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One-electron oxidation activation

Subsequent studies (63,64) suggested that the nature of the chemical activation process was a one-electron oxidation of the fluorescer by (27) followed by decomposition of the dioxetanedione radical anion to a carbon dioxide radical anion. Back electron transfer to the radical cation of the fluorescer produced the excited state which emitted the luminescence characteristic of the fluorescent state of the emitter. The chemical activation mechanism was patterned after the CIEEL mechanism proposed for dioxetanones and dioxetanes discussed earher (65). Additional support for the CIEEL mechanism, was furnished by demonstration (66) that a linear correlation existed between the singlet excitation energy of the fluorescer and the chemiluminescence intensity which had been shown earher with dimethyl dioxetanone (67). [Pg.266]

Polymerization Initiator. Some unsaturated monomers can be polymerized through the aid of free radicals generated, as transient intermediates, in the course of a redox reaction. The electron-transfer step during the redox process causes the scission of an intermediate to produce an active free radical. The ceric ion, Ce" ", is a strong one-electron oxidizing agent that can readily initiate the redox polymerization of, for example, vinyl monomers in aqueous media at near ambient temperatures (40). The reaction scheme is... [Pg.371]

Cremonesi P, EL Cavalieri, EG Rogan (1989) One-electron oxidation of 6-substituted benzo(a)pyrenes by manganic acetate. A model for metabolic activation. J Org Chem 54 3561-3570. [Pg.137]

Many of the problems and misconceptions occurring for dithiolene compounds are related to the fact that the ligands are redox-active and can be oxidized to monoanionic radicals. Typical examples for this phenomenon are the mono and diradical complexes [Fe ( "bdt )( "bdt)(PMe3)] (9) and [Fe ( "bdf)2(PMe3)]-" (10) for which bdt and bdt are tcrt-butyl-dithiolene and its one-electron oxidized form. Originally, these and other bdt derivatives had been described as... [Pg.420]

The one-step reaction of H2prCl6] with MeC02Li under 02 in a mixed solvent of acetic acid and acetic anhydride yields the Ir11 binuclear complex [Ir2(/u-02CMe)2Cl2(C0)2].483 Crystal-structure determinations of [Ir2(/x-02CMe)2Cl2(C0)2L2], (295), where L = MeCN, DMSO, and py, are reported. The one-electron oxidation product for (295), L = py, is EPR active at 77 K the odd electron occupies the 6Ir Ir orbital. [Pg.200]

A relatively low potential, one-electron oxidation is observed (Equation (72)), followed above pH 2.2 by a two-electron oxidation, two-proton step (Equation (73)) and a one-electron oxidation (Equation (74)). In more acidic solutions a direct three-electron oxidation occurs leading also to the [Ruv O Ruv]4+ species. In various studies the Rulv O Rulv, RuIV-0 Ruv, and Ruv O Ruv species have been considered as the catalytically active form. Although these species have been characterized by resonance Raman and EPR spectroscopies,475,476,480 no definitive conclusion about the mechanism involved in the catalysis can be drawn and the question remains largely open. [Pg.497]

Radicals are versatile synthetic intermediates. One of the efficient procedures for radical generation is based on one-electron oxidation or reduction with transition metal compounds. An important feature is that the redox activity of transition metal compounds can be controlled by appropriate ligands, in order to attain chemoselectivity in the generation of radicals. The application to small ring compounds provides useful methods for organic syntheses. Reductive transformation are first reviewed here. [Pg.139]

PAH radical cations are also involved in the metabolic conversion of PAH to PAH diones. Carcinogenicity studies of PAH in rat mammary gland indicate that only PAH with ionization potential low enough for activation by one-electron oxidation induce tumors in this target organ. These results and others indicate that one-electron oxidation of PAH is involved in their tumor initiation process. [Pg.293]

At present a variety of studies with PAH, as well as other chemicals, suggest that metabolic activation in target tissues can occur by one-electron oxidation (6,7). The electrophilic intermediate radical cations generated by thTs mechanism can react directly with various cellular nucleophiles. In this paper, we will discuss chemical, biochemical and biological evidence which indicates that one-electron oxidation plays an important role in the metabolic activation of PAH. [Pg.294]

For activation by one-electron oxidation, these properties of PAH radical cations enable us to predict the position(s) at which covalent binding of PAH to cellular targets may occur. [Pg.294]

