Arylamines oxidation products

The reagent prepared from the reaction of 30 % hydrogen peroxide with glacial acetic acid also contains peroxyacetic acid but the main product of arylamine oxidation is usually the corresponding nitroso compound. On heating with an excess of this reagent the nitro compound is usually obtained. ... 

Prostaglandin synthetase, peroxidase or lipid peroxidation have been shown to oxidise arylamine xenobiotics to reactive species that bind extensively to DNA. The binding could be an initial event in the toxic or carcinogenic process. Evidence is presented that cation radicals are involved in the formation of the various oxidation products and DNA adduct formation with the carcinogen aminofluorene. Furthermore methylaminoazobenzene (butter yellow) was found to form the same major GSH adduct as is formed in vivo. 

Phenols are less effective antioxidants than the arylamines but they are non-discolouring. They are converted into a variety of oxidation products e.g. quinones and stable phenoxyl radicals) by further reaction with oxygen or peroxyl radicals (page 64). Many of these are themselves antioxidants. 

Treatment of amine oxides containing at least one nitrogen-attached methyl group with acetic anhydride, results in the Polonovski reaction (reaction 65) product studies on which indicate the involvement of radicals . The reaction is also catalysed by Fe(ni) and by many transition-metal complexes (reaction 66) . These reactions have been studied as models for the bacterial degradation of nicotine which involves iV-oxidation as the first step . JV Arylamine oxides give considerable amounts of o-acetylarylamines on treatment with acetic anhydride, presumably via cyclisation from the N-ace-tate , and similar migrations are common for heterocyclic... 

In studies with chloroperoxidase (CPX), a peroxidative enzyme that is amazingly similar in certain properties to cytochrome P-450, we found the nitrosoarene metabolite to be the terminal product of arylamine oxidation (Fig. 6) (23, 31). CPX has been used to prepare nitrosoarene chemicals on a micro scale (17) because few chemical techniques are available for the direct conversion of arylamines to nitrosoarene compounds (28). It is probable that this enzymatic oxidation produces an intermediary hydroxylamine compound which, under the reaction conditions, is rapidly converted to the nitroso level. An apparent kinetic block in the oxidation of nitrosoarene to nitroaromatic compounds allows for the fairly selective production of the former by mild oxidants, particularly for those arylamines with electron-withdrawing substituents. 

The formation of 0-seryl or 0-prolyl esters (Figure 1) of certain N-hydroxy arylamines has been inferred from the observations that highly reactive intermediates can be generated in vitro by incubation with ATP, serine or proline, and the corresponding aminoacyl tRNA synthetases (11,12,119). For example, activation of N-hydroxy-4-aminoquinoline-l-oxide (119,120), N-hydroxy-4-aminoazobenzene (11) and N-hydroxy-Trp-P-2 (121) to nucleic acid-bound products was demonstrated using seryl-tRNA synthetase from yeast or rat ascites hepatoma cells. More recently, hepatic cytosolic prolyl-, but not seryl-, tRNA synthetase was shown to activate N-hydroxy-Trp-P-2 (12) however, no activation was detectable for the N-hydroxy metabolites of AF, 3,2 -dimethyl-4-aminobiphenyl, or N -acetylbenzidine (122). 

The identification of C8-guanyl and N6-adenyl adducts of 4-aminoquinoline-l-oxide (102,103) in DNA modified by the metaboli-cally-generated 0-seryl ester and the similarity of the adduct profile with that obtained on reaction of DNA with N-acetoxy-4-araino-quinoline-l-oxide suggest an electrophilic reaction mechanism similar to that for the N-acetoxy or N-sulfonyloxy arylamines (Figures 4 and 5). However, N-seryloxy or N-prolyloxy arylamines have not been synthesized and the decomposition products of the esters generated in vitro have not yet been studied. 

N-AryInitrones (XIII) formed by oxidation of N-hydroxy-N-methyl arylamines, show high reactivity toward carbon-carbon and carbon-nitrogen double bonds in non-aqueous media (21,203) (Figure 10). Under physiological conditions, however, it appears that N-arylnitrones exist as protonated salts that readily hydrolyze to formaldehyde and a primary N-hydroxy arylamine and efforts to detect N-arylnitrone addition products in cellular lipid, protein or nucleic acids have not been successful (204). Nitroxide radicals derived from N-hydroxy-MAB have also been suggested as reactive intermediates (150), but their direct covalent reaction with nucleic acids has been excluded (21). 

