Five-membered heterocyclic amines

Other common five-membered heterocyclic amines include imidazole and thiazole. Imidazole, a constituent of the amino acid histidine, has two nitrogens, only one of which is basic. Thiazole, the five-membered ring system on which the structure of thiamin (vitamin Bt) is based, also contains a basic nitrogen that is alkylated in thiamin to form a quaternary ammonium ion. 

Five-membered heterocyclic amines have been attracting attention for a long time. Their antioxidant effect was confirmed in model experiments. Derivatives of indole and carbazole are HS for PVC and copolymers of vinyl chloride [92], Some indoles are medical or biological AO protecting against chemical carcinogenesis or chemically induced hepatoxicity [93]. 6-Hydroxycarbazole suppresses oxidation of methyl linoleate, its sacrificial transformation yields a QI. 2,2-Disubstituted l,2-dihydro-3-oxo(or phenylimino)-3//-indoles (15a, b, R = Me, Et) have a potential importance as HS for PO [36]. 

A completely different, important type of synthesis, which was developed more recently, takes advantage of the electrophilicity of nitrogen-containing 1,3-dipolar compounds rather than the nucleophilicity of amines or enamines. Such compounds add to multiple bonds, e.g. C—C, C C, C—O, in a [2 + 3 -cycioaddition to form five-membered heterocycles. 

Some examples of ring opening reactions with carbanions leading to five-membered heterocyclic ring formation are shown in Scheme 85. Pyrrole syntheses from functionally substituted oxiranes and amines are often described and typical examples are shown in Scheme 86. 

Sheremetev and co-workers employed diazo compounds of type 60, prepared from the corresponding amines in moderate yields as alternative excellent precursors for the preparation of side-chain-functionalized derivatives (Scheme 29). Several furazans bearing reactive groups or cyclopropyl or five-membered heterocyclic substituents have been prepared by standard procedures (99MI6). 

Certain amine oxides, especially those derived from six-membered heterocyclic amines e.g. N-methylpiperidine oxide, that cannot go through a planar, five-membered transition state, do not undergo the Cope elimination reaction. 

In addition to nitrones, azomethine ylides are also valuable 1,3-dipoles for five-membered heterocycles [415], which have found useful applications in the synthesis of for example, alkaloids [416]. Again, the groups of both Grigg [417] and Risch [418] have contributed to this field. As reported by the latter group, the treatment of secondary amines 2-824 with benzaldehyde and an appropriate dipolarophile leads to the formation of either substituted pyrrolidines 2-823, 2-825 and 2-826 or oxa-zolidines 2-828 with the 1,3-dipole 2-827 as intermediate (Scheme 2.184). However, the yields and the diastereoselectivities are not always satisfactory. 

In addition, complexes of P(/-Bu)3 have been shown to catalyze the formation of diaryl heteroarylamines from bromothiophenes.224 Aminations of five-membered heterocyclic halides such as furans and thiophenes are limited because their electron-rich character makes oxidative addition of the heteroaryl halide and reductive elimination of amine slower than it is for simple aryl halides. Reactions of diarylamines with 3-bromothiophenes occurred in higher yields than did reactions of 2-bromothiophene, but reactions of substituted bromothiophenes occurred in more variable yields. The yields for reactions of these substrates in the presence of catalysts bearing P(/-Bu)3 as ligand were much higher than those in the presence of catalysts ligated by arylphosphines. 

No nucleophilic substitution in five membered heterocycles with hydroxylamines has been reported so far, although any nucleophilic substitution reaction known for amines should be suitable for hydroxylamines as well. 

Paal-Knorr synthesis It is a useful and straightforward method for the synthesis of five-membered heterocyclic compounds, e.g. pyrrole, furan and thiophene. However, necessary precursors, e.g. dicarbonyl compounds, are not readily available. Ammonia, primary amines, hydroxylamines or hydrazines are used as the nitrogen component for the synthesis of pyrrole. 

A significant part of the examples of transition metal catalyzed formation of five membered heterocycles utilizes a carbon-heteroatom bond forming reaction as the concluding step. The palladium or copper promoted addition of amines or alcohols onto unsaturated bonds (acetylene, olefin, allene or allyl moieties) is a prime example. This chapter summarises all those catalytic transformations, where the five membered ring is formed in the intramolecular connection of a carbon atom and a heteroatom, except for annulation reactions, involving the formation of a carbon-heteroatom bond, which are discussed in Chapter 3.4. 

