Aniline, formation preparation

The palladium-catalyzed formation of diarylamines has been used in several contexts to form molecules with biological relevance. The ability to prepare haloarenes selectively by an ortho-metallation halogenation sequence allows for the selective delivery of an amino group to a substituted aromatic structure. Snieckus has used directed metallation to form aryl halides that were subsequently reacted with anilines to prepare diarylamines (Eq. 34)) [156]. Frost and Mendon a have reported an iterative strategy to prepare (by palladium-catalyzed chemistry) amides and sulfonamides that may act as peptidomimetics. Diarylamine units are constructed using the DPPF-ligated palladium catalysts, and the products are then acylated or sulfo-nated with 4-bromo benzoyl or arylsulfonyl chlorides [157]. 

The tremendous utility of catalytic C-0 and C-N bond formation processes, pioneered by Buchwald and Hartwig, is largely based on the efficiency of palladium-catalyzed systems. However, efficient nickel-catalyzed processes have also been reported for this important class of transformations. The catalytic coupling of aryl chlorides with primary or secondary amines is a particular niche where utility of the nickel-catalyzed process was found. A representative sampling of aniline derivatives prepared by the activity of Ni(cod)2/dppf as the pre-catalyst is depicted below (Figure 3-3). 

The most noteworthy reaction of azo-compounds is their behaviour on reduction. Prolonged reduction first saturates the azo group, giving the hydrazo derivative (C NH-NH C), and then breaks the NH NH linkage, with the formation of two primary amine molecules. If method (1) has been employed to prepare the azo-compound, these two primary amines will therefore be respectively (a) the original amine from which the diazonium salt was prepared, and (6) the amino derivative of the amine or phenol with which the diazonium salt was coupled. For example, amino-azobenzene on complete reduction gives one equivalent of aniline, and one of p-phenylene diamine, NHaCeH NH benzene-azo-2-naphthoI similarly gives one equivalent of aniline and one of... 

Note on the laboratory preparation of monoethylaniline. Although the laboratory preparation of monomethyl- or monoethyl-aniline is hardly worth whUe, the following experimental details may be useful to those who wish to prepare pure monoethylaniline directly from amline. In a flask, fitted with a double surface reflux condenser, place 50 g. (49 ml.) of aniline and 65 g. of ethyl bromide, and boU gently for 2 hours or until the mixture has almost entirely sohdified. Dissolve it in water and boil off the small quantity of unreacted ethyl bromide. Render the mixture alkaUne with concentrated sodium hydroxide solution, extract the precipitated bases with three 50 ml. portions of ether, and distil off the ether. The residual oil contains anihne, mono- and di-ethylaniline. Dissolve it in excess of dilute hydrochloric acid (say, 100 ml. of concentrated acid and 400 ml. of water), cool in ice, and add with stirring a solution of 37 g. of sodium nitrite in 100 ml. of water do not allow the temperature to rise above 10°. Tnis leads to the formation of a solution of phenyl diazonium chloride, of N-nitrosoethylaniline and of p-nitrosodiethylaniline. The nitrosoethylaniline separates as a dark coloured oil. Extract the oil with ether, distil off the ether, and reduce the nitrosoamine with tin and hydrochloric acid (see above). The yield of ethylaniline is 20 g. 

To minimize the formation of fuhninating silver, these complexes should not be prepared from strongly basic suspensions of silver oxide. Highly explosive fuhninating silver, beheved to consist of either silver nitride or silver imide, may detonate spontaneously when silver oxide is heated with ammonia or when alkaline solutions of a silver—amine complex are stored. Addition of appropriate amounts of HCl to a solution of fuhninating silver renders it harmless. Stable silver complexes are also formed from many ahphatic and aromatic amines, eg, ethylamine, aniline, and pyridine. 

Coe et al. reported an efficient modification for the preparation of /-substituted indole analogs for biology screening in good yield. The intermediate P-nitrostyrene 44, prepared from the condensation of 43 with DMFDMA, underwent methanolysis and reduction to provide the aniline acetal intermediate 45. Alkylation of amine 45 was carried out employing standard conditions of reductive alkylation to provide A-alkyl analogs represented by 46. The indole 47 was generated by formation of the oxonium ion (from 46) under acidic conditions, followed by cyclization, accompanied by loss of methanol. 

The Henegar modification of the Friedlander reaction has been recently reported. The A-Boc protected derivative of o-aminobenzaldehyde (25, in this case prepared via directed ortho metallation of 24) is a stable, crystalline compound that can be stored for extended periods (in contrast with 4, which typically is freshly prepared). Treatment of 25 with ketone 26 in acetic acid results in deprotection of the aniline in situ and subsequent formation of 27, an intermediate in the synthesis of mappicine. 

