Substitution imidazoles

Uses. Uses of sulfuryl chloride include the manufacture of chlorophenols, eg, chlorothymol for use as disinfectants. It is also used in the manufacture of alpha-chlorinated acetoacetic derivatives, eg, CH2COCHCICOOC2H3, which ate precursors for important substituted imidazole dmgs,... 

Ketoconazole. For treatment of systemic mycoses with amphotericin B or miconazole, the patient must be admitted to a hospital. This is not always possible, particularly in areas where systemic mycoses occur frequently, nor is it always desirable, because of the expense. For these reasons, it was desirable to find an antimycotic that combined safety and broad-spectmm activity with oral adraiinistration. Ketoconazole (10), which is orally active, met most of these requirements. This inhibitor of the ergosterol biosynthesis is an A/-substituted imidazole, that differs from its precursors by the presence of a dioxolane ring (6,7). Ketoconazole is rapidly absorbed in the digestive system after oral adrninistration. Sufficient gastric acid is required to dissolve the compound and for absorption. Therefore, medication that affects gastric acidity (for example, cimetidine and antacids) should not be combined with ketoconazole. 

SH 1-Substituted imidazole Liquid film, MeOH, EtOH NH, C=S... 

Imidazoles are hydroxymethylated by CH2O at the 4-position 1-substituted imidazoles react at the 2-position. Isoxazoles can be chloromethylated in the 4-position (63AHC(2)365). 

Uncharged azoles not containing oxygen or sulfur are often resistant to attack by hydroxide ions at temperatures up to 100 °C and above. However, neutral azoles react with hydroxide ions under extreme conditions, e.g. 1-substituted imidazoles such as (153) at 300°C give the corresponding imidazolinone (154) 80AHC(27)24l). 

Substituted imidazoles can be acylated at the 2-position by acid chlorides in the presence of triethylamine. This reaction proceeds by proton loss on the (V-acylated intermediate (241). An analogous reaction with phenyl isocyanate gives (242), probably via a similar mechanism. Benzimidazoles react similarly, but pyrazoles do not (80AHC(27)24l) cf. Section 4.02.1.4.6). 

Table 1. Thermal Condensation of Substituted Imidazoles with TrifluoroacetaJdehyde Ethyl Hemiacetal [5]...

The formation of quaternary salts by the action of the common quatemizing reagents on 1-substituted imidazoles and benzimidazoles (29) to give salts of type 30 is well known. Only N-3 possesses a free... 

Annular tautomerism of azoles and benzazoles [the nonaromatic tautomers of imidazole 17, 2H and 4(5)H have been calculated at the MP2/6-31G level to be about 15 kcal mol less stable than the IH tautomer (95JOC2865)]. We present here the case of 4(5)-substituted imidazoles, different from the histamine, histidine, and derivatives already discussed. By analogy with these histamines, 4-methylimidazole 17a is often named distal [N(t)H] and 5-methylimidazole 17b, proximal [N(7t)H] (Scheme 9). 

Theoretical studies of the relative stabilities of tautomers 14a and 14b were carried out mostly at the semiempirical level. AMI and PM3 calculations [98JST(T)249] of the relative stabilities carried out for a series of 4(5)-substituted imidazoles 14 (R = H, R = H, CH3, OH, F, NO2, Ph) are mostly in accord with the conclusion based on the Charton s equation. From the comparison of the electronic spectra of 4(5)-phenylimidazole 14 (R2 = Ph, R = R3 = H) and 2,4(5)-diphenylimidazole 14 (R = R = Ph, R = H) in ethanol with those calculated by using ir-electron PPP method for each of the tautomeric forms, it follows that calculations for type 14a tautomers match the experimentally observed spectra better (86ZC378). The AMI calculations [92JCS(P1)2779] of enthalpies of formation of 4(5)-aminoimidazole 14 (R = NH2, R = R = H) and 4(5)-nitroimidazole 14 (R = NO2, R = R = H) point to tautomers 14a and 14b respectively as being energetically preferred in the gas phase. Both predictions are in disagreement with expectations based on Charton s equation and the data related to basicity measurements (Table III). These inconsistencies may be... 

We do not discuss in detail the cases of tautomerism of heterocycles embedded in supramolecular structures, such as crown ethers, cryptands, and heterophanes, because such tautomerism is similar in most aspects to that displayed by the analogous monocyclic heterocycles. We concentrate here on modifications that can be induced by the macrocyclic cavity. Tire so-called proton-ionizable crown ethers have been discussed in several comprehensive reviews by Bradshaw et al. [90H665 96CSC(1)35 97ACR338, 97JIP221J. Tire compounds considered include tautomerizable compounds such as 4(5)-substituted imidazoles 1///4//-1,2,4-triazoles 3-hydroxy-pyridines and 4-pyridones. 

All triazoles, tetrazoles, and unsymmetrically substituted imidazoles and pyrazoles can exist in two tautomeric forms, e.g., 1 2 and 3 4. However, attempts to isolate the individual tautomers have been unsuccessful, always leading to one isomer (for summaries of this aspect of the tautomerism of imidazoles, see references 1 and 2). Although the isolation of both tautomers of a number of com-... 

