Imidazoles sulfonation

Anilino-5 -o -2 [3-axiimo-phenyl] [naphtbo-1 2 4.5-imidazol]-sulfon saure (7 ) 86, 627. 

In azole chemistry the total effect of the several heteroatoms in one ring approximates the superposition of their separate effects. It is found that pyrazole, imidazole and isoxazole undergo nitration and sulfonation about as readily as nitrobenzene thiazole and isothiazole react less readily ica. equal to m-dinitrobenzene), and oxadiazoles, thiadiazoles, triazoles, etc. with great difficulty. In each case, halogenation is easier than the corresponding nitration or sulfonation. Strong electron-donor substituents help the reaction. 

Sulfonation conditions are given in Table 4. The orientation is as expected. Azolinones react as readily as the corresponding azoles sulfonation of (117) occurs at the positions indicated (H2SO4/SO3 at 100 °C). Imidazoles are readily chlorosulfonated at C-4. 

Alkylthio groups are oxidized to sulfoxides by H2O2 and readily by various oxidizing reagents to sulfones, e.g. in the imidazole series. The SR group is replaced by hydrogen with Raney nickel, and dealkylation is possible, e.g. of 3-alkylthio-l,2-dithiolyliums to give... 

Azolesulfonic acids frequently exist as zwitterions. The usual derivatives are formed, e.g. pyrazole-3-, -4- and -5-sulfonic acids all give sulfonyl chlorides with PCI5. The sulfonic acid group can be replaced by nucleophiles under more or less vigorous conditions, e.g. by hydroxyl in imidazole-4-sulfonic acids at 170 °C, and by hydroxyl or amino in thiazole-2-sulfonic acids. 

Imidazole, 4-methyl-annular tautomerism, 5, 363 association, 5, 362 boiling point, 5, 362 bromination, 5, 398 deuteration, 5, 417 diazo coupling, 5, 403 hydrogen bonding, S, 350 hydroxymethylation, 5, 404 iodination, 5, 400 kinetics, 5, 401 mass spectra, 5, 358 melting point, 5, 362 methylation, 5, 364 sulfonation, 5, 397 synthesis, 5, 479-480, 482, 484, 489 Imidazole, 5-methyl-annular tautomerism, 5, 363 Imidazole, l-methyl-4-chloro-ethylation, 5, 386 Imidazole, l-methyl-5-chloro-ethylation, 5, 386 nitration, 5, 395... 

The antiarrhythmic activity of local anesthetics has been noted several times previously. Another such agent is prepared by first alkylating isopropylamine with sulfone 199. Reaction of the ])ioduct (200) with diethylethylenediamine and carbonyldiimidazole results in transfer of the CDI carbonyl group and formation of the urea suricainide (201) [52]. The transform in all likelihood involves stepwise replacement of the imidazole groups by the basic groups in the other reactants. 

B) A mixture of 2.4 parts of 1 acetyl-4-(4-hydroxyphenyl)piperazine, 0.4 part of sodium hydride dispersion 78% 75 parts of dimethylsulfoxide and 22.5 parts of benzene is stirred for one hour at 40°C. Then there are added 4.2 parts of cis-2-(2,4-dichlorophenyl)-2-(1 H-imidazol-1 -ylmethyl)-1,3-dioxolan-4-ylmethyl methane sulfonate and stirring is continued overnight at 100°C. The reaction mixture Is cooled and diluted with water. The product is extracted with 1,1 -oxybisethane. The extract is dried, filtered and evaporated. The residue Is crystallized from 4-methyl-2-pentanone. The product is filtered off and dried, yielding 3.2 parts (59%) of cis-1-acetyl-4-[2-(2,4-dichlorophenyl)-2-(1 H-imidazol-1-ylmethyl)-13-di-oxolan-4-ylmethoxy] phenyl] piperazine MP 146°C. 

