Electrophilic reactivity

Xmino substituents in both neutral and protonated thiazole rings should favor electrophilic reactivity. 

Acetamidothiazole is nitrated in the same way (58, 378, 379). 2-Acetamido-4-phenylthiazole is reported to be nitrated on C-5 (380) as opposed to 2-amino-4-phenylthiazole, where nitration occurs on the phenyl ring (381). This latter result is not consistent with the other data on electrophilic reactivity in most cases 2-amino-4-arylthiazole derivatives react with electrophilic reagents at the C-5 position (see Sections rV.l.B and D). Furthermore, N-pyridy]-(2)-thiazolyl-2-amine (178) is exclusively nitrated on the thiazole ring (Scheme 113) (132, 382). 

The recently reported rearrangement (1581) of 2-allylamino-4-carboxamido-5-aminothiazoIes to 4-aminoimidazole-5-carboxamide in presence of sodium bicarbonate probably involves the electrophilic reactivity of C-2, which allows the ring opening. 

Reactivity of A-4-thiazoline-2-thiones and derivatives involves four main possibilities nucleophilic reactivity of exocyclic sulfur atom or ring nitrogen, electrophilic reactivity of carbon 2 and electrophilic substitution on carbon 5. 

An interesting reaction studied by Gronowitz et al. (244) also involves the electrophilic reactivity of C-5. When R4 = Me the yields of dimerization product (101) are much lower than if R4 = H (Scheme 51). Ganapathi... 

An example of the electrophilic reactivity of the C-4 atom is the easy formation of oxime and phenylhydrazone derivatives (422). It has been reported, however, that 2 pheny -A-2-thiazoline-4-one does not react with phenylhydrazine (397). 

All attempts to prepare selenazole derivatives by the Gatterman (for-mylation) or Friedel-Crafts (alkylation) methods failed (19, 26). indicating that the electrophilic reactivity of the 5-position is less than that of benzene or toluene. 

Bulka et al. (43) have demonstrated the electrophilic reactivity of selenazoles possessing an hydrazonc in the 2-position and nonsubstituted in the 5-position toward diazonium salt to give 5-phenylazo derivatives preferentially. For example, the main product of the coupling of 2-benzylidene hydrazino-4-phenylselenazole with diazo-o-phenetidine is the 5-(o-ethoxyphenylazo)-selenazole (Scheme 371 ruby red prisms, m.p. 206°C. yield 67"o). A formazan is obtained as by-product. (See Section III.6) (43). 

In conclusion, in terms of electrophilic reactivity a methyl group in the 2-position is equally reactive in the two categories of heterocycles (selenazole and thiazole). Of the two positions ortho to nitrogen, only the 2-position is activated. The 5-position is sensitive to electrophilic reagents and resembles more closely the para position of a benzene ring. 

With respect to thiazole, the selenazole system displays a lesser nucleophilic reactivity in the 2-position and a greater electrophilic reactivity of the 5-position, but undergoes fission of the cycle more easily. 

Alcohol attack generates an unstable intermediate that undergoes nucleophilic attack by CL at carbon. Compare electrostatic potential maps of methanol, thionyl chloride intermediate, and phosphorus trichloride intermediate. What features of these maps are consistent with an electrophilic reactive intermediate ... 

The pyrylium cation possesses, according to the substituents in positions 2, 4, and 6, a more or less pronounced electrophilic reactivity which enables it to add nucleophiles in these positions. According to the nucleophilic reactivity and the carbon basicity " of the anions, an ion pair (a substituted pyrylium cation and an anion halide, perchlorate, sulfate, fluoroborate, chloroferrate, etc.), or a covalently bonded 2H- or 4//-pyran may be formed. With the more basic anions... 

The mechanism for the conversion of the A -oxide (94) to the o-methylaminophenylquinoxaline (96) involves an initial protonation of the A -oxide function. This enhances the electrophilic reactivity of the a-carbon atom which then effects an intramolecular electrophilic substitution at an ortho position of the anilide ring to give the spiro-lactam (98). Hydrolytic ring cleavage of (98) gives the acid (99), which undergoes ready dehydration and decarboxylation to (96), the availability of the cyclic transition state facilitating these processes. ... 

Inspection of the three cations shows that (13) and (14) would be expected to be quito active as electrophilic reagents by reason of delocalization of the positive charge by mesomerism leading to the transfer of electrophilic character to the carbon atom. Cation (12), on the other hand, would show electrophilic reactivity at carbon only by induction. Since neutral pyrrole is so susceptible to electrophilic attack, it is extremely likely that it would react with one or other of the three cations. 