By far the most common starting material is l-methylimidazole. This is readily available at a reasonable cost, and provides access to the majority of cations likely to be of interest to most researchers. There is only a limited range of other N-substituted imidazoles commercially available, however, and many are relatively expensive. The synthesis of l-alkylimidazoles may be achieved without great difficulty, though, as indicated in Scheme 2.1-2. 

A wider range of C-substituted imidazoles is commercially available, and the combination of these with the reaction shown in Scheme 2.1-2 permits the formation of many different possible starting materials. In some cases, however, it may still be necessary to carry out synthesis of the heterocycle from first principles. For reasons of space, this topic is not covered here. 

In Brown s classification a diazonium ion is a reagent of very low reactivity and correspondingly high substrate selectivity and regioselectivity. This follows from the fact that benzenediazonium salts do not normally react with weakly nucleophilic benzene derivatives such as toluene. More reactive heteroaromatic diazonium ions such as substituted imidazole-2-diazonium ions will even react with benzene (see Sec. 12.5). 

A number of microwave-assisted multicomponent methods for the synthesis of imidazoles have been reported [68-71 ]. The irradiation of a 1,2-diketone and aldehyde with ammonium acetate in acetic acid for 5 min at 180 °C in a single-mode reactor provides alkyl-, aryl-, and heteroaryl-substituted imidazoles 39 in excellent yield (Scheme 14) and this method has been used for the rapid and efficient preparation of two biologically active imidazoles, lepidiline B and trifenagrel [68]. 

The imidazole ring is a privileged structure in medicinal chemistry since it is found in the core structure of a wide range of pharmaceutically active compounds efficient methods for the preparation of substituted imidazole libraries are therefore of great interest. Recently, a rapid synthetic route to imidazole-4-carboxylic acids using Wang resin was reported by Henkel (Fig. 17) [64]. An excess aliphatic or aromatic amine was added to the commercially available Wang-resin-bound 3-Ar,M-(dimethylamino)isocyano-acrylate, and the mixture was heated in a sealed vial with microwave irradi-... 

The mechanism of the reaction has not been eiuddated. Presumably iodine eliminates the imidazole ring from N-substituted imidazole derivatives such as clotrimazole, and this then couples with diazotized sulfanilic acid to yield an azo dye. 

Note The reaction is very specific for N-substituted imidazole derivatives. In serum investigations the detection limit was 50 ng clotrimazole per milliliter serum. The reagent can be employed on silica gel, kieselguhr and Si 50000 layers. 

With sUght modifications of these conditions it is possible to prepare mono N-substituted imidazoles (Scheme 5), the reaction working well with aliphatic amines but not with many aromatic amines. The imsymmetrical... 

Burgess followed a similar strategy for the preparation of the salts 8 (Scheme 7). On that occasion several routes to mono-N-substituted imidazoles were explored yielding the desired compoimds in variable yields depending on the nature of the amines. The chirality was introduced via alkylating reagents 9 bearing chiral oxazolines [15]. 

Gade and Bellemin-Laponnaz have reported the synthesis, in good yields, of chiral oxazoline-imidazoliums salts 10a (Scheme 8) obtained by reaction of 2-bromo-4(S)-t-butyl oxazoline with several mono-N-substituted imidazoles [16]. Similaly an imidazolium salt 10b bearing a paracyclophane substituent was prepared by Bolm [17]. 

The O-silylated acyloins such as 1920 c and 1927 are useful synthons for preparation of five-membered aromatic heterocycles such as the substituted imidazole 1925, pyrrole 1926, and furan 1928 [119] (Scheme 12.35). 

The reactive 1-acyl-3-alkylimidazolium species also plays a role in acylation of alcohols with carboxylic anhydrides or carboxylic acid chlorides using 1-substituted imidazoles as catalysts.[145] In this case the reactive species is formed in situ ... 

Illustrative yields for the two acylation methods catalyzed by -substituted imidazoles are given in the following tables. 

Table 3-4. Acylation of 4-methyl-2-pentanol with acetic anhydride to produce the acetate, with the indicated N-substituted imidazoles as catalysts. 1451...

Further examples for the preparation of 4(5)-substituted imidazoles with AT-sulfa-moylimidazoles are given below. In these cases both the sulfamoyl and the silyl groups are used as protecting functions (bisprotection of the imidazole moiety). 163... 

From silylated iV-sulfamoyl-protected imidazoles or pyrazoles, imidazolyl or pyr-azolyl anions can be generated with the strong base CsF (carbodesilylation) and subsequently treated with electrophiles. In this way 5-substituted imidazoles or pyrazoles can be prepared after the deprotection of N(l) [181... 

Table 20-1. N-Substituted imidazoles and triazoles prepared by transfer reactions of azolides A—F with tertiary alcohols of the triphenylmethanol type and analogues.

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