Hydroxylamine aromatic, reaction with acids

Reductions with zinc are carried out in aqueous [160 as well as anhydrous solvents [163 and at different pHs of the medium. The choice of the reaction conditions is very important since entirely different results may be obtained under different conditions. While reduction of aromatic nitro groups in alkali hydroxides or aqueous ammonia gives hydrazo compounds, reduction in aqueous ammonium chloride gives hydroxylamines, and reduction in acidic medium amines (p. 73). Of organic solvents the most efficient seem to be dimethyl formamide [164 and acetic anhydride [755]. However, alcohols have... 

The syntheses of the methyl esters 116-118 from 115 and hydroxamic acids 119-121 were carried out via a typical alkylation of the hydroxy function of methyl 4-hydroxyben-zoate 116 followed by either reaction with hydroxylamine to provide bishydroxamic acids 119-121 containing an alkyl spacer between two aromatic rings. 

Acid hydrolysis of 32-7 leads to hydrolysis of both acetal groups in 32-7 as well as dehydration of the C5 hydroxyl group to give the penultimate intermediate 33-1 (Scheme 4.33). Reaction of the aldehyde on the aromatic ring with hydroxylamine affords the oxime 33-2 and thus asoprinsil. 

The fact that substitution of bromine in compounds of type (127) with hydroxylamine is accompanied by Walden inversion led Noce et al. (158) to the first synthesis of optically active N-hydroxyamino acids L- and D-N-hydroxyleucine (66). The same method was later used to synthesize the aromatic D-amino acids N-hydroxytyrosine (35) and N-hydroxyphenylalanine (34) (159). Reaction of hydroxylamine with a,a -dibromopimelic acid gave l-hydroxy-2,6-piperidine dicarbox-ylic acid (134) (158). Shin (160) studied the reaction of esters (128) and (129) with hydroxylamine in the presence of triethylamine and obtained the ethyl (77) and tert miy (130) esters of N-hydroxyamino acids as oils. 

Equation (40) is known as a transimination or a trans-SchifSza-tion reaction. It probably proceeds via a two-step mechanism involving a m-diamine intermediate, analogous to the carbinolamine intermediate observed in imine formation fix>m carbonyl compounds. The transimination reactions of Schiff bases derived from either aliphatic or aromatic amines with semicarbazide, hydroxylamine or methoxyamine, of oximes with semicarbazide and of semicarbazones with hydroxylamine all appear general base catalyzed in terms of one protonated and one free base reactant or general acid catalyzed in terms of two reactants of free base. These results may be accounted for by a nearly symmetrical mechanism for transimination (equations 41 and 42). Simple proton transfers are considered to be rapid and... 

Reactions with Electrophiles. The structure of isoquinoline 1 is the result of fusing benzene and pyridine together. Electrophilic aromatic substitution predominately occurs on the benzene ring under acidic conditions and usually addition takes place at the 5-position but can sometimes add to the 8-position. The rate of electrophilic aromatic substitution is slower for isoquinoline compared to naphthalene. The nitrogen in isoquinoline reacts similar to a pyridine nitrogen and will add a variety of electrophilic species such as 0-(2,4-dinitrophenyl)hydroxylamine 2 to aminate the nitrogen (eq 1). Friedel-Crafts acylation and alkylation do not work due to the formation of IV-acyl or IV-alkyl isoquinolinium salts. 

A positive reaction is obtained, however, with a series of nonphenolic compounds aromatic amines, ends or hydroxymethylene compounds, tautomeric jS-diketones, j -ketoesters, derivatives of malonic acid esters or of cyanoacetate with a negative substituent at the -- CH2 group, some isonitrites, hydroxylamine derivatives, oximes, hydroxamic acids, and certain derivatives of sulfur. 

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). 

Other Applications. Hydroxylamine-O-sulfonic acid [2950-43-8] h.2is many applications in the area of organic synthesis. The use of this material for organic transformations has been thoroughly reviewed (125,126). The preparation of the acid involves the reaction of hydroxjlamine [5470-11-1] with oleum in the presence of ammonium sulfate [7783-20-2] (127). The acid has found appHcation in the preparation of hydra2ines from amines, aUphatic amines from activated methylene compounds, aromatic amines from activated aromatic compounds, amides from esters, and oximes. It is also an important reagent in reductive deamination and specialty nitrile production. 

In a similar reaction, aromatic acyl halides are converted to amines in one laboratory step by treatment with hydroxylamine-O-sulfonic acid. " ... 

The photoreduction of aromatic nitro compounds to the amino compounds can be carried out on the surface of semiconductor particles such as titanium oxide1 with H-atom donors (equation 1). At a shorter duration of the photoinduced reduction of p-nitroacetophenone, the hydroxylamine intermediate can be obtained in about 30% yield. The reaction mechanism proposed is based on the photoexcitation of TiC>2 to generate an electron and a positive hole (equations 2 and 3). Aliphatic nitro compounds such as 12-nitrododecanoic acid can be reduced to 12-amino dodecanoic acid in 90% yield by this method. 

Hydroxylamines are usually more accessible than the corresponding nitroso compounds, so only few examples of this reaction have been described in the literature. Aromatic nitroso compounds have been reduced into hydroxylamines with ascorbic acid, gly-oxylic acid and by NADH. It can be safely assumed that any reagent capable of reducing nitro compounds should reduce nitroso compounds as well. 

Okamoto and co-workers noted that N-phenylhydroxylamine gave predominately diphenylamine on treatment with benzene in TFA but mostly 4-aminobiphenyl and 2-aminobiphenyl in the stronger acid trifluoromethane-sulfonic acid (TFSA). Similar results were obtained if benzene was replaced by toluene or anisole. The authors suggested that the reaction in TFA proceeded through O-protonated hydroxylamine either via a direct Sn2 displacement on N by the aromatic nucleophile or via attack of the aromatic compound on the N of a nitrenium ion. In TFSA they favored a mechanism in which the diprotonated hydroxylamine lost water to generate an iminium-benzenium dication (11, Scheme 5), a protonated nitrenium ion. " This... 

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. 

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