduced to RN also by certain oxidizing free radicals, e.g. by the thiyl CyaS·; O -atom transfer may in this case lead to the generation of reactive oxyl radicals.

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Nature of Chemisorptive Mechanisms in Rubber Reinforcement

Rubber Chemistry and Technology ◽

10.5254/1.3542708 ◽

1957 ◽

Vol 30 (2) ◽

pp. 596-609 ◽

Cited By ~ 4

Author(s):

V. A. Garten ◽

G. K. Sutherland

Keyword(s):

Free Radicals ◽

Free Radical ◽

Active Sites ◽

Rubber Matrix ◽

Excess Oxygen ◽

Radical Intermediates ◽

Chemical Bond Formation ◽

Crosslinked Networks ◽

Carbon Gel ◽

State Of Research

Abstract The present state of research in the field of reinforcing rubber fillers is reviewed and it is pointed out that although a strong school of thought still maintains that the strength of bonding depends on particle size, there are many observations indicating the presence of reactive sites and suggesting the possibility of strong bonds of a chemical nature between filler and rubber matrix. The phenomenon of carbon-gel formation as foremost among these, is discussed as lending fresh support to the idea of chemical bond formation. This effect, known to be most pronounced in the presence of an unsaturated matrix is correlated with the mechanism of vulcanization as proceeding via free radical intermediates. It is suggested that the formation of chemical bonds between pigment and rubber constitutes an integral part of the chemical crosslink formation commenced on the rubber mill and completed by vulcanization. This hypothesis is corroborated by results obtained during studies on the reactivity of pigment surfaces towards simple inorganic and organic free radicals. It is shown that active pigments react with free radicals with the formation of nonionic bonds. Hydrophilic blacks have been prepared by treatment with persulfate. Similarly, electrochemically produced stearate free radicals have been reacted with the surface to form hydrophobic carbons. The “benzidine ”blue free radical, being the monooxidation product of benzidine, reacted easily with less active pigments and thus provided a useful measure of activity. From the experiments with free radicals, the number of active sites for various fillers has been calculated and shown to cover a range of 0.01–3.1 per 100 sq. A˚. Multifunctional polystyrene radicals, obtained in the presence of excess oxygen, yielded crosslinked networks with carbon blacks which resisted solvent extraction. These are considered to be complete analogues to carbon gel. The statistical mechanics of the rubber network has been developed to include crosslink formation as caused by rubber-filler interaction. It is shown that the mechanical properties of a rubber compound that are controlled solely by the network structure are directly proportional to σ/r, the ratio between the number of active sites per unit area and the particle radius. Abrasion does not appear to be only a mechanical phenomenon.

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Characterization and Fate of Hydrogen-Bonded Free-Radical Intermediates and Their Coupling Products from the Hydrogen Atom Transfer Agent 1,8-Naphthalenediol

ACS Omega ◽

10.1021/acsomega.8b00155 ◽

2018 ◽

Vol 3 (4) ◽

pp. 3918-3927 ◽

Cited By ~ 9

Author(s):

Paola Manini ◽

Massimo Bietti ◽

Marco Galeotti ◽

Michela Salamone ◽

Osvaldo Lanzalunga ◽

...

Keyword(s):

Free Radical ◽

Hydrogen Atom ◽

Hydrogen Atom Transfer ◽

Atom Transfer ◽

Radical Intermediates ◽

Hydrogen Bonded

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THE STRUCTURE OF BUTADIENE DIMERS PRODUCED BY A FREE-RADICAL CHAIN-TRANSFER MECHANISM

Canadian Journal of Chemistry ◽

10.1139/v57-194 ◽

1957 ◽

Vol 35 (12) ◽

pp. 1467-1474 ◽

Cited By ~ 3

Author(s):

L. J. Gendron ◽

R. V. V. Nicholls

Keyword(s):

Free Radicals ◽

Free Radical ◽

Chain Transfer ◽

Transfer Mechanism ◽

The Other ◽

Chain Transfer Agent ◽

Radical Chain

Butadiene was dimerized by using acetyl peroxide as source of free radicals and chloroform as solvent and chain-transfer agent. The dimers were identified and their structures were determined by means of ozonolysis and oxidative hydrolysis. It was established that two dimers were produced in nearly equal amount. One dimer was formed only by 1,4-additions, the other only by 1,2-additions. This result implies that polybutadienes may be mixtures of two varieties: one variety resulting from 1,4-additions, the other from 1,2-additions.