This list includes BP, 7,12-dimethylbenz[a]anthracene, 3-methylchol-anthrene, dibenzo[a,i]pyrene and dibenzo[a,h]pyrene. These PAH can be activated both by one-electron oxidation and/or monooxygenation. There are a few PAH with low IP which are inactive (Table I), such as perylene, or weakly active, such as anthanthrene. This indicates that low IP is a necessary, but not sufficient factor for determining carcinogenic activity by one-electron oxidation. These inactive or weakly active PAH have the highest density of positive charge delocalized over several aromatic carbon atoms in their radical cations, whereas the active PAH with low IP have charge mainly localized on one or a few carbon atoms in their radical cations. [Pg.300]

The first line of evidence derives from the predominant formation of quinones when metabolism of BP is conducted under peroxi-datic conditions, namely by prostaglandin H synthase (21) or by cytochrome P-450 with cumene hydroperoxide as cofactor T22). Under these metabolic conditions one-electron oxidation is the preponderant mechanism of activation. [Pg.300]

The carcinogenicity of a series of PAH in the mammary gland has been examined in 50-day-old female Sprague-Dawley rats using direct application of the compound to the mammary tissue (1 , 17, 18). The results of these experiments, presented in Table III, are compared to the carcinogenicity results in mouse skin from repeated application obtained in our laboratory and others. PAH were selected because they were or were not expected to be activated by one-electron oxidation, based on the hypothesis that compounds with relatively high IP cannot be activated by this mechanism. Furthermore, some... [Pg.304]

PAH were chosen in which activation by monooxygenation or one-electron oxidation was blocked. [Pg.306]

The only difference between the active oxidizing and a ferric porphyrin hydroxide complex is two electrons (scheme 4). Indeed, the electrochemical oxidation of hydroxy ferric tetra-mesitylporphyrin shows two reversible one-electron oxidations (40), and, in principle, use of water and an electrode should allow development of a system capable of catalytically oxidizing hydrocarbons. [Pg.106]

Laccase is one of the main oxidizing enzymes responsible for polyphenol degradation. It is a copper-containing polyphenoloxidase (p-diphenoloxidase, EC 1.10.3.2) that catalyzes the oxidation of several compounds such as polyphenols, methoxy-substituted phenols, diamines, and other compounds, but that does not oxidize tyrosine (Thurston, 1994). In a classical laccase reaction, a phenol undergoes a one-electron oxidation to form a free radical. In this typical reaction the active oxygen species can be transformed in a second oxidation step into a quinone that, as the free radical product, can undergo polymerization. [Pg.116]

The competition between antioxidant and prooxidant activity of flavonoids depends firstly on their chemical structure. If we suppose that the oxidation of flavonoids (Reaction (17)) takes place by one-electron transfer mechanism, then it must depend on the capacity of flavonoids to donate an electron, i.e., on their one-electron oxidation potentials. [Pg.869]

There are two kinds of redox interactions, in which ubiquinones can manifest their antioxidant activity the reactions with quinone and hydroquinone forms. It is assumed that the ubiquinone-ubisemiquinone pair (Figure 29.10) is an electron carrier in mitochondrial respiratory chain. There are numerous studies [235] suggesting that superoxide is formed during the one-electron oxidation of ubisemiquinones (Reaction (25)). As this reaction is a reversible one, its direction depends on one-electron reduction potentials of semiquinone and dioxygen. [Pg.877]

Cytochrome c oxidase is an enzyme that couples the one-electron oxidation of cytochrome c to the four-electron reduction of 02 and is thus a crucial component of respiration. Cytochrome c contains the redox-active heme c, while cytochrome c oxidase contains a dinuclear Cua redox site in subunit II and three redox-active sites in subunit I heme a, heme a3, and Cur. It is believed that heme a is an electron-transfer site, while heme a3 and Cur function together at the 02 reduction site. [Pg.372]

See other pages where One-electron oxidation activation is mentioned: [Pg.112]    [Pg.360]    [Pg.227]    [Pg.232]    [Pg.112]    [Pg.360]    [Pg.227]    [Pg.232]    [Pg.254]    [Pg.303]    [Pg.60]    [Pg.259]    [Pg.303]    [Pg.286]    [Pg.670]    [Pg.189]    [Pg.263]    [Pg.446]    [Pg.497]    [Pg.293]    [Pg.296]    [Pg.304]    [Pg.304]    [Pg.306]    [Pg.306]    [Pg.344]    [Pg.723]    [Pg.733]    [Pg.204]    [Pg.241]    [Pg.81]   


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4- one 1-oxide

Activated oxidation

Activation electronic

Activation oxidation

Active oxides

Activity oxidation

Electron Oxidants

Electron activation

Electron oxidation activation

Electronic oxides

Electrons active

Electrons oxidation

One oxidation

One-electron oxidant

Oxidation one-electron

Oxidative activation

Oxides activated

Oxidizing activators

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