Pyrrole, 2-bromo-, synthesis

Alder/retrograde Diels-Alder reaction sequence of a diaryl alkyne with a 3,6-dicarbomethoxy tetrazine. The resulting diazine (14) is then reduced, cleaved and cyclized with Zn/acetic acid to the 2,3,4,5-tetrasubstituted pyrrole (15), which is then N-alkylated with a-bromo-4-methoxyacetophenone to give a pentasubstituted pyrrole (16). The synthesis of lukianol A is completed by ester hydrolysis, decarboxylation, ring closure and deprotection. 

Among early reported Pd-catalyzed reactions, the Mori-Ban indole synthesis has proven to be very useful for pyrrole annulation. In 1977, based on their success of nickel-catalyzed indole synthesis from 2-chloro-fV-allylaniline, the group led by Mori and Ban disclosed Pd-catalyzed intramolecular reactions of aryl halides with pendant olefins [122]. Compound 102, easily prepared from 2-bromo-lV-acetylaniline and methyl bromocrotonate, was adopted as the cyclization precursor. Treatment of 102 with Pd(OAc)2 (2 mol%), Ph3P (4 mol%) and NaHCQ3... 

The first synthesis of the parent compound of the benzo[4,5]thieno[2,3-f]pyrrole ring system 387 <2003T1477> and its derivatives was accomplished using the same synthetic sequence (Scheme 42). Starting with 2-methyl-benzo[ ]thiophene-3-carbaldehyde 388, an intermediate 389 was obtained. Treatment of bromo compound 389 with sodium azide in ethanol led to the stable triazoline 390. 1,3-Dipolar cycloreversion of 390 was induced by a catalytic amount of />-TsOH to give the parent 2//-benzo[4,5]thieno[2,3-c]pyrrole 387. Alternatively, direct treatment of bromo compound 389 with excess ammonia furnished 387 in one step. Compound 387 was treated with di-/-butyl dicarbonate and 4-dimethylaminopyridine (DMAP) to give iV-BOC derivative 391. Reaction of 389 with... 

Pyridinium bromide perbromide efficiently brominates pyrroles already substituted by electron-withdrawing substituents and also gives a high yield of 3-bromoindole in its reaction with indole. In conjunction with sulfuryl chloride, it has been used in the synthesis of 3-bromo-2-chloro-, 2-bromo-3-chloro- and 2,3-dibromo-indole (81SC253). 3-Methylindole reacts with A-bromosuccinimide in acetic acid to give the 2-bromo derivative which reacts further with an excess of A-bromosuccinimide to yield 2,6-dibromo-3-methylindole (B-70MI30500, 72HC(25-2)127) whilst in aqueous or alcoholic media, 3-bromo-3-methylox-indole is produced (cf. Scheme 15). All of these reactions proceed via the 3-bromo-3A-indolium cation, but the course of the reaction depends not only upon the orientation or... 

For the synthesis of isoindoles (benzo[c]pyrroles) by type la cyclization the required intermediate is an o -acylbenzylamine. The only viable route to these substances which has been developed starts with a -bromo-o -toluic acid which is converted first to a phthalimide and then to the acid chloride. The acid chloride is then elaborated to the requisite ketone by Friedel-Crafts acylation. Condensation to the isoindole occurs on liberation of the primary amino group using hydrazine (equation 18) (64JA4152). 

Of lesser relevance to this discussion are halogenation methods involving the modification of the carbon skeleton (synthesis and degradation). The Hunsdiecker reaction, as applied to certain heterocyclic acids, has had limited application for the synthesis of halogen derivatives. The preparation of 3-bromo-4,6-dimethyl-2-pyridone from the silver salt of the respective 3-carboxylic acid by treatment with bromine in carbon tetrachloride is a rare example of success.13 The interaction of carbenes with heterocycles also has been employed infrequently, but recent advances in carbene generation may reactivate this approach.14 The Ciamician-Dennstedt ring expansion of pyrrole to / -halopyridines is a case in point18 [Eq. (4)] ... 

Because of the deactivated ir-deficient nature of the ring, nucleophilic attack can readily occur on tetrazoles. Nucleophilic replacement of halogens at the C-5 position has been widely used for the synthesis of disubstituted tetrazoles, e.g. (56). Kinetic studies of the reaction between 5-bromo-l-methyltetrazole and the 2-methyl isomer with piperidine have shown the 1-methyl compound to be considerably more reactive. Comparison of these kinetics with similar reactions for a series of azoles has suggested that two to three deactivating doubly bound nitrogens (—N=) are required to overcome the electron release from one pyrrole-type nitrogen atom in these systems <67JCS(B)64l>. 

In C-alkylation of other compounds containing nitrogen atoms. Chi s group [35] has done a lot of work. They have described a novel approach for pyrrole C-alkylation in which [BMIM][SbFg] and CH CN as a mixture was onployed for the synthesis of 2-(3-phenylpropyl)pyrrole from pyrrole and 7-bromo-3-phenylpropane with the results that 81% yield was achieved at 115 C for 44 h with 5% yield of dialkylated compound. It is obvious that the ionic Uqnid demonstrated an important driving force in the regioselective alkylation of pyrrole. Moreover, it is worthy to be noted that in this reaction, no Lewis add/base catalysts were needed. 

In a model synthesis <81CC524>, a nitro-Michael addition of the readily available nitroalkyl pyrrole 36 to mesityl oxide was used to introduce a geminally dimethylated structural element into an AD component rac-39 for the desired chlorin. Reduction of the nitro function in rac-37 leads to the desired AD dimer rac-38 which is combined in the presence hydrobromic acid with the well known a-bromo-a -bromomethyl dipyrromethene 40 after acid induced ester clevage and decarboxylation to yield the tetrapyrrolic biline rac-41. In the final step the linear tetrapyrrole rac-41 undergoes oxidation and cyclization in the presence of copper(II) acetate to give the copper chlorin. The cyclization occurs via the enamine tautomer of rac-41 by nucleophilic attack of the enamine structure on the bromo imine part of the linear tetrapyrrole. 

Interest in alkaloids of the nicotine group appears to be on the increase. A review has appeared covering tobacco-specific nitrosamines, which may be causative factors in tobacco-related cancers. The solution conformation, and proton, deuterium, carbon-13, and nitrogen-15 n.m.r. spectra of nicotine and its 2- and 4-isomers, have been studied. A new synthesis of nornicotine and nicotine has been described, and a quantitative carbon-13 n.m.r. spectral analysis of nicotine that is labelled at positions 1, 2, and 3 with carbon-13 been presented. The synthesis and mass spectrometry of several structurally related nicotinoids have been reported. Nicotine is dehydrogenated on irradiation in benzene solution in the presence of benzophenone to l -methyl-2 -(3-pyri-dyl)pyrrole. ° Nornicotine has been synthesized in four steps from 3-bromo-pyridine and N-3-butenyl-phthalimide, using a palladium-catalysed vinylic... 

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