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Free Radicals Generated in Photocatalytic Oxidation of Some Amines and Diamines

Journal of Advanced Oxidation Technologies ◽

10.1515/jaots-1996-0205 ◽

1996 ◽

Vol 1 (2) ◽

Author(s):

Ciping Chen ◽

Daohui Lu ◽

Guangzhi Xu

Keyword(s):

Free Radicals ◽

Free Radical ◽

Photocatalytic Oxidation ◽

Spin Trapping ◽

Experimental Results ◽

Epr Spectra ◽

Radical Species ◽

Radical Intermediates ◽

Radical Adduct ◽

Spin Trapping Technique

AbstractFree radical intermediates produced during photocatalytic oxidation of some typical amines and diamines were investigated by a spin trapping technique. The EPR spectra of N-centered radical adduct and Ccentered radical adduct were observed. Experimental results disclose that these radicals are participants in the initial steps of photodegradation of these compounds. A mechanism which is consistent with the observation of these radical species is discussed.

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Flavonoids with Glutathione Antioxidant Synergy: Influence of Free Radicals Inflow

Antioxidants ◽

10.3390/antiox9080695 ◽

2020 ◽

Vol 9 (8) ◽

pp. 695 ◽

Cited By ~ 1

Author(s):

Igor Ilyasov ◽

Vladimir Beloborodov ◽

Daniil Antonov ◽

Anna Dubrovskaya ◽

Roman Terekhov ◽

...

Keyword(s):

Free Radicals ◽

Free Radical ◽

Antioxidant Capacity ◽

Sulfonic Acid ◽

Lag Time ◽

The Other ◽

Molar Ratio ◽

Different Types ◽

Great Excess ◽

The One

This report explores the antioxidant interaction of combinations of flavonoid–glutathione with different ratios. Two different 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid radical (ABTS•+)-based approaches were applied for the elucidation of the antioxidant capacity of the combinations. Despite using the same radical, the two approaches employ different free radical inflow systems: An instant, great excess of radicals in the end-point decolorization assay, and a steady inflow of radicals in the lag-time assay. As expected, the flavonoid–glutathione pairs showed contrasting results in these two approaches. All the examined combinations showed additive or light subadditive antioxidant capacity effects in the decolorization assay. This effect showed slight dilution dependence and did not change when the initial ABTS•+ concentration was two times as high or low. However, in the lag-time assay, different types of interaction were detected, from subadditivity to considerable synergy. Taxifolin–glutathione combinations demonstrated the greatest synergy, at up to 112%; quercetin and rutin, in combination with glutathione, revealed moderate synergy in the 30–70% range; while morin–glutathione appeared to be additive or subadditive. In general, this study demonstrated that, on the one hand, the effect of flavonoid–glutathione combinations depends both on the flavonoid structure and molar ratio; on the other hand, the manifestation of the synergy of the combination strongly depends on the mode of inflow of the free radicals.

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Anti-Oxidant effects of Swarnamakshika Bhasma : A Experimental Study

Journal of Ayurveda and Integrated Medical Sciences (JAIMS) ◽

10.21760/jaims.5.4.16 ◽

2020 ◽

Vol 5 (04) ◽

pp. 92-101

Author(s):

Shrikanth AS ◽

P. G. Jadar

Keyword(s):