The preparation of an aryl fluoride—e.g. fluorobenzene 3—starting from an aryl amine—e.g. aniline 1—via an intermediate arenediazonium tetrafluoroborate 2, is called the Schiemann reaction (also called the Balz-Schiemann reaction) The diazotization of aniline 1 in the presence of tetrafluoroborate leads to formation of a benzenediazonium tetrafluoroborate 2 that can be converted into fluorobenzene 3 by thermolysis. 

Preparation of the first of these antiinflammatory prodrugs starts with the displacement of halogen on bromophthal ide 2 by the anion of the nicotinic acid derivative 1. Reaction of the intermediate 3 with aniline 4 leads to formation of talniflumate (5). ... 

Closely related to the use of rhodium catalysts for the hydrogenation of phenols is their use in the reduction of anilines. The procedure gives details for the preparation of the catalyst and its use to carry out the low-pressure reduction of /j-aminobenzoic acid. Then, as in the preceding experiment, advantage is taken of the formation of a cyclic product to carry out the separation of a mixture of cis and trans cyclohexyl isomers. 

A novel approach to 3-substituted indolines and indoles via the anionic cyclization of 2-bromo-lV,lV-diallyanilines has been developed simultaneously by Bailey <96JOC2596> and Liebeskind <96JOC2594>. Thus, treatment of 2-bromo-lV,lV-diallylanilines 78 with 2 equivalents of BuLi at -78 °C leads to the formation of the intermediate 79 which may be trapped with an electrophile to afford 3-substituted indolines 80. Aside from ease of preparation, an additional benefit of the intramolecular carbolithiation of <7-lithio-W,Al-diallyl-anilines is the production of Al-allyl-protected indolines, which are easily deprotected using... 

Stepwise addition of the aniline moieties in analogy to Scheme 7 (Route A) allows the preparation of asymmetrically substituted derivatives.55,56 The use of pyridine-3,4-dicarboxylic acid anhydride similarly results in the formation of mixtures of 5- and 6-azaphthalides.57 Quinoline-2,3-dicarbo-xylic anhydride has also been converted into the corresponding azaphthal-ides in a similar manner.58 Pyrazine-2,3-dicarboxylic acid anhydride yields... 

The synthesis of this aminoquinoline starts with one of the standard sequences for preparation of 4-hydroxyquinolines, i.e., with the formation of the Shiff base (5) from the appropriately substituted aniline and diethyl oxaloacetate. Thermal cycliza-tion gives the quinolone (6) this then spontaneously tautomerizes to the enol form (7). Saponification followed by decarboxylation gives the desired quinolol... 

Nowhere, perhaps, is this phenomenon better illustrated than in the phenothiazine class. The earlier volume devoted a full chapter to the discussion of this important structural class, which was represented by both major tranquilizers and antihistamines. The lone phenothiazine below, flutiazin (130), in fact fails to show the activities characteristic of its class. Instead, the ring system is used as the aromatic nucleus for a nonsteroidal antiinflammatory agent. Preparation of 130 starts with formylation of the rather complex aniline 123. Reaction with alcoholic sodium hydroxide results in net overall transformation to the phenothiazine by the Smiles rearrangement. The sequence begins with formation of the anion on the amide nitrogen addition to the carbon bearing sulfur affords the corresponding transient spiro intermediate 126. Rearomatization... 

Interesting octahydroacridines 2-860 have been prepared by Beifuss and coworkers by combining the condensation step with a rare intramolecular polar [4jt++2 jrj-cydization of a-aryliminium ions 2-859, obtained from anilines 2-857 by reaction with the oo-unsaturated aldehyde 2-858 (Scheme 2.191) [440]. The overall domino process seems to be stereoselective, since the formation of the two di-astereomers 2-860 can be traced to the use of the substrate 2-858 as a diastereom-eric mixture. 

The technical preparation of crystal violet and of its methyl-free parent substance, parafuchsine, almost the oldest of the triphenylmethane dyes, is not so easily explained. As is well known, in this process aniline and p-toluidine are united by oxidation in an acid melt. (In the preparation of fuchsine itself, which contains a methyl group attached to one of the benzene rings, o-toluidine is an additional ingredient.) Although all the phases of this important synthesis have not yet been experimentally established, we may nevertheless explain it on the basis of a dehydrogenation similar to that involved in the formation of malachite green. Moreover, the union of several molecules of base proceeds exactly according to the principle on which indamines are formed (p. 321) (Bucherer). 

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