Imidazole opening

Figure 29 Spectrofluorimetric titration of the dizinc(II)-20 system in an aqueous solution buffered to pH = 9.6, with imidazole (open triangles), histidine (lull triangles), acetate (circles).

The photorearrangement of pyrazoles to imidazoles is probably analogous, proceeding via iminoylazirines (82AHC(30)239) indazoles similarly rearrange to benzimidazoles (67HCA2244). 3-Pyrazolin-5-ones (56) are photochemically converted into imidazolones (57) and open-chain products (58) (70AHC(ll)l). The 1,2- and 1,4-disubstituted imidazoles are interconverted photochemically. 

Imidazoles and benzimidazoles (155) react with acid chloride and alkali to give compounds of type (157), but these are reactions of the cation (156). 1,2,4-Triazoles and tetrazoles similarly undergo ring opening. 

Deacylations are known. C-Acyl groups in 1,3,4-thiadiazoles are cleaved by sodium ethoxide in ethanol (68AHC(9)165). Imidazole-2-carbaldehyde behaves similarly, yielding imidazole and ethyl formate this reaction involves an ylide intermediate. 3-Acylisoxazoles (405) are attacked by nucleophiles in a reaction which involves ring opening (79AHC(25)147). 

Isoxazoles (478) in the presence of base undergo ring opening to a-ketonitriles (479). When the reaction was carried out in the presence of hydrazines, 5-aminopyrazoles (480) were obtained. The reaction is also a convenient source of imidazoles, For example, when the 1,2-benzisoxazole (481) was treated with phenylhydrazine, decarboxylation initially occurred with subsequent ring closure to (482) (see Chapter 4.16). 

Heterocyclic amines are compounds that contain one or more nitrogen atoms as part of a ring. Saturated heterocyclic amines usually have the same chemistry as their open-chain analogs, but unsaturated heterocycles such as pyrrole, imidazole, pyridine, and pyrimidine are aromatic. All four are unusually stable, and all undergo aromatic substitution on reaction with electrophiles. Pyrrole is nonbasic because its nitrogen lone-pair electrons are part of the aromatic it system. Fused-ring heterocycles such as quinoline, isoquinoline, indole, and purine are also commonly found in biological molecules. 

N)-Ethy 1 lactate (98%) and imidazole (99+%) were purchased from Aldrich Chemical Co. TBDMSC1 was purchased from FMC Corporation (submitters) or Aldrich (checkers). A newly opened bottle of dimethylformamide (ACS Reagent grade, 0.02% water) was used as received. 

Scheme 24.—Correspondence between the carbon atoms of AIR and those of pyramine, and the mode of opening of the imidazole ring in the ring expansion in the synthesis of pyramine.

However, more-rigorous treatment (5% acetic acid, 100°C, 17 hours) opened the imidazole ring and produced /V -cyclohexyl-a-formylaminoacetamidine (57), characterized as the crystalline picrate. Amidine 57 produced no dye in the Bratton-Marshall assay. The same behavior can be expected from AIR (46), although the product of hydrolytic ring-opening was not actually isolated. On the other hand, it was observed that a solution of AIRs (0.2 mM in 0.01-M ammonium hydroxide) prepared by biosynthesis, when stored at 4°C, did not change appreciably within a day. A decrease in the concentration of AIRs of about 30% occurred within a month. 

The synthesis of imidazoles is another reaction where the assistance of microwaves has been intensely investigated. Apart from the first synthesis described since 1995 [40-42], recently a combinatorial synthesis of 2,4,5-trisubstituted and 1,2,4,5-tetrasubstituted imidazoles has been described on inorganic solid support imder solvent-free conditions [43]. Different aldehydes and 1,2 dicarbonyl compounds 42 (mainly benzil and analogues) were reacted in the presence of ammonium acetate to give the trisubstituted ring 43. When a primary amine was added to the mixture, the tetrasubstituted imidazoles were obtained (Scheme 13). The reaction was done by adsorption of the reagent on a solid support, such as silica gel, alumina, montmorillonite KIO, bentonite or alumina followed by microwave irradiation for 20 min in an open vial (multimode reactor). The authors observed that when a non-acid support was used, addition of acetic acid was necessary to obtain good yields of the products. 