The first question one asks is why does the reaction with 2-methyl-pyrrole stop at the dimer stage, whereas the pyrrole dimer itself cannot be isolated, but reacts further to form the trimer. The answer probably lies in the greater electrophilic reactivity of... 

Because it s much easier to measure the acidity of a substituted benzoic acid than it is to determine the relative reactivity of an aromatic ring toward electrophilic substitution, the correlation between the two effects is useful for predicting reactivity. If we want to know the effect of a certain substituent on electrophilic reactivity, we can simply find the acidity of the corresponding benzoic acid. Worked Example 20.1 gives an example. 

It is appropriate at this juncture to address some of the more useful transformations of 2,3-epoxy alcohols.913 A 2,3-epoxy alcohol such as compound 14 possesses two obvious electrophilic sites one at C-2, and the other at C-3. But in addition, C-l of a 2,3-epoxy alcohol also has latent electrophilic reactivity. For example, exposure of 14 to aqueous sodium hydroxide solution results in the formation of triol 19 in 79% yield (see Scheme 5). In this interesting transformation, hydroxide ion induces the establishment of an equilibrium between 2,3-epoxy-l-ol 14 and the isomeric 1,2-epoxy-3-ol 18. This reversible, base-induced epoxide migration reaction is a process known as the Payne rearrangement.14... 

Glucose- 6-phosphate dehydrogenase Low or absent enzyme activity in about 10% of African populations. Hemolysis following intake of a number of drugs which have electrophilic reactive metabolites, but also, carriers of this enzyme deficiency have a partial protection from malaria. 

This diazotization is typical of many aminoazoles the diazonium ions formed are relatively strong acids. The pATa values of five di-, tri-, and tetrazolediazonium ions are reported to be between 3 and 4, i. e., about 10 units lower (more acidic) than those of the respective unsubstituted heterocycles (Vilarrasa et al., 1974). Therefore, deprotonation of the diazonium ion is easy and, depending on reaction conditions, yields either the diazonium salt or its conjugate base, the diazo compound. The electrophilic reactivity of the P nitrogen atom in the diazo group of the base is lower than the reactivity of the diazonio group of the cation (Diener and Zollinger, 1986 see Sec. 12.2). 

Use of kinetic studies of acylation as a measure of electrophilic reactivities... 

The wide variation in the entropy factors for both the substituted phenyl and heterocyclic compounds and in particular for the methoxyphenyl and furan derivatives was considered to be strong evidence for solvent effects being predominant in determining the activation entropy. Consequently, discussion of the substituent effects in terms of electronic factors alone requires caution in this reaction. Caution is also needed since rates for the substituted phenyl compounds were only determined over a 20 °C range. The significance of entropy factors has also been indicated by the poor correlation of the data of the electrophilic reactivities of the heterocyclic compounds, as derived from protodemercuration, with the data for other electrophilic substitutions and related reactions572. 

Electrophilic reactivity and structure of the coordinated nitrosyl group. J. Masek, Inorg. Chim. Acta, Rev., 1969,3, 99-108 (36). 

A p-PhS02 group enhances the electrophilic reactivity of chlorobenzene towards KOH far more than a p-PhSO group, and the p-isomer is much more reactive than the m-isomer in each group. 

Activated esters of halogenated alcohols, such as 2-chloroethanol, 2,2,2-trifluoroethanol, and 2,2,2-trichloroethanol, have been often used as substrate for enzymatic synthesis of esters, owing to an increase in the electrophilicity (reactivity) of the acyl carbonyl and avoid significant alcoholysis of the products by decreasing the nucleophilicity of the leaving alcohols. ... 

Not only because of their diminished electrophilic reactivity but also because of their propensity to undergo enolization and many other side reactions, nucleophilic alkylation of aliphatic aldehydes often suffers from low yields. Accordingly, the reaction that is successful for aromatic aldehydes is not necessarily successful for aliphatic aldehydes. 

The reaction can be performed in one flask with great operational ease a mixture of an aldehyde and p-anisidine is stirred in THF for 5-10 h at 50 °C. Then, without removing the water produced, Ni(acac)2, isoprene, and Et2Zn are added in this order at room temperature. The mixture is stirred at the same temperature for the period of time indicated (Table 8). The products 57 and 58 are isolated as a mixture by column chromatograph after the usual work-up. Table 8 demonstrates the scope regarding the kind of aldehyde that encompasses not only aromatic aldehydes but also aliphatic aldehydes and even the parent formaldehyde. Despite the diminished electrophilic reactivity of aldimines, the reaction is complete at room temperature within a reasonable reaction time. The reaction of aldimines proceeds in an opposite sense of stereoselectivity to that of aldehydes and selectively provides 1,3-syn isomers 57. 

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