Adduct radicals

Homolytic cleavage of dlazonlum salts to produce aryl radicals is induced by titan1um(III) salt, which is also effective in reducing the a-carbonylalkyl radical adduct to olefins, telotnerization of methyl vinyl ketone, and dimerization of the adduct radicals. The reaction can be used with other electron-deficient olefins, but telomerization or dimerization are important side reactions. 

Other limitations of the reaction are related to the regioselectivity of the aryl radical addition to double bond, which is mainly determined by steric and radical delocalization effects. Thus, methyl vinyl ketone gives the best results, and lower yields are observed when bulky substituents are present in the e-position of the alkene. However, the method represents complete positional selectivity because only the g-adduct radicals give reductive arylation products whereas the a-adduct radicals add to diazonium salts, because of the different nucleophilic character of the alkyl radical adduct. ... 

In related work, the reactions of hydrogen peroxide with iron(II) complexes, including Feu(edta), were examined.3 Some experiments were carried out with added 5.5"-dimethyl-1-pyrroline-N-oxide (DMPO) as a trapping reagent fa so-called spin trap) for HO. These experiments were done to learn whether HO was truly as free as it is when generated photochemically. The hydroxyl radical adduct was indeed detected. but for some (not all) iron complexes evidence was obtained for an additional oxidizing intermediate, presumably an oxo-iron complex. 

Developments in the synthesis and characterization of stable silylenes (RiSi ) open a new route for the generation of silyl radicals. For example, dialkylsilylene 2 is monomeric and stable at 0 °C, whereas N-heterocyclic silylene 3 is stable at room temperature under anaerobic conditions. The reactions of silylene 3 with a variety of free radicals have been studied by product characterization, EPR spectroscopy, and DFT calculations (Reaction 3). EPR studies have shown the formation of several radical adducts 4, which represent a new type of neutral silyl radicals stabilized by delocalization. The products obtained by addition of 2,2,6,6-tetramethyl-l-piperidinyloxy (TEMPO) to silylenes 2 and 3 has been studied in some detail. ... 

Kim and coworkers introduced silyl radical mediated addition of alkyl radical to silyloxy enamine 76. The silyloxy enamine moiety is readily accessible from a variety of functionalities. The mechanistic concept is illustrated in the Scheme 12 and involves the addition of R radical to 76 to give the radical adduct 77 and the subsequent homolytic cleavage of N-O bond to yield the desired product 78 and a silyloxy radical 79. The latter undergoes 1,2-phenyl migration to give the silyl radical 80 that abstracts halogen from the alkyl halide to regenerate the R radical. 

Silyl radicals generated from both phenyl and n-hexyl substituted poly-(hydrosilane)s add readily to a variety of compounds containing C = C and 0 = C moieties to give the corresponding radical adducts for which EPR spectra have been recorded. ... 

Nevertheless, such a combination of polar factors actually makes this step less efficient than that is usually in the reactions with CBr4, and as a result the radical-adduct CB3CH2CHCF3 takes part in concurrent reaction of growth chain with another monomer molecule to form telomer T2 this is basically non-typical for reactions of CBr4. 

Floyd, R.A. Zs-Nagy (1984). Formation of long lived hydroxyl free radical adducts of proline and hydroxyproline in a Fenton reaction. Biochimica Bio-physica Acta, 790, 94-7. 

The pinacol formation reaction follows a radical mechanism. Benzopinacol, benzophenone and the mixed pinacol are formed jointly with many radical species [72, 74]. In the course of the reaction, first a high-energy excited state is generated with the aid of photons. Thereafter, this excited-state species reacts with a solvent molecule 2-propanol to give two respective radicals. The 2-propanol radical reacts with one molecule of benzophenone (in the ground state, without photon aid) to lengthen the radical chain. By combination of radicals, adducts are formed, including the desired product benzopinacol. Chain termination reactions quench the radicals by other paths. 

Floyd, R.A., Watson, J.J., Wong, P.K., Altmiller, D.H. and Rickard, R.C. (1986). Hydroxyl-free radical adduct of deox-yguanosine sensitive detection and mechanisms of formation. Free Rad. Res. Commun. 1, 163-172. 

