Hydroxylamines from aromatic nitro

Electrolytic reductions generally caimot compete economically with chemical reductions of nitro compounds to amines, but they have been appHed in some specific reactions, such as the preparation of aminophenols (qv) from aromatic nitro compounds. For example, in the presence of sulfuric acid, cathodic reduction of aromatic nitro compounds with a free para-position leads to -aminophenol [123-30-8] hy rearrangement of the intermediate N-phenyl-hydroxylamine [100-65-2] (61). 

Formation of azo-type products might be troublesome. These by-products, arising from reduction of aromatic nitro compounds, usually are assumed to be derived from the coupling of intermediate nitroso and hydroxylamine compounds. The coupling problem is accentuated in reduction of nitroso compounds because of much higher concentrations. It can be alleviated by dropwise addition of the substrate to the hydrogenation and use of acidic media. 

I.2. Oxidation of Amines Oxidation of primary amines is often viewed as a particularly convenient way to prepare hydroxylamines. However, their direct oxidation usually leads to complex mixtures containing nitroso and nitro compounds and oximes. However, oxidation to nitrones can be performed after their conversion into secondary amines or imines. Sometimes, oxidation of secondary amines rather than direct imine oxidation seems to provide a more useful and convenient way of producing nitrones. In many cases, imines are first reduced to secondary amines which are then treated with oxidants (26). This approach is used as a basis for a one-pot synthesis of asymmetrical acyclic nitrones starting from aromatic aldehydes (Scheme 2.5) (27a) and 3,4-dihydroisoquinoline-2-oxides (27b). 

Hydroxylamines can be synthesized from various aliphatic and aromatic nitro compounds by reduction with metals and other one-electron donors, with complex hydrides and other two-electron donors, and by hydrogenation. In all cases the reduction proceeds stepwise and, depending on reaction conditions, can provide both amines and hydroxylamines. 

Historically this reaction developed from the assumption that the formation of azoxy compounds by the reduction of aromatic nitro compounds probably involved the intermediate formation of C-nitroso compounds and hydroxylamines. In the all-aliphatic series, this reaction appears to be quite general. Symmetrically and unsymmetrically substituted azoxy compounds have been prepared by it, the only major problems being the usual ones of developing procedures that afford good yields and of determining the exact position of the azoxy oxygen in unsymmetrically substituted products. 

The reduction of aromatic nitro compounds is believed to proceed to an intermediate mixture of nitroso compounds and substituted hydroxylamines which are not isolated but condense to form an azoxy compound which, in turn, is reduced to an azo compound. Contributing evidence to substantiate this mechanism is that the reduction of a mixture of two aromatic nitro compounds leads to a mixture of azo compounds consistent with that predicted if each of the nitro compounds were reduced to a nitroso compound and a hydroxylamine and these, in turn, reacted with each other in all possible combinations. This observation also implies that the bimolecular reduction of nitro compounds is practical only from the preparative standpoint for the production of symmetrically substituted azo compounds. Spectrophotometric studies of the reaction kinetics of the reduction of variously substituted nitro compounds may, however, uncover reasonable procedures for the synthesis of unsymmetrical azo compounds. 

The filtered reaction mixtures from the zinc-ammonium chloride reductions of aromatic nitro compounds have been added to aqueous solutions of ferric chloride. Within 10-15 min the oxidation to nitroso compounds was completed. In the oxidation of nine different hydroxylamines, yields ranged from 30 to 60% [86a, b]. 

Fluorinated aromatic hydroxylamines can be selectively oxidized to the corresponding nitroso-benzenes 8 using iron(III) choridc as the oxidizing agent.248 The hydroxylamine is prepared in situ from the nitro compound.248... 

According to Angeli and Angelico [52], and later Meisenheimer [38], aromatic nitro compounds react with hydroxylamine to form aminonitro derivatives. Thus, Angeli obtained l-nitro-4-naphthylamine from 1-nitronaphthalene ... 

N-oxidation can occur in a number of ways to give either hydroxylamines from primary and secondary amines [Eqs. (11) and (12)], hydroxamic acids from amides, or N-oxides from tertiary amines [Eq. (13)]. The enzyme systems involved are either cytochrome P450 or a flavoprotein oxygenase. Hydroxylamines may be further oxidized to a nitro compound via a nitroso intermediate [Eq. (11)]. Oximes can be formed by rearrangement of the nitroso intermediate or N-hydroxylation of an imine, that could in turn be derived by dehydration of a hydroxylamine [Eq. (11)]. N-Oxides may be formed from both tertiary arylamines and alkylamines and from nitrogen in heterocyclic aromatic systems, such as a pyridine ring. 

