Nitro reaction with sodium amide

There are three groups of substrates for which SNH reactions are especially characteristic (i) neutral azines and azoles (ii) azinium and azolium salts and (iii) nitro-arenes. Their electron-deficiency and, thus, their ability to react with nucleophiles strongly differ from each other. Azinium salts are the more electrophilic and are able to add even neutral nucleophiles very easily. Triazines,. v-tetrazines and polynitro-arenes also possess high electrophilicity. At the same time substrates such as pyridine (82JHC1285, 72JA682) and cinnoline (03CHE87), at a low temperature (e.g. in liquid ammonia as a solvent), do not react even with sodium amide. It should also be... 

Nucleophilic substitution of unactivated benzene derivatives occurs by a mechanism different from the addition-elimination we saw with the nitro-substituted halobenzenes. A clue to the mechanism is provided by the reaction of p-bromotol ucnc with sodium amide. The products are a 50 50 mixture of m- andp-toluidine. 

Nucleophilic Substitution, Metallation, and Halogen-Metal Exchange.—Direct nucleophilic displacement of the 7-chloro-group of 7-chloro-3-methyl-benzo[b]thiophen has been achieved. 3-Bromobenzo[b]thiophen was reduced to the 3-deuterio-derivative by the reaction with sodium borodeuteride and palladium chloride. Meisenheimer complexes were formed in the reaction of methoxide ion with 2-methoxy-3-nitro- and 3-methoxy-2-nitrobenzo[b]thiophen. Rate and equilibrium data were determined in methanol at 25 C. On treatment of 2-bromobenzo[b]thiophen with potassium amide in liquid ammonia, bromine migration to the adjacent carbon atom was observed. Considerable evidence for the occurrence of an intermolecular transbromination was obtained. The reaction of 3-bromo-benzo[b]thiophen with piperidine has been reinvestigated and found to give primarily the normal, but also some of the cine-substitution product, which is the only product obtained in the reaction of 2-bromobenzo[b]thiophen. Possible mechanisms for some of these reacticms are suggested. 

The resistance of the furoxan ring to chemical attack allows derivatives to be prepared via the reactions of the substituents (Section 4.22.3.4). Carboxylic acids are available by permanganate oxidation of methyl derivatives or by hydrolysis of the corresponding esters reaction with ammonia affords carboxamides. Acylfuroxans provide a source of hydroxyalkyl compounds by reduction, and oximes, for example, via nucleophilic addition. Acylation and oxidation of aminofuroxans allows the amide and nitro derivatives to be prepared. Nucleophilic displacements of nitro substituents can take place, but can be somewhat hazardous on account of the explosive nature of these compounds. Alkoxy derivatives are formed with sodium alkoxide, while reaction with thiolate anions yields sulfides, from which sulfones can be synthesized by peracid oxidation. Nitrofuroxans have also been reduced to... 

The popularity of the Nef reaction is due in part to the ready availability of nitro compounds. Primary and secondary halides react with sodium nitrite in dimeAyl sulfoxide (DMSO) or dimethylform-amide (DMF) to give useful yields of nitro compounds. Primary amines can be oxidized to nitro compounds with potassium permanganate, m-chloroperbenzoic acitP or ozone. Chlorination of oximes with hypochlorous acid and reduction with magnesium, zinc or hydrogen/lpalladium gives secondary nitro compounds. Stabilized carbanions can be nitrated by treauitent with a nitrate ester, and enol acetates are nitrated by acetyl nitrate to give nitro ketones. ... 

The synthetic importance of reaction (a) ° comes from the fact that it reduces to one step the pathway for conversion of an acid chloride into a nitrile (instead of the classical and rather inconvenient two-step route via an acid amide). Reaction is an example of a new transformation for aliphatic amines. Previously, there were no methods available for the direct transformation of an amino into a nitro group and the stepwise procedures were too cumbersome to be of practical use. Transformation of a nitro group into a carbonyl is a well-known reaction. Its modification, shown in reaction represents a welcome opportunity to obtain a protected carbonyl group as the immediate result of such a transformation. The viability of the sequential reactions (b) plus (c) enables the employment of a > CHNH2 moiety as a synthetic equivalent to a protected carbonyl group. A one-pot sequence of imine formation and its reduction with sodium triacetoxyborohydride represents a convenient... 

The amide can be easily prepared in high yield and high purity by the reaction of 2,3-dichloro-4-hydroxy-aniline and 1-methylcyclohexane-carboxylic acid chloride, e.g., in toluene with sodium hydroxide as a base (Scheme 17.24). The starting aniline can be made by a Bamberger rearrangement of the intermediate hydroxyl-amine obtained by partial reduction of the corresponding nitro aromatic [109]. 

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