Radical attack yields nucleobase radical adducts that must undergo either oxidation or rednction to yield a stable final prodnct. The cellular oxidant in these reactions may be molecnlar oxygen or high-valent transition metal ions (e.g., Fe ), while the reduc-tant may be either thiols, snperoxide radical, or low-valent transition metal ions (e.g., Fe ). In many cases, the base remains largely intact and the seqnence of chemical events can be readily inferred. In some other cases, more extensive base decomposition occurs. Here, we will consider a set of representative examples that provide a framework for understanding virtnally all radical-mediated base damage reactions. 

ENDOR spectrum exhibited chlorine and nitrogen splittings indicating a carotenoid-quinone radical adduct formation. 

In case of scavenging of lipid-derived peroxyl radicals (LOO"), the radical adduct formed [LOO-CaiT is less reactive than the LOO, so carotenoids act as chain-breaking antioxidants in lipid peroxidation (Equation 15.6) ... 

A spin trap is a diamagnetic compound that reacts with a radical by addition of the radical functionality typically to a double bond in the trap, thus forming a new radical that is more stable (better, less unstable) than the original radical. By far the most common class of spin traps are nitrone compounds that, upon addition of the primary radical, produce a stable aminoxyl radical (Figure 10.1). The compound DMPO is the paradigmatic spin trap it is readily available, widely used, and its EPR spectra are relatively easy to interpret. Some of its radical adducts have unpractically short lifetimes. 

FIGU RE 10.1 The structure of DMPO. The diamagnetic compound 5,5-dimethyl-l-pyrroline-iV-oxide reacts with an unstable radical R to form a relatively stable radical adduct. 

From the EPR spectroscopist s viewpoint the spin-trap experiment is next to trivial the molecular mass of the radical adduct is small enough to guarantee the molecule to tumble sufficiently rapidly at ambient temperatures in aqueous solution to ensure complete averaging away of any anisotropy in the spin Hamiltonian ... 

In principle, EPR spectrometry is well suited as a method to monitor kinetic events however, in practice, the time required to tune the spectrometer, and its intrinsically low sensitivity compared to fluorescence or light-absorption spectrometry, affect its competitiveness. Relatively slow reactions on the timescale of minutes, such as the decomposition of the DMPO-superoxide adduct and the subsequent formation of the hydroxyl radical adduct (cf. Pou et al. 1989) are readily followed, either as the first-order disappearance of the DMPO/ OOH signal... 

In contrast to the direct reduction as described above, the indirect electrochemical reduction of perfluoroalkyl halides is a versatile and novel method for generating perfluoroalkyl radicals selectively. Saveant et al. have demonstrated many successful examples. Using terephthalonitrile as a mediator, the indirect reduction of CF3Br in the presence of styrene leads to the dimer of the radical adduct obtained by the attack of CF on styrene. On the other hand, in the presence of butyl vinyl ether, the mediator reacts with the radical adduct obtained by the attack of CF3. on the olefin (Scheme 3.4) [14]. 

Germyl enol ethers react with perfluoroalkyl iodides under Et3B initiation to give a-pcrfluoroalkyl ketones. The intermediate radical adduct decomposes readily via /1-elimination and provides the a-perfluoroalkyl ketone and a trialkylgermanyl radical as a chain carrier (Scheme 12) [32]. 

The use of nitrone scavengers was precedented by the work of Iwamura and Inamoto (1967), who had used esr spectroscopy to detect the nitroxide formed by addition of cyanopropyl radicals to the cyclic nitrone, 5,5-dimethyl-pyrroline-N-oxide (DMPO) [2], and had actually isolated the cyanopropyl radical adduct of the nitrone [3]. 

Table 6 Acyloxyl radical adducts formed in the oxidation of tetrabutylammonium carboxylates and PBN [3] by Ph4POsvCl6 in dichloromethane at 20°C. ...

Formation of phenylhydronitroxide radicals, DMPO (5,5-dimethyl-l-pyrroline-7V-oxide)/glutathiyl and DMPO/hemoglobin thiyl free radical adducts has been detected in erythrocytes of rats in vivo after administration of nitrosobenzene and phenylhydroxylamine, respectively92,94. The data, however, could also be interpreted in a different way ... 

---