Carbon-heteroatom bond forming reactions are also efficient in introducing amines onto other five membered heterocycles. 2-, and 3-bromothiophene were both coupled with diphenylamine using the highly active palladium-PlBih catalyst system. The reactions furnished the desired products in both cases, although the yield varied significantly with the substitution pattern (6.75.),106... 

Compound 86 highlights a more unusual 1,3,2,4-dithiadiazole <1975AGE498, 2004CPL516, 2005CPL440>. This five-membered heterocyclic ketone, which can be alternatively formulated as a meso-ionic l,3,2,4-dithiadiazolium-5-olate, is synthesized from tetrasulfur tetranitride and tris(trimethylstannyl)amine to form 5,5-dimethyl-l,3A4,2,4,5-dithiadiazastannole 87, which upon treatment with COF2 is converted into compound 86 in 49% yield, with dimethyltin fluoride as the by-product. 

This is another reaction typical of aromatic amines and phenols, which is successful with many five-membered heterocycles. 

Aminations of five-membered heterocyclic halides, such as furans and thiophenes, are limited. These substrates are particularly electron-rich. As a result, oxidative addition of the heteroaryl halide and reductive elimination of the amine are slower than for simple aryl halides (see Sections 4.7.1 and 4.7.3). In addition, the amine products can be air-sensitive and require special conditions for their isolation. Nevertheless, Watanabe has reported examples of successful couplings between diarylamines and bromothiophenes [126]. Triaryl-amines are important for materials applications because of their redox properties, and these particular triarylamines should be especially susceptible to electrochemical oxidation. Chart 1 shows the products formed from the amination of bromothiophenes and the associated yields. As can be seen, 3-bromothiophene reacted in higher yields than 2-bromothiophene, but the yields were more variable with substituted bromothiophenes. In some cases, acceptable yields for double additions to dibromothiophenes were achieved. These reactions all employed a third-generation catalyst (vide infra), containing a combination of Pd(OAc)2 and P(tBu)3. The yields for reactions of these substrates were much higher in the presence of this catalyst than they were in the presence of arylphosphine ligands. 

In a detailed investigation of the mechanism and scope of palladium catalyzed amination of five-membered heterocycles, the 1-methyl-3-bromoindole 145 was aminated with secondary amines to the 3-aminoindoles 146. Similar results were obtained for l-methyl-2-bromoindole <03JOC2861>. Rhodium-catalyzed cyclopropanation reactions involving 1-methyl-3-diazooxindole and exocyclic alkenes provided novel dispirocyclic cyclopropanes <03SL1599>. New applications of palladium-mediated cross-coupling reactions have been utilized to prepare a variety of functionalized indoles. Suzuki-Miyaura coupling reactions of indole-3-boronates <03H(59)473> and indole-5-boronates <03H(60)865> were utilized to prepare inhibitors of lipid peroxidation and melatonin analogues, respectively. 

Like other aromatic compounds, these five-membered heterocycles undergJ nitration, halogenation, sulfonation, and Friedel-Crafts acylation. They are mucji more reactive than benzene, and resemble the most reactive benzene derivatives (amines and phenols) in undergoing such reactions as the Reimer-Tiemann reaction, nitrosation, and coupling with diazonium salts. 

In the example shown below, the regiochemistry of attack of the nucleophilic amine at the six-member ring favors, for steric reasons, formation of a five-member heterocyclic ring. ... 

We can now look at specific examples, and see how the principles above can lead to the aromatic heterocycles. In the first of the two broad categories, where only C-heteroatom bonds need to be formed, and for the synthesis of five-membered heterocycles, precmsors with two carbonyl groups related 1,4 are required, thus 1,4-diketones react with ammonia or primary amines to give 2,5-disubstituted pyrroles two successive heteroatom-to-carbonyl carbon additions and loss of two molecules of water produce the aromatic ring, though the exact order of these several steps is never certain. 

The ring synthesis of five-membered heterocycles has been extensively investigated, and many and subtle methods have been devised. Each of these three heterocyclic systems can be prepared from 1,4-dicarbonyl-compounds, for furans by acid-catalysed cyclising dehydration, and for pyrroles and thiophenes by interaction with ammonia or a primary amine, or a source of sulfur, respectively. 

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