Heterocyclic compounds electron-rich heterocycles

Several enzymes that halogenate organic substrates are well known and these enzymes have been studied extensively, especially those involving alkenes, alkynes, active methylene compounds, electron-rich heterocycles (pyrroles, indoles), and phenols [1,103-105]. Both chloroperoxidase and bromoperoxidase are widespread in the... 

Concerning nomenclature, fulvalene 2 and its related systems 1 and 3-6 are the parent structures of this class of heterocyclic cross-conjugated compounds. Both ring systems are numbered as shown in formula 9 (1,4,5,8-tetraazafulva-lene) beginning at the heteroatoms. Alternatively, as in the case of heptafulva-lene 10 (3,3 -diazaheptafulvalene), the numbers 1-7 and l -7 can be used.Tlie use of the name of the parent heterocycle connected by an olefinic double bond is often favored for the nomenclature of electron-rich olefines, for example, bis[3-(2,6-diisopropylphenyl)-4,5-dimethylthiazol-2-ylidene] for compound 51a (97LAR365). Similarly, azafulvalenes of type 11 and 12 can be re-... 

The site of dihydroxylation in heterocycles depends on the nature of the heteroaromatic system (Scheme 9.31) usually, electron-rich heterocycles like thiophene are readily biooxidized but give conformationally labile products, vhich may undergo concomitant sulfoxidation [241]. Electron deficient systems are not accepted only pyridone derivatives give corresponding cis-diols [242]. Such a differentiated behavior is also observed for benzo-fused compounds biotransformation of benzo[b] thiophene gives dihydroxylation at the heterocyclic core as major product, while quinoline and other electron-poor systems are oxidized at the homoaromatic core, predominantly [243,244]. 

Almost accidentally, Bienayme and Bouzid discovered that heterocyclic amidines 9-76 as 2-amino-pyridines and 2-amino-pyrimidines can participate in an acid-catalyzed three-component reachon with aldehydes and isocyanides, providing 3-amino-imidazo[l,2-a]pyridines as well as the corresponding pyrimidines and related compounds 9-78 (Scheme 9.15) [55]. In this reachon, electron-rich or -poor (hetero)aromatic and even sterically hindered aliphatic aldehydes can be used with good results. A reasonable rahonale for the formation of 9-78 involves a non-con-certed [4+1] cycloaddition between the isocyanide and the intermediate iminium ion 9-77, followed by a [1,3] hydride shift. 

Cycloaddition reactions of electron-rich allenes with some heterodienes take place at the C1-C2 bond of the allene to yield heterocycles, a,Unsaturated carbonyl compounds 185 react with the internal C=C bond of ethoxyallene to afford dihydro-pyrans in moderate yields [150]. 

A wide variety of cyclic S-N compounds containing two or three coordinate sulfur is known (i ), The binary S-N rings vary in size from four (S2N2) to ten (SsNs" ") atoms and examples of anions (SsNs") and cations (S3N2 , S N3 , S N ) are known in addition to neutral molecules (2). The excess of electrons in these planar, electron-rich heterocycles is often accommodated in low lying tt orbitals but, in some cases (e.g. S N, S Ns"), the number of tt electrons is reduced by formation of transannular S-S bonds to give cages ( , ). 

In many ways, the electron-rich five-membered aromatic heterocycles behave very much like carbocyclic aromatic compounds when it comes to lithiation. Lithiation a to O or S of furan and thiophene is straightforward (Scheme 130) . The usual selection of orf/io-directing groups allows lithiation at other positions and some examples... 

The term charge tranter refers to a succession of interactions between two molecules, ranging from very weak donor-acceptor dipolar interactions to interactions that result in the formation of an ion pair, depending on the extent of electron delocalization. Charge transfer (CT) complexes are formed between electron-rich donor molecules and electron-deficient acceptors. Typically, donor molecules are p-electron-rich heterocycles (e.g., furan, pyrrole, thiophene), aromatics with electron-donating substiments, or compounds... 

Alkylation of tt-Electron-rich Heterocyclic Compounds with Electrophilic Olefins G. V. 

The acid-catalyzed dimerization of pyrroles and indoles also involves electrophilic attack by the 2H- or 3//-protonated species upon the non-protonated heterocycles (Schemes 6, 7 and 8, Section 3.05.1.2.2), and 3,3-dimethyl-3//-indole has been reported to react with 7r-electron-rich aromatic compounds to yield the 2-ary.l-3,3-dimethyl-2,3-dihydroindoles (77S343). In the absence of a nucleophile strong acids promote the interchange of substituents at the 2- and 3-positions of 2,3,3-trisubstituted 3//-indoles, e.g. (510) (511) (62JOC1553). 

Only a few papers on the formation of compounds with small rings have been published. One example is the [2 + 2]-cycloaddition of electron-rich enamines to Schiff bases under high pressure (1.4 GPa) (87JOC365). The reaction leads to substituted azetidines (1). Four-membered ring heterocycles, thietane derivatives (4), are formed by interaction of sulfene (2) with enamines (3) (86CB257 93JOC3429). 

A logical route to the synthesis of platinum carbene complexes is by using a carbene precursor. This method has been successfully used with electron-rich alkenes. Reacting (30) with ci -PtCl2(PPh3)2 and similar complexes leads to the formation of carbene complexes (equation 125).378-380 Heterocyclic chloro compounds have also been used to prepare carbene complexes (equation 126).381... 

Nucleophiles other than hydride can be added to support-bound imines to yield amines. These include C,H-acidic compounds, alkynes, electron-rich heterocycles, organometallic compounds, boronic acids, and ketene acetals (Table 10.9). When basic reaction conditions are used, stoichiometric amounts of the imine must be prepared on the support (Entries 1-3, Table 10.9). Alternatively, if the carbon nucleophile is stable under acidic conditions, imines or iminium salts might be generated in situ, as, for instance, in the Mannich reaction. Few examples have been reported of Mannich reactions on insoluble supports, and most of these have been based on alkynes as C-nucleophiles. 

Reissert compounds (l-acyl-l,2-dihydro-2-quinolinecarbonitriles) have been prepared on cross-linked polystyrene and C-alkylated in the presence of strong bases (Entry 8, Table 15.25). Treatment of polystyrene-bound C-alkylated Reissert compounds with KOH leads to the release of isoquinolines into solution (Entry 9, Table 15.25). The reaction of support-bound quinoline- and isoquinoline /Y-oxides with acy-lating agents followed by treatment with electron-rich heteroarenes and enamines has been used to prepare alkylated and arylated derivatives of these heterocycles (Entry 10, Table 15.25 see also Table 15.26). 

Compounds containing the C=N functional group derivatives undergo anodic oxidation when the nitrogen atom bears an electron-rich heteroatom. Perhaps the simplest such species are aldoximes, which are anodically oxidized to nitrile oxides (34)38. The reaction was carried out in an undivided cell3 , hence the species 34 underwent immediate reduction to a nitrile (equation 19). However, since nitrile oxides are 1,3-dipolar species, one could in principle carry out the oxidation in a divided cell in the presence of a good 1,3-dipolarophile40 to effect the synthesis of substituted heterocycles. 

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