Free-radical mechanism, formation

Details of the free radical formation mechanism were discussed elsewhere (16). 

The reactive species that iaitiate free-radical oxidatioa are preseat ia trace amouats. Exteasive studies (11) of the autoxidatioa mechanism have clearly estabUshed that the most reactive materials are thiols and disulfides, heterocycHc nitrogen compounds, diolefins, furans, and certain aromatic-olefin compounds. Because free-radical formation is accelerated by metal ions of copper, cobalt, and even iron (12), the presence of metals further compHcates the control of oxidation. It is difficult to avoid some metals, particularly iron, ia fuel systems. 

Acrylamide polymerization by radiation proceeds via free radical addition mechanism [37,38,40,45,50]. This involves three major processes, namely, initiation, propagation, and termination. Apart from the many subprocesses involved in each step at the stationary state the rates of formation and destruction of radicals are equal. The overall rate of polymerization (/ p) is so expressed by Chapiro [51] as ... 

K. R. and Roberts, L.J. (1990). Formation of unique biologically active prostaglandins in vivo by a non-cyclooxygenase free radical catalyzed mechanism. Adv. Prostagland. Thromboxanes Leukotriene Res. 21, 125-128. 

This may occur by free-radical formation, especially in the presence of transition-metal ions such as those of iron or copper. Similar mechanisms can result in the decomposition of peroxide but there are means of controlling or avoiding this problem. 

Different mechanisms of free radical formation as a result of the decomposition of initiators are known. 

Since for an endothermic reaction the activation energy E > AH, all such reactions cannot explain the experimental value of the activation energy (see Chapter 4). The following mechanism seems to be the most probable now. Hydrogen peroxide is protonized in a polar alcohol solution. Protonization of H202 intensifies its oxidizing reactivity. Protonized hydrogen peroxide reacts with alcohol with free radical formation. 

The chain generation by the reaction with dioxygen was studied for esters of different structures. Four mechanisms of free radical formation were evidenced. 

Other very convincing evidences for free radical-mediated mechanism of decomposition and reactions of peroxynitrite and nitrosoperoxocarboxylate were demonstrated by Lehnig [140] with the use of CIDNP technique. This technique is based on the effects observed exclusively for the products of free radical reactions their NMR spectra exhibit emission characterizing a radical pathway of their formation. Lehnig has found the enhanced emission in the 15N NMR spectra of N03- formed during the decomposition of both peroxynitrite and nitrosoperoxocarboxylate. This fact indicates that N03- was formed from radical pairs [ N02, H0 ] and [ N02, C03 ]. Emission was also observed in the reaction of both nitrogen compounds with tyrosine supposedly due to the formation of radical pair [ N02, tyrosyl ]. 

The mechanism of free radical formation in the reactions catalyzed by MPO and other heme peroxidase may be presented as follows [180] ... 

At present, numerous free radical studies related to many pathologies have been carried out. The amount of these studies is really enormous and many of them are too far from the scope of this book. The main topics of this chapter will be confined to the mechanism of free radical formation and oxidative processes under pathophysiological conditions. We will consider the possible role of free radicals in cardiovascular disorders, cancer, anemias, inflammation, diabetes mellitus, rheumatoid arthritis, and some other diseases. Furthermore, the possibilities of antioxidant and chelating therapies will be discussed. 

As mentioned above, PAF and PAF-like molecules are rapidly synthesized by keratinocytes following UV exposure. We suggest that two mechanisms are involved. UV-induced free radical formation leads to membrane oxidation and the formation of oxidized phosphatidylcholine. The PAF-like molecules bind to PAF receptors in either a paracrine or autocrine fashion. This induces the release of arachidonic acid from the membrane, activates PI.A2 and promotes the synthesis of bona fide PAF.55 The newly synthesized PAF then binds to PAF receptors, which upregulates the production of more PAF and downstream biological modifiers such as eicosanoids and cytokines. Ultimately this activates the cascade of events that leads to immune suppression. 

Transition metals (iron, copper, nickel and cobalt) catalyse oxidation by shortening the induction period, and by promoting free radical formation [60]. Hong et al. [61] reported on the oxidation of a substimted a-hydroxyamine in an intravenous formulation. The kinetic investigations showed that the molecule underwent a one-electron transfer oxidative mechanism, which was catalysed by transition metals. This yielded two oxidative degradants 4-hydroxybenzalde-hyde and 4-hydroxy-4-phenylpiperidine. It has been previously shown that a-hydroxyamines are good metal ion chelators [62], and that this can induce oxidative attack on the a-hydroxy functionality. 

The EE and phE mechanisms for neat polymers proposed by ourselves and others all involve the consequences of breaking bonds during fracture. Zakresvskii et al. (24) have attributed EE from the deformation of polymers to free radical formation, arising from bond scission. We (1) as well as Bondareva et al. (251 hypothesized that the EE produced by the electron bombardment of polymers is due to the formation of reactive species (e.g., free radicals) which recombine and eject a nearby trapped electron, via a non-radiative process. In addition, during the most intense part of the emissions (during fracture), there are likely shorter-lived excitations (e.g., excitons) which decay in a first order fashion with submicrosecond lifetimes. The detailed mechanisms of how bond scissions create these various states during fracture and the physics of subsequent reaction-induced electron ejection need additional insight. 

It is the opinion of the present authors that isomerization of a tertiary alkyl radical to a primary radical as in the formation of II from I is improbable. The formation of IV is similarly unlikely. The cycliza-tion of V by intramolecular alkylation seems quite plausible however, equation 9 does not explain either the formation of V or its subsequent cyclization. The following mechanism has the advantages that, like the generally accepted free radical-initiated mechanisms, it postulates a chain reaction and that the intramolecular alkylation step is directly analogous to that proposed for thermal alkylation, namely addition of an alkyl radical to the double bond of the alkene (Frey and Hepp, 12). The method of formation of the chain initiator, R —, again is not critical since R —, merely starts the first cycle of the chain reaction it may be formed by decomposition of the isobutylene. 

Siraki, A.G., Deterding, L.J., Bonini, M.G., Jian, J., Ehrenshaft, M., Tomer, K.B. and Mason, R.P. (2008) Procainamide, but not N-Acetylprocainamide, induces protein free radical formation on myeloperoxidase a potential mechanism of agranulocytosis. Chemical Research in Toxicology, 21, 1143-1153. 

Mo containing Y zeolites were also tested for cyclohexene oxidation with oxygen as oxidant and t-butyl hydroperoxide as initiator [86]. In this case the selectivity for cyclohexene oxide was maximum 50%, 2-cyclohexene-l-ol and 2-cyclohexene-l-one being the main side products. The proposed reaction scheme involves a free radical chain mechanism with intermediate formation of cyclohexenyl hydroperoxide. Coordination of the hydroperoxide to Mo + in the zeolite and oxygen transfer from the resulting complex to cyclohexene is believed to be the major step for formation of cyclohexene oxide under these conditions. 

This study indicates that the oxidation of dihydroanthracene in a basic medium involves the formation of a monocarbanion, which is then converted to a free radical by a one-electron transfer step. It is postulated that the free radical reacts with oxygen to form a peroxy free radical, which then attacks a hydrogen atom at the 10-position by an intramolecular reaction. The reaction then proceeds by a free-radical chain mechanism. This mechanism has been used as a basis for optimizing the yield of anthraquinone and minimizing the formation of anthracene. 

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