Acidic ring closure resembles the Du Pont process in that the central benzene ring of the quinacridone structure is synthesized totally. The process bears resemblance to the Liebermann method [2, see also 1.3]. Condensation of succinylosuc-cinic ester with two equivalents of arylamine affords 2,5-diarylamino-3,6-dihy-droterephthalic diester. Subsequent oxidation with suitable agents yields 2,5-di-arylaminoterephthalic diester 57. Hydrolysis and cyclization in polyphosphoric acid or other acidic condensation agents produces crude quinacridone [10]. This product already consists of very small particles. 

Although the synthesis is completed in very few steps, oxidation of 1,4-xylene to the corresponding terephthalic acid does not afford a uniform product. Partial dihalogenation gives rise to side products. The condensation reaction requires two equivalents of arylamine per halogen atom. One equivalent is needed to neutralize the generated hydrohalogen acid, which is subsequently separated as aryl-amine-hydrohalide and recycled as hydrohalide and arylamine. 

More recently, an environmentally benign method using air as oxidant has been developed for the oxidative cyclization of arylamine-substituted tricarbonyl-iron-cyclohexadiene complexes to carbazoles (Scheme 19). Reaction of methyl 4-aminosalicylate 45 with the complex salt 6a affords the iron complex 46, which on oxidation in acidic medium by air provides the tricarbonyliron-complexed 4a,9a-dihydrocarbazole 47. Aromatization with concomitant demetalation by treatment of the crude product with p-chloranil leads to mukonidine 48 [88]. The spectral data of this compound are in agreement with those reported by Wu[22j. 

An alternative method for the oxidative cyclization of the arylamine-substituted tricarbonyl(r -cyclohexa-l,3-diene)iron complex (725) is the iron-mediated arylamine cyclization. Using ferricenium hexafluorophosphate in the presence of sodium carbonate provided hyellazole (245) directly, along with the complex 727, which was also converted to the natural product (599,600) (Scheme 5.71). 

Both NAT1 and NAT2 N-acetylate benzidine and O-acetylate the N-hydroxy metabolite. Because NAT2 and, to a lesser extent, NAT1 both show variation in the human population, this influences susceptibility to the carcinogenic effects of arylamines such as benzidine. With other aromatic amines, such as the heterocyclic amines found as food pyrolysis degradation products, N-acetylation is not favored, N-oxidation being the primary route followed by O-acetylation. This seems to take place in the colon. 

Hydroxylation of arylamines with persulfate ion, or Boyland-Sims oxidation, gives ortho-substituted aminophenols in good yields [29]. As with the Elbs oxidation, the procedure is also carried out in two steps - first, treatment with the oxidant to obtain an aminophenyl sulfate ester and, second, hydrolysis to obtain the final product. Primary, secondary and tertiary amines can all be used in this reaction. The ortho product is formed, except when no ortho-positions are available, which leads to para-substitution. Electrophilic attack on the ipso-carbon is believed to be the most likely mechanism, although minor radical pathways also seem to be present. 

The most studied kinds of explosives are nitroaromatic explosives and their metabolites. Therefore, the emphasis of this review is on properties of nitroaromatic explosives, rather than propellants, pyrotechnics, or munitions, and their interactions with soils. Nitroaromatic explosives are toxic, and their environmental transformation products, including arylamines, arylhydroxyl-amines, and condensed products such azoxy- and azo-compounds, are equally or more toxic than the parent nitroaromatic [3]. Aromatic amines and hydroxylamines are implicated as carcinogenic intermediates as a result of nitrenium ions formed by enzymatic oxidation [4], Aromatic nitro compounds... 

Multiple arylations of polybromobenzenes have been conducted to generate electron-rich arylamines. Tribromotriphenylamine and 1,3,5-tribromobenzene all react cleanly with A-aryl piperazines using either P(o-tolyl)3 or BINAP-ligated catalysts to form hexamine products [107]. Reactions of other polyhalogenated arenes have also been reported [108]. Competition between aryl bromides and iodides or aryl bromides and chlorides has been investigated for the formation of aryl ethers [109], and presumably similar selectivity is observed for the amination. In this case bro-mo, chloroarenes reacted preferentially at the aryl bromide position. This selectivity results from the faster oxidative addition of aryl bromides and is a common selectivity observed in cross-coupling. Sowa showed complete selectivity for amination of the aryl chloro, bromo, or iodo over aryl-fluoro linkages [110]. This chemistry produces fluoroanilines, whereas the uncatalyzed chemistry typically leads to substitution for fluoride. 

In 1994, Paul, Patt, and Hartwig showed that the Pd(0) catalyst in Kosugi s process was Pd[P(o-C6H4Me)312 (3), which underwent oxidative addition of aryl halides to give dimeric aryl halide complexes (4) [91]. These aryl halide complexes reacted directly with tin amides to form arylamine products (Eq. (3)). Thus, this chemistry could formally be viewed as being roughly parallel to Stille coupling. 

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