However, when the X-ray crystal structure of the MoFe protein was examined, it was clear that homocitrate could not directly hydrogen bond to the histidine, since the carboxylate group and imidazole are stacked parallel to each other in the crystal. Nevertheless, as noted in the previous section, studies on model complexes have suggested that homocitrate can become monodentate during nitrogenase turnover, with the molybdenum carboxylate bond breaking to open up a vacant site at molybdenum suitable for binding N2. 

Phosphazene polymers can act as biomaterials in several different ways [401, 402,407]. What is important in the consideration of skeletal properties is that the -P=N- backbone can be considered as an extremely stable substrate when fluorinated alcohols [399,457] or phenoxy [172] substituents are used in the substitution process of the chlorine atoms of (NPCl2)n> but it becomes highly hydrolytically unstable when simple amino acid [464] or imidazole [405-407] derivatives are attached to the phosphorus. In this case, an extraordinary demolition reaction of the polymer chain takes place under mild hydrolytic conditions transforming skeletal nitrogen and phosphorus into ammonium salts and phosphates, respectively [405-407,464]. This opens wide perspectives in biomedical sciences for the utilization of these materials, for instance, as drug delivery systems [213,401,405,406,464] and bioerodible substrates [403,404]. 

The foam-holding characteristics of foam from surfactants in oil field jobs can be tailored by adding an imidazoline-based amphoacetate surfactant. Amphoacetates are a special class of amphoteric tensides (Figure 16-1). Imidazoles, such as 2-heptylimidazoline, are reacted with fatty acids under the ring opening. For alkylation, the imidazoline is reacted with, for example, chloroacetate [493]. 

Fig. 34. A cooperative open polymer assembled from imidazole-functionalized porphyrins.

The phosphorylation of alcohols by CEP-imidazole (41 X=N) with CEP-ring retention is already well-established. Following from the observation that CEP-pyrrole (41 X=CH) phosphorylates alcohols with CEP-ring opening, an explanation has been advanced based upon the differences in apicophilicities of the pyrrole and imidazole moieties in pentaco-ordinate intermediates (Scheme 10). A scale of relative reactivities based upon the reactions in the equations... 

Fig. 11) would likely proceed by different mechanisms. Protonation of the diol (IV, Fig. 12) derived from theobromine would lead to ring opening at the C6— Cs position giving an imidazole isocyanate (XVI, Fig. 12). This could readily form XVII which after hydrolysis and loss of C02 would give dimethyl-allantoin (XVIII). On the other hand, the uric acid diol derived from caffeine (X, Fig. 12) cannot fragment by this mechanism. Accordingly, either or both of the processes could Occur via the form of the diol hydrated at the C6 carbonyl group (XIX, Fig. 12) which could readily lose C02 to give XX followed by rearrangement to trimethylallantoin (XXI).

CsF induces the ring-opening cyclization of the thus obtained l-[2-(trimethylsilylmethyl)cyclopropylcarbonyl] imidazole 154 with diethyl fumar-ate or diethyl maleate to give the cyclobutanone 155 [80], The facile ring fission of 154 also occurs in the presence of BF3OEt with the formation of the corresponding y,<5-unsaturated carboxylic acid. (Scheme 55)... 

A rather complex microwave-assisted ring-opening of chiral difluorinated epoxy-cyclooctenones has been studied by Percy and coworkers (Scheme 6.131) [265]. The epoxide resisted conventional hydrolysis, but reacted smoothly in basic aqueous media (ammonia or N-methylimidazole) under microwave irradiation at 100 °C for 10 min to afford unique hemiacetals and hemiaminals in good yields. Other nitrogen nucleophiles, such as sodium azide or imidazole, failed to trigger the reaction. The reaction with sodium hydroxide led to much poorer conversion of the starting material. 

Microwave-assisted ring opening of (R)-styrene oxide by pyrazole and imidazole leads to the corresponding (R)-l-phenyl-2-azolylethanols. With pyrazole, use of microwave irradiation increases both chemo- and regioselectivity compared with the conventional heating [81] (Eq. 27). 

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