Nitrogen thiazolic reaction

Thiazoles can be quaternized at nitrogen by reaction with a range of alkylating agents. These salts can form an ylide by deprotonation at C-2. This thiazolium 2-ylide is markedly stable because of the ability of sulfur to stabilize an adjacent carbanion. The reaction is of considerable importance due to the occurrence of thiazolium-2-ylides as intermediates in classical biochemical (thiamine action) and chemical (Stetter reaction) processes (see Section 3.06.12). Desilylation at C-2 can lead to a thiazolium 2-ylide as well. Thus, the formation of this type of intermediate has been formulated as a key step along the reaction pathway involving a 2-trialkylsilylthiazole and C-electrophiles (Dondoni reaction, see Section 3.06.12.12). Thiazolium salts are also susceptible to be oxidized by a variety of oxidants (see Section 3.06.5.4.8). 

The amino group activates the thiazole ring toward electrophilic centers. This point is illustrated by the rate constants of the reaction between 2-dialkylaminothiazoles (32) and methyl iodide in nitromethane at 25 C (Scheme 23) (158). The steric effects of substituents on nitrogen are... 

Thus in neutral medium the reactivity of 2-aminothiazoles derivatives toward sp C electrophilic centers usually occurs through the ring nitrogen. A notable exception is provided by the reaction between 2-amino-thiazole and a solution (acetone-water, 1 1) of ethylene oxide (183) that yields 2-(2-hydroxyethylamino)thiazole (39) (Scheme 28), Structure 39... 

Both carbonyl groups of terephthaldehyde are reported to react with the exocyclic nitrogen of 2-aminothiazole yielding 1.4-phenylene bis(2-methyleneamino)thiazole. The same report describes the reactions of 2-amino-4-phenylthiazole with terephth aldehyde and salicylaldehyde as yielding 64 and 65, respectively (Scheme 45) (215), whose structures are based on ultraviolet and infrared spectra. 

The nitro group increases the acidity of the hydrogen born by the exocyclic nitrogen, and alkylation of 2-nitraminothiazole with diazomethane is possible (87), The formed 2-(A"-methylnitramino)-thiazole also may be obtained from the reaction of 2-nitraminothiazole with dimethylsulfate in basic medium (194). 

The interesting reactions where a free mercapto group is linked to the nitrogen atom of the thiazole (63), after the cleavage of a fused ring, is another illustration of the additive properties of the carbocation (Scheme 40). 

Thiazolium salts with alkyl (103, 722), arylalkyl (116), aryl (305), or heteroaryl (96) substituents on the nitrogen have been also prepared by this procedure. As in the thiazole series, N-substituted thioamides can be formed directly in the reaction mixture from phosphorus pentasulfide and N-substituted amides (127). These methods are important in the synthesis of thiamine 102 (vitamin Bj) (Scheme 45). 

The quatemization of the nitrogen atom of the thiazole ring (the Menschutkin s reaction) by alkyl halide or methyl tosylate can be used to measure the reactivity of this atom and thus to evaluate steric and electronic effects of ring substituents. 

The quatemization reaction of the thiazole nitrogen has been used to evaluate the steric effect of substituents in heterocyclic compounds since thiazole and its alkyl derivatives are good models for such study. In fact, substituents in the 2- and 4-positions of the ring only interact through their steric effects (inductive and resonance effects were constant in the studied series). The thiazole ring is planar, and the geometries of the ground and transition states are identical. Finally, the 2- and 4-positions have been shown to be different (259. 260). 

Physical Chemical Characterization. Thiamine, its derivatives, and its degradation products have been fully characterized by spectroscopic methods (9,10). The ultraviolet spectmm of thiamine shows pH-dependent maxima (11). H, and nuclear magnetic resonance spectra show protonation occurs at the 1-nitrogen, and not the 4-amino position (12—14). The H spectmm in D2O shows no resonance for the thiazole 2-hydrogen, as this is acidic and readily exchanged via formation of the thiazole yUd (13) an important intermediate in the biochemical functions of thiamine. Recent work has revised the piC values for the two ionization reactions to 4.8 and 18 respectively (9,10,15). The mass spectmm of thiamine hydrochloride shows no molecular ion under standard electron impact ionization conditions, but fast atom bombardment and chemical ionization allow observation of both an intense peak for the patent cation and its major fragmentation ion, the pyrimidinylmethyl cation (16). 