Reaction of a-isocyano-a, / -unsaturated sulfones with primary aliphatic amines affords 1,5-disubstituted imidazoles 59 (equation 56)48. The reaction of aromatic amines such as aniline is too slow to be of practical use. Results of the preparation of 59 are listed in Table 5. 

A fluid loss additive useful in cementing oil and gas wells is a blend [423,424,1015] of a copolymer of acrylamide/vinyl imidazole. The second component in the blend is a copolymer of vinylpyrrolidone and the sodium salt of vinyl sulfonate. Details are given in Table 2-2. The copolymers are mixed together in the range of 20 80 to 80 20. Sodium or potassium salts or a sulfonated naphthalene formaldehyde condensate can be used as a dispersant. 

With carboxylic acids there was no activation to carboxylic acid imidazolides observed. Reaction with p-toluenesulfonic acid in boiling tetrahydrofuran did not yield the />-toluenesulfonic acid imidazolide, but rather the double p-toluene sulfonate, from which A -sulfonyldiimidazole can be released again quantitatively with imidazole or aniline. Only from the melt of water-free p-toluenesulfonic acid and AyV -sulfonyldiimidazole at 90 °C p-toluenesulfonic imidazolide (m.p. 75.5-77 °C 87% yield) could be obtained1201 (see also Section 10.1.1). 

Ester formation from polysaccharides can be achieved in several ways First by acylation of the OH groups with carboxylic or sulfonic acid azolides, second by converting the OH groups with imidazole carboxylates into carbonates, and third by reaction of an acid leash on the polysaccharide with an alcohol by means of CDI or analogous azolides. The acid leash might, for example, be a succinate attached to the polysaccharide. 

Imidazolides of aromatic sulfonic acids react much more slowly in alcoholysis reactions than the carboxylic acid imidazolides. Although the reaction with phenols is quantitative when a melt is heated to 100 °C for several hours, with alcohols under these conditions only very slight alcoholysis is observed. In the presence of 0.05 equivalents (catalytic amount) of sodium ethoxide, imidazole sodium, of NaNH2, however, imidazolides of sulfonic acids react with alcohols almost quantitatively and exothermically at room temperature in a very short time to form sulfonic acid esters (sulfonates). (If the ratio of sulfonic acid imidazolide to alcoholate is 1 2, ethers are formed see Chapter 17). The mechanism of catalysis by base corresponds to that operative in the synthesis of carboxylic esters by the imidazolide method. Because of the more pronounced nucleophilic character of alkoxide ions, sulfonates can also be prepared in good yield by alcoholysis of their imidazolides in the presence of hydroxide ions i.e., with alcoholic sodium hydroxide. 45 Examples of syntheses of sulfonates are presented below. 

The imidazolides required for these reactions can be prepared from sulfonyl chlor-ides[1] or sulfonic anhydrides[2] and imidazole, or by treatment of the corresponding sulfonic acid with CDI,[1] ImSOIm,[3] or ImS02Im[3] (see Section 10.1.1). However, for the synthesis of sulfonamides it is more convenient to employ a one-pot reaction starting from the free sulfonic acid, CDI or ImSOIm, and the appropriate amine [1]... 

With the sodium derivative of benzyl alcohol, dibenzyl ether was obtained in 63% yield, accompanied by 24% of A-benzylimidazole. Formation of the latter compound results from the reaction of the benzyl sulfonate with imidazol sodium in competition with the second step of the ether synthesis (b). 

Table 21-1. Halides prepared from alcohols via imidazole-V-carboxylates, -sulfonates and -sulfinates.

Di(2-pyridyl)-l //-imidazol-2-yl]phenylboronic acid A,A -Disuccinimidyl carbodiimide S -Diethylthiadicarbocyanine iodide Divinyl sulfone Electrochemical... 

Fig. 1 Plot of log for reaction of nucleophiles with an aryl sulfinyl sulfone (139) (Table 6) vs. log k 1 for their reaction with PhS02S02Ph (191) (Table 10) in 60% dioxan at 25°C. GEE, glycine ethyl ester Im, imidazole.

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