Heterocycles, acylation arylation

So-called aryl values have been introduced by Imoto et ai. - for the piu pose of systematizing the reactivities of different aromatic systems by means of the linear free-energy relationship, which however, could not be applied to the decomposition rates of heterocyclic acyl azides in toluene. ... 

Several aromatic and heterocyclic acyl trimethylsilanes have been used as acyl anion equivalents by treatment with fluoride ion (Scheme 81, path a)23 133 154b160191192. Provided that the acyl substituent is electron-withdrawing, and that there are no aryl substituents on the silicon atom, acyl anions can be trapped by various electrophiles in moderate to good yields indeed, acyl anions and pentacoordinate silicon anionic species have both been detected in gas-phase reactions of acyl silanes with fluoride ion193. 

The method has been adapted to the formation of l)fs-diazoacetylalkanes from dibasic acid chlorides. Diazo ketones have been obtained from acyl chlorides containing a /Sj y-double bond, an ester group, and certain heterocyclic and aryl nuclei having alkyl, methoxyl, and nitro substituents. On the other hand, functional groups such as phenolic hydroxyl, arylamino, aldehyde, active methylene, and a,/S-unsaturated linkages may interfere. The method is ideal for application to complex molecules. 

The aerobic reduction of aryl and alkyl carboxylates to the corresponding aldehydes. The reaction involves formation of an acyl-AMP intermediate by reaction of the carboxylic acid with ATP NADPH then reduces this to the aldehyde (Li and Rosazza 1998 He et al. 2004). The oxidoreductase from Nocardia sp. is able to accept a range of substituted benzoic acids, naphthoic acids, and a few heterocyclic carboxylic acids (Li and Rosazza 1997). 

R1 = H, alkyl, aryl R4 = aryl, alkyl, heterocycle E = ester, acyl, amide nitro... 

Diazadienes have been used in organic synthesis for the preparation of various heterocyclic compounds. Alkylation of 1,3-diazadienes 207 and the benz-fused analog 210 at the nitrogen atom by aryl acyl bromides provided the iV-alkyl amidinium bromides 208 and 211, which underwent annulation to the 2,3-dihydro-imidazo[2,l-A]thiazole 209 and imidazo[2,l- ]benzothiazoles 212, respectively (Equations 92 and 93) <2001S741, 2002J(P1)741>. 

Amino-substituted naphthoquinones and heterocyclic variants have been disclosed in the patent literature as 5-LO inhibitors. Compounds represented by (80) (X = C, N) from Lilly inhibited SRS-A release from sensitized guinea-pig lung tissue [218]. Similar compounds such as (81) (R = carboxylic ester, acyl, or aryl) and related naphthalene derivatives, from American Cyanamid, gave good inhibition in guinea-pig ISN (at 10 //g/ml) and in passive cutaneous anaphylaxis in mice (25-60 /zM i.p.) [219,220]. 

Enehydroxylamines (102) are invoked as intermediates in the rearrangement of O-vinyl, acyl or aryl oximes (101) (equation 31). Varlamov and coworkers demonstrated that the heterocyclization of ketoximes (103) with acetylene in snper basic medium and in the presence of metal hydroxides proceeds by a [3,3]-sigmatropic rearrangement of the enehydroxylamine 105 of the corresponding oxime vinyl ethers 104 (equation 32). The unreactivity of 3-methyl-2-azabicyclo[3.3.1]nonan-9-one oxime (106) in the same reaction conditions was explained by its inability to isomerize to the corresponding enehydroxylamine. 

A second type of synthetic route to meso-ionic l,3,4-thiadiazol-2-imines (247) is based on the acid-catalyzed reaction of N-thioacylhydrazines (232) with aryl isothiocyanates (Ar-NCS). " This reaction yields the s ts (248) as precursors of the meso-ionic heterocycles (247). An interesting variant upon this route involves the reaction between IV-thioacylhydrazines (232) and acyl isothiocyanates (RCO-NCS). This leads to the meso-ionic heterocycles 247, R = COzEt, CONMej, COMe, COCMe, COAr, and SOjPh. The investigation of these compounds by X-ray photoelectron spectroscopy is a good example of the application of this physical method for the examination of meso-ionic compounds. 

Other synthetic routes to benzazepines involving ring expansion of six-membered heterocycles include the action of diazomethane (77CPB321), sulfonium ylides (77H(7)37> or acyl halides (75T1991) on quaternary 3,4-dihydroisoquinolines that of sulfoxonium ylides on quaternary quinolines (74IJC(B)1238) and the zinc-acetic acid reduction of quaternary 1-acyltetrahydroisoquinolines (77BSF893). Photoaddition of acyl- or aryl-nitrenes to the exocyclic alkene bond of 2-methylene-1,2-dihydroquinolines results in ring expansion to... 

Aryl and alkyl nitriles also react with pyrrolyl and indolyl anions to yield the acylated heterocycles (see Section 3.05.1.2.9). 

Heterocycles containing an NH group, such as pyrroles, indoles, imidazoles, triazoles, etc., can be linked to insoluble supports as N-alkyl, N-aryl, or N-acyl derivatives (Table 3.29). The optimal choice depends mainly on the NH acidity of the heterocycle in question. Increasing acidity will facilitate the acidolytic cleavage of N-benzyl groups and the nucleophilic cleavage of /V-acyl groups from these heterocycles. 

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). 

Acyl peroxides of structure (16) are known as diacyl peroxides. In this structure R1 and R2 are the same or different and can be alkyl, aryl, heterocyclic, imino, amino, or fluoro. Acyl peroxides of structures (17), (18), (19), and (20) are known as dialkyl peroxydicarbonates, OO-acyl ((-alkyl monopcroxycarbonatcs. acyl organosulfonyl peroxides, and di(oiganosulfonyl) peroxides, respectively. R1 and R2 in diesc structures are the same or different and generally are alkyl and aryl. Many diacyl peroxides (16) and dialkyl peroxydicarbonates (17) are produced commercially and used in large volumes. 

Broadly, NOC are divided into two groups (a) /V-nitrosamines and (b) N-nitrosamides. In jV-nitrosamines, the two remaining substituent groups on the >N—N=0 atom can be either alkyl or aryl, or they can form the part of a heterocyclic ring (as in N-nitrosopyrrolidine). On the other hand, in N-nitrosamides, more correctly called N-acyl-N-nitroso compounds, one of these... 

Hilgeroth, A., Baumeister, U. and Heinemann F.W., Solution-dimerization of 4-Aryl- 1,4-dihydropyridines, Eur. J. Org. Chem., 2000, 245-250 Hilgeroth, A., Baumeister, U. and Heinemann F.W., Rotameric properties of novel N acyl and N-acyloxy dimeric 4-phenyl-1,4-dihydropyridines derived from developed solid-state synthesis, Heterocycles, 1999, 51, 2367-2376. 

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