A multiply bonded nitrogen atom deactivates carbon atoms a or y to it toward electrophilic attack thus initial substitution in 1,2- and 1,3-dihetero compounds should be as shown in structures (110) and (111). Pyrazoles (110 Z = NH), isoxazoles (110 Z = 0), isothiazoles (110 Z = S), imidazoles (111 Z = NH, tautomerism can make the 4- and 5-positions equivalent) and thiazoles (111 Z = S) do indeed undergo electrophilic substitution as expected. Little is known of the electrophilic substitution reactions of oxazoles (111 Z = O) and compounds containing three or more heteroatoms in one ring. Deactivation of the 4-position in 1,3-dihetero compounds (111) is less effective because of considerable double bond fixation (cf. Sections 4.01.3.2.1 and 4.02.3.1.7), and if the 5-position of imidazoles or thiazoles is blocked, substitution can occur in the 4-position (112). 

Furthermore, the strongly metallic character of selenium weakens the C-Se bond and thus favors reactions involving opening of the ring. The basicity of the three heterocycles is approximately in the same order, the nitrogen atom of selenazole and thiazole possessing much the same properties as the heteroatom of pyridine. Of the two carbon atoms ortho to nitrogen, that is, the 2-carbon and the 4-carbon, only the one in the 2-position is fairly active as a result of its interaction with selenium or sulfur. The 4- and 5-positions of thiazole and selenazole are more susceptible to electrophilic substitution than the 3- and 5-positions of pyridine. This is particularly true of the 5-position of selenazole. Thus it can be said that the 2- and 5-positions of the selenazoles and thiazoles... 

The carbonylation of imidazole derivatives with several olefins takes place in high yields with the aid of an Ru3(CO)i2 catalyst.112,112a The carbonylation occurs exclusively at the a-position to the sp2 nitrogen (Equation (85)). A wide range of olefins can be utilized in this reaction, and a variety of functional groups are compatible under the reaction conditions. The (/i-H)triruthenium clusters such as 12 are proposed as a key species in this carbonylation reaction. Other five-membered A-heteroaromatic compounds, such as pyrazoles, oxazoles, and thiazoles, can be used for the carbonylation reactions, where the carbonylation takes place at the a-C-H bond to the sp2 nitrogen. 

By comparing rates for the thiazolium cation and neutral thiazole it is clear that the positive charge on the a-nitrogen is worth more than a factor of 10 to the exchange rate at the 2-position. Similarly, 2-methyliso-thiazolium iodide (29) exchanges its 5-H approximately 10 times faster than isothiazole itself. Substituent effects for isothiazole are similar to those observed for thiazole and the reaction is catalyzed by OD with... 

Thiamine diphosphate (TPP, 3), in cooperation with enzymes, is able to activate aldehydes or ketones as hydroxyalkyl groups and then to pass them on to other molecules. This type of transfer is important in the transketo-lase reaction, for example (see p. 152). Hydroxyalkyl residues also arise in the decarboxylation of 0x0 acids. In this case, they are released as aldehydes or transferred to lipoamide residues of 2-oxoacid dehydrogenases (see p. 134). The functional component of TPP is the sulfur- and nitrogen-containing thiazole ring. 

A base-mediated condensation of an isocyanide and an isothiocyanate gives 4,5-disubstituted thiazoles, as first reported by Matsumoto et al. in 1982 [73]. In subsequent work by Solomon et al., a regioisomeric imidazole was observed as a side-product due to the flexibility of the route that allows facile introduction of a substituent on the exocyclic nitrogen atom [74]. Baxendale et al. [75] explored this reaction under microfiow conditions (Scheme 33). 

In a similar vein, reaction of the thiobenzamide (100-1) with 4-bromoacetoacetate (100-2) in the presence of a base starts by the displacement of bromine by sulfur to afford a transitory substimtion product such as (100-3). This can then undergo internal imine formation between basic nitrogen and the adjacent carbonyl goup to afford the thiazole (100-4). Saponification then leads to the NSAID fenclosic acid (100-5) [110]. 

The presence of an internal salt, a zwitterion or betaine, in cephalosporins enhances their solubity in water, making such agents particularly suitable for parenteral administration. The preparation of one such dmg first involves the replacement of allyl oxygen in the tert-butylcarbonyloxy protected 7-ACA derivative (23-1) by nitrogen in azaindan (23-2) to afford the betaine (23-3). The protecting group is then removed so as to free the amine on the azetidone (23-4) by treatment with trifluoroacetic acid. Reaction with the thiazole free acid (23-5) in the presence of DCC then affords cefpirone (23-6) [26]. 

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