Indoles 3-nitro

Indole, l-methyl-2-sulfonamido-tautomerism, 4, 200 Indole, l-methyl-3-sulfonamido-tautomerism, 4, 200 Indole, (methylthio)-synthesis, 4, 368 Indole, 3-(methylthio)-synthesis, 4, 338, 368 Indole, l-methyl-3-vinyl-oxidation, 4, 280 Indole, nitro-rearrangement, 4, 297 Indole, 3-nitro-nitration, 4, 211, 213 reduction, 4, 362 synthesis, 4, 210, 363 Indole, 5-nitro-synthesis, 4, 211, 363 Indole, nitroso-rearrangement, 4, 297 Indole, 1-nitroso-reduction, 4, 362 Indole, 3-nitroso-reduction, 4, 362 Indole, nitrovinyl-... 

A Michael adduct, reminiscent in structure of the first intermediate in the Gates synthesis of morphine, has been obtained as a catechol derivative en route to conversion to an indole. 3-Nitro-6-ethoxycarbonyl-1,2-naphthoquinone with ethyl acetoacetate in dioxan containing zinc chloride was refluxed for 5-10 minutes, allowed to stand for 20 minutes, the nitro compound reduced with zinc dust to the amino compound which cyclised after a final oxidation step to an indole,... 

Keywords Alkyl hydroperoxides Amination Ammonia Benzimidazole Benzisoxazole Carbanions Heterocycles Hydroxylation Indole Nitro compounds Nucleophiles Nucleophilic substitution Oxidation Phenazine Potassium permanganate Pyridine Quinoline Sulfones Vicarious... 

As regards reaetions other than nitration brought about by some of these systems, especially noteworthy are the addition processes undergone by eertain indole derivatives when treated with solutions of nitrie aeid in aeetie aeid. Produets inelude glycols, nitro-alcohols, and nitro-alcohol acetates. Such additions might well be encountered with some polynuclear aromatie eompounds, and with sueh eompounds the possibility of nitration by addition-elimination must always be borne in mind. 

A solution of trifluoroacetic acid in toluene was found to be advantageous for cydization of pyruvate hydrazoncs having nitro substituents[4]. p-Toluene-sulfonic acid or Amberlyst-15 in toluene has also been found to give excellent results in preparation of indole-2-carboxylale esters from pyruvate hydra-zoiies[5,6J. Acidic zeolite catalysts have been used with xylene as a solvent to convert phenylhydraziiies and ketones to indoles both in one-flask procedures and in a flow-through reactor[7]. 

X)ml), The reaction mixture was stirred for 24 h. Nearly all of the solvent was removed in vacuo and the residue dissolved in CH2CI2. The solution was washed with 5% NHj, 1N HCl and brine. The organic layer was dried (NajSOJ and the solvent evaporated in vacuo. The residue was purified by chromatography using CHClj-hexane to give the product (28.0 g, 86%) along with a little 3-[2-nitro-2-(indol-3-ylmethyl)ethyl]indole (2.8 g. 5%). 

Indole can be nitrated with benzoyl nitrate at low temperatures to give 3-nitroindole. More vigorous conditions can be used for the nitration of 2-methylindole because of its resistance to acid-catalyzed polymerization. In nitric acid alone it is converted into the 3-nitro derivative, but in a mixture of concentrated nitric and sulfuric acids 2-methyl-5-nitroindole (47) is formed. In sulfuric acid, 2-methylindole is completely protonated. Thus it is probable that it is the conjugate acid which is undergoing nitration. 3,3-Dialkyl-3H-indolium salts similarly nitrate at the 5-position. The para directing ability of the immonium group in a benzenoid context is illustrated by the para nitration of the conjugate acid of benzylideneaniline (48). 

Recently, the Bartoli indole synthesis was extended to solid supports. In contrast to the earlier reports in the liquid phase, o,o-unsubstituted nitro analogs (see 25) prove to be useful substrates. In addition, fluoro/chloro substituted nitro derivatives are well tolerated, which typically undergo nucleophilic substitution under Bartoli conditions in the liquid phase. 

Under basic conditions, the o-nitrotoluene (5) undergoes condensation with ethyl oxalate (2) to provide the a-ketoester 6. After hydrolysis of the ester functional group, the nitro moiety in 7 is then reduced to an amino function, which reacts with the carbonyl group to provide the cyclized intermediate 13. Aromatization of 13 by loss of water gives the indole-2-carboxylic acid (9). 

Because the nucleophiles can be introduced at the orr/io-posidon of the nitro group, various heterocycles can be prepared via VNS and related reacdons. Indoles and related compounds are prepared via the VNS reacdon and subsequent cyclizadon. The VNS reaction of nitroarenes followed by cyclizadon v/ithEt- N-Me SiCl gives 1-hydroxyindoles fEq. 9.53. Cyclizadon is Mso catrilyzed on treatment v/ith bases, in which nitroso intermediates are postidated. 

As discussed in Chapter 6, nitro compounds are converted into amines, oximes, or carbonyl compounds. They serve as usefid starting materials for the preparation of various heterocyclic compounds. Especially, five-membered nitrogen heterocycles, such as pyrroles, indoles, ind pyrrolidines, are frequently prepared from nitro compounds. Syntheses of heterocyclic compounds using nitro compounds are described partially in Chapters 4, 6 and 9. This chapter focuses on synthesis of hetero-aromadcs fmainly pyrroles ind indolesi ind saturated nitrogen heterocycles such as pyrrolidines ind their derivadves. 

The Siindberg indole synthesis using aromadc azides as precursors of nitrenes has been used in synthesis of various indoles. Somekmds of aryl azides are readily prepared by S Ar reacdon of aromadc nitro compounds v/ilh an azide ion. For example, 2,4,6-trinitrotoliiene (TNT can be converted into 2-aryl-4,6-dinitroindole, as shovmin Eq. 10.60. ... 

Soderberg and coworkers have developed a palladium-phosphine-catalyzed reductive iV-het-eroannuladon of 2-nitrostyrenes forming indoles in good yields For example, reaction of 6-bromo-2-nitrostyrene with carbon monoxide in the presence of a catalytic amount of palladium diacetate (6 mol% and triphenylphosphine 124 mol% in acetonitrile at 30 gives 4-bromoindole in 86% yield fEq 10 62 Several functional groups, such as esters, ethers, bromides, tnflates, and additional nitro groups, have been shown to be compatible with the reaction conditions... 

An excellent method for producing methyl indole-4-carboxylate from commercially available 3-nitro-2-methylbenzoic acid involves reduction of an intermediate nitroenamine (57). 

It has been said that the above procedure cannot be applied to the synthesis of the corresponding nitro derivative, 8-nitro[l,2,4]triazino[5,6-b]indole-3-thione. Thus, heating 5-nitroisatin-3-thiosemicarbazone in aqueous potassium carbonate gave after acidification a mixture of oxotria-zinethione 137 and 5-nitroindazole 3-carboxylic acid (90ZOR1327). 

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