Free Radicals ◽

Free Radical ◽

Food Habits ◽

Cellular Level ◽

Oxidation Reactions ◽

Chain Reactions ◽

Herbal Preparations ◽

Radical Intermediates ◽

Immune System Dysfunction ◽

Anti Oxidant

Shodhana of Swarnamakshika carried out by Bharjana in Eranda Tila. Marana of Swarnamakshika by finely powdered Shudda Swarnamakshika was taken in a Khalvayantra. Then equal quantity of Shudda Gandhaka was added and triturated together till they become homogenous. To this mixture 100ml of Jambhira Rasa was added triturated well till it becomes semisolid consistency. The paste were made into shape of Chakrikas weighing 25gm and 8cm uniformly and kept for drying. Subjecting into 5 required number of Varahaputas. The present day lifestyle and food habits have increased the production of free radicals. These cytotoxic free radicals not only raise the oxidative stress but also play an important role in the immune-system dysfunction due to which the mankind is prone to various major ailments and it is now proved that diseases like Prameha, Pandu, Vatavyadhi etc. are free radical mediated ones. To tackle these free radicals our body needs antioxidants. An antioxidant is a molecule which is capable of inhibiting the oxidation of other molecules. Oxidation reactions can produce free radicals which in turn start chain reactions that damage cells. Antioxidants terminate these chain reactions by removing free radical intermediates and inhibit other oxidation reactions. Many herbals drugs and compound herbal preparations have been screened for their antioxidant and immuno-modulatory properties but still there is a need for effective antioxidants. This dearth and also the fact that Swarnamakshika is being used in treating many of the free radical mediated diseases prompted us to take the present study which aims to validate the Antioxident effect of Swarnamakshika Bhasma scientifically and explain its probable mode of action at the cellular level.

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Free-Radical Intermediates in Atom Transfer Radical Addition and Polymerization: Study of Racemization, Halogen Exchange, and Trapping Reactions

Macromolecules ◽

10.1021/ma010268q ◽

2001 ◽

Vol 34 (10) ◽

pp. 3127-3129 ◽

Cited By ~ 28

Author(s):

Krzysztof Matyjaszewski ◽

Hyun-jong Paik ◽

Devon A. Shipp ◽

Yutaka Isobe ◽

Yoshio Okamoto

Keyword(s):

Free Radical ◽

Radical Addition ◽

Atom Transfer ◽

Radical Intermediates ◽

Halogen Exchange ◽

Atom Transfer Radical Addition ◽

Trapping Reactions

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The involvement of oxygen-derived free radicals in plant–pathogen interactions

Proceedings of the Royal Society of Edinburgh Section B Biological Sciences ◽

10.1017/s0269727000014500 ◽

1994 ◽

Vol 102 ◽

pp. 479-493

Author(s):

B. A. Goodman

Keyword(s):

Free Radicals ◽

Free Radical ◽

Atmospheric Oxygen ◽

Oxygen Species ◽

Defence Mechanisms ◽

Paramagnetic Resonance ◽

Radical Intermediates ◽

Oxygen Derived Free Radicals ◽

Plant Pathogen Interactions ◽

Electron Paramagnetic

SynopsisPlants have evolved a multiplicity of defence mechanisms against pathogen attack. Their modes of action may be to (i) kill the pathogen directly, (ii) block the action of enzymes required for infection, or (iii) erect barriers to pathogen growth. Some of these reactions proceed via free radical intermediates and make use of either atmospheric oxygen or reactive oxygen species. This paper reviews the various types of reaction involving oxygen-derived free radicals that are initiated in plant tissue when it is invaded by pathogenic organisms. Both the production of free radicals by plants in defensive processes and the utilisation of free radicals by pathogens in offensive reactions are considered and particular attention is given to the use of electron paramagnetic resonance (EPR) spectroscopy for the direct observation of such free radical reactions.

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Sulfamides Direct Radical-Mediated Chlorination of Aliphatic C–H Bonds

10.26434/chemrxiv.8120654 ◽

2019 ◽

Author(s):

Melanie Short ◽

Mina Shehata ◽

Matthew Sanders ◽

Jennifer Roizen

Keyword(s):

Hydrogen Atom ◽

Transfer Reaction ◽

Hydrogen Atom Transfer ◽

Chain Propagation ◽

Propagation Mechanism ◽

Atom Transfer ◽

Radical Chain ◽

Radical Intermediates ◽

Transfer Processes ◽

Unusual Position

Sulfamides guide intermolecular chlorine transfer to gamma-C(sp<sup>3</sup>) centers. This unusual position-selectivity arises because accessed sulfamidyl radical intermediates engage in otherwise rare 1,6-hydrogen-atom transfer processes. The disclosed chlorine-transfer reaction relies on a light-initiated radical chain-propagation mechanism to oxidize C(sp<sup>3</sup>)-H bonds.

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