3- Substituted imidazole 1-oxide oxidation

Chichibabin reaction, 5, 409-410 UV spectra, 5, 356 Naphthimidazoles, 2-amino-tautomerism, 5, 368 Naphth[2,3-h]imidazoles oxidation, 5, 405 Naphth[l,2-d]imidazolium salts nucleophilic substitution, 5, 412 Naphth[l, 2-h]isoquinolines... 

The synthesis of the furan-imidazole derivatives, shown in Scheme 2, were also described by Wang et al. [34]. Reaction of 4-(dimethylamino)benzalde-hyde (20) with trimethylsilylcyanide (TMS)-CN in the presence of Znl2 produced the TMS cyanohydrin 21. Compound 21 was treated with LDA followed by the addition of 3,4,5-trimethoxybenzaldehyde to give the benzoin intermediate 22. Oxidation with CUSO4 in aqueous pyridine, followed by reaction with 3-furaldehyde in acetic acid, produced the substituted imidazole 23. 

Imidazole was converted by hydrogenation over platinum oxide in acetic anhydride to 1,3-diacetylimidazolidine in 80% yield, and benzimidazole similarly to 1,3-diacetylbenzimidazoline in 86% yield [480. While benzimidazole is very resistant to hydrogenation over platinum at 100° and over nickel at 200° and under high pressure, 2-alkyl- or 2-aryl-substituted imidazoles are reduced in the benzene ring rather easily. 2-Methylbenzimidazole was hydrogenated over platinum oxide in acetic acid at 80-90° to 2-methyl-... 

Amino methyl substituted pyrrolo-benzodiazepine 215 forms a cyclic aminal with aldehydes that can be further oxidized with Mn02 to fused 3-substituted imidazole 216. Alternatively, cyclic imine 217 can be submitted to TosMlC cycli-zation to afford unsubstituted 9H-benzo[e]imidazo[5,l-c]pyrrolo[l,2-fl][l,4]-diazepine 218 (Scheme 45, Section 3.1.1.2 (1993JHC749)). 

The formula for the parent 3-substituted imidazole 1-oxide 245 is shown in Scheme 67... 

The resonance structures of the 3-substituted imidazole 1-oxides 245 are discussed in Section 1.1.1. According to IUPAC nomenclature, structure 245 is a 1-substituted lH-imidazole 3-oxide since the rules dictate that when R=H the indicated hydrogen position takes numbering precedence. Other names found in the literature are 1-substituted imidazole 3-oxides or 1-substituted 3-oxo-lH-imidazoles. Frequently the numbering is switched to give the names 3-substituted 2H-imidazole 1-oxide, 3-substituted imidazole 1-oxides, or 3-substituted 1 -oxo-3H-imidazoles. In the present review the most commonly used naming, which is accepted by IUPAC, Chem. Abstr. Autonom., is used calling structure 245 a 3-substituted imidazole 1-oxide. Consistently, structure 245 (R=OH, OAlk, or NH2) is named 3-hydroxy, 3-alkoxy, or 3-aminoimidazole 1-oxide, respectively. 

Substituted imidazole 1-oxides 228 can be prepared by N-oxidation of imidazoles 248, by N-alkylation of 1-hydroxyimidazoles 249, or by cycliza-tion using suitable starting materials derived from a 1,2-dicarbonyl compound, an aldehyde, an amine, and hydroxyamine. The substituents at the three first starting materials are transferred to the product and make control over the substituents in the imidazole 1-oxide 228 possible depending on the protocol used by the synthesis. The synthesis of 3-hydroxyimidazole 1-oxides is presented in Section 3.1.6. 

At-Alkylation of 1-hydroxyimidazoles 249 produces 3-substituted imidazole 1-oxides 228 (R=Aik) in low yields due to competing O-alkylation and dialkylation leading to 1-alkoxyimidazoles 250 and l-alkyl-3-alkyloxy-imidazolium salts 251, respectively (1970ZC211,1990S795) (Scheme 70). 

This issue was addressed taking into advance that butyloxycarbonyl (Boc)protection of 249 takes place regioselectively at the oxygen atom to give 252. Subsequent alkylation finds only N-3 accessible for attack (1990S795). Subsequent methanolysis and neutralization afforded the 3-substituted imidazole 1-oxide 228 (Scheme 71). 

Substituted imidazole 1-oxides 228 are predicted to be activated toward electrophilic aromatic substitution, nucleophilic aromatic substitution, and metallation as described in Section 1. Nevertheless little information about the reactivity of imidazole 1-oxides in these processes exists. The reason for this lack may be the high polarity of the imidazole 1-oxides, which makes it difficult to find suitable reaction solvents. Another obstacle is that no method for complete drying of imidazole 1-oxides exists and dry starting material is instrumental for successful metallation. Well documented and useful is the reaction of imidazole 1-oxide 228 with alkylation and acylation reagents, their function as 1,3-dipoles in cycloadditions, and their palladium-catalyzed direct arylation. 

Substituted imidazole 1-oxides 263 upon treatment with dimethyl or diethyl sulfate furnish l-alkoxy-3-subtituted imidazolium salts 283 that were converted to the tetrafluoroborate 283 (A- = BF4 ) or hexafluorophos-phates 283 (A = PF6-) by treatment with sodium tetrafluoroborate or hexa-fluorophosphate (2007ZN(A)295). The tetrafluoroborates 283 (A = BF4 ) reacted with cyanide ion to give 2-cyanoimidazoles 285 (1975JCS(P1)275). The reaction probably follows a mechanism similar to that suggested to be operative in the pyrazole series encompassing O-alkylation succeeded by nucleophilic addition and elimination of methanol (Scheme 85). 

Cycloaddition with thioketones 3-Substituted imidazole 1-oxides 228 react with 2,2,4,4-tetramethylcylobutane-l,3-dithione with formation of l,3-dihydro-2H-imidazol-2-thiones 305 (1998HCA1585, 2011H765). 

N-Dealkylation of 3-substituted imidazole 1-oxides 228 has not been reported. 

The rearrangements taking place when 3-substituted imidazole 1-oxides 228 are treated with acetic anhydride are discussed in Section 3.1.8.8. 

Acylation, O-silylation, or O-phosphorylation, expected to follow the trends observed for 3-substituted imidazole 1-oxides, have not been reported. 

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