The reaction sequence involved in the hydrogenation of aromatic nitro groups is shown in Scheme 19.1. This can be classed as a complex Type III selectivity. The end product from all paths is the aniline (10), but intermediates such as hydroxylamines (11), azo (12), azoxy (13), and hydrazo (14) compounds are present and can sometimes be isolated under the proper reaction conditions. In general, the dimeric products usually form in alkaline media, the partially reduced monomeric species form in neutral solutions, and anilines are produced in acid. The best yields of partially reduced products are obtained when the reaction is interrupted before it stops spontaneously and when it is carried out in the presence of various modifiers. ... 

The different steps of the biotransformations that produce a primary amine from an aromatic nitro compound involve a nitro radical-anion, a nitroso derivative, a nitroxyl radical, a hydroxylamine and then the primary amine (Figure 33.15). 

Amination of aromatic nitro compounds often occurs smoothly and directly also on condensation with hydroxylamine in alkaline solution, the amino group normally entering ortho or para to the nitro group. One nitro group activates naphthalene derivatives sufficiently, but in the benzene series two are necessary to induce this reaction. 2-Nitro-l-naphthylamine was thus obtained (80%) from 2-nitronaphthalene,400 and 4-nitro-l-naphthyl-amine (60%) from 1-nitronaphthylamine.401 The amino group also enters the nitrated ring of quinoline derivatives. 

Under suitable conditions it is possible to isolate the A-substituted hydroxylamines that are formed as intermediates in the reduction of nitro compounds. For this purpose it is essential in the reduction of aromatic nitro compounds to work with neutral or nearly neutral solutions suitable reducing agents are hydrogen and platinum oxide catalysts in glacial acetic acid,82,83 zinc dust in ammonium chloride solution,84 aluminum amalgam,85 and ammonium sulfide.86 Aliphatic nitro compounds may be reduced as their alkali salts (nitronates) by diborane in tetrahydrofuran, then giving A-alkylhydroxyl-amines 87 for instance, A-cyclohexylhydroxylamine is thus obtained from nitrocyclohexane in 53% yield. However, aliphatic nitro compounds are converted into A-alkylhydroxylamines more simply by catalytic hydrogenation in the presence of palladium-barium sulfate unlike aromatic nitro compounds, aliphatic nitro compounds require an acid medium for reduction to hydroxylamines an oxalic acid medium has proved the most suitable. 

The metabolism of nitrobenzenes to quinone-imines arises from a six-electron reduction of the nitro group to the corresponding aniline metabolite via the intermediate nitroso and hydroxylamine analogs. Aromatic ring hydroxylation by CYP ortho or para to the aniline nitrogen then generates the aminophenol derivative. The conversion of a nitrobenzene derivative to a quinone-imine is illustrated with the catechol-O-methyltransferase inhibitor tolcapone, an... 

The enzymatic reduction of the nitro group involves the stepwise addition of six reducing equivalents potentially derived from reduced pyridine nucleotides (Fig. 8). The first reaction yields a nitroso derivative which is subsequently reduced to a hydroxylamine the hydroxylamino compound is then reduced to the amine. In most systems studied to date (Cemiglia and Somerville, this volume) a single nitroreductase enzyme is responsible for all three reactions and there is little or no accumulation of the intermediates. However, reduction of nitro compounds does not seem to be the physiological function of the enzymes that have been reported to carry out these reactions. Diaphorases (23), ferredoxin-NADPH reductase (33), and a variety of other enzymes from procaryotes and eucaryotes have been shown to catalyze the fortuitous reduction of aromatic nitro groups. 

In some cases in which the Caro s acid oxidation of amines was not satisfactory, the corresponding hydroxylamines have been oxidized with acidified dichromate solutions [42], Both aliphatic and aromatic nitroso compounds have been prepared by this method [17, 42, 82, 90]. Frequently the reaction mixture from the reduction of a nitro compound is treated directly with the oxidizing medium without the isolation of the intermediate hydroxylamine. The method has been called the nitro reduction oxidation technique, [82] a terminology we cannot condone. 

Selective reduction to hydroxylamine can be achieved in a variety of ways the most widely applicable systems utilize zinc and ammonium chloride in an aqueous or alcoholic medium. The overreduction to amines can be prevented by using a two-phase solvent system. Hydroxylamines have also been obtained from nitro compounds using molecular hydrogen and iridium catalysts. A rapid metal-catalyzed transfer reduction of aromatic nitroarenes to N-substituted hydroxylamines has also been developed the method employs palladium and rhodium on charcoal as catalyst and a variety of hydrogen donors such as cyclohexene, hydrazine, formic acid and phosphinic acid. The reduction of nitroarenes to arylhydroxyl-amines can also be achieved using hydrazine in the presence of Raney nickel or iron(III) oxide. ... 

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