Pyridine electrophilic attack

Bromination of pyridine is much easier than chlorination. Vapour phase bromination over pumice or charcoal has been studied extensively (B-67MI20500) and, as with chlorination, orientation varies with change in temperature. At 300 °C, pyridine yields chiefly 3-bromo-and 3,5-dibromo-pyridine (electrophilic attack), whilst at 500 °C 2-bromo- and 2,6-dibromo-pyridine predominate (free radical attack). At intermediate temperatures, mixtures of these products are found. Similarly, bromination of quinoline over pumice at 300 °C affords the 3-bromo product, but at higher temperatures (450 °C) the 2-bromo isomer is obtained (77HC(32-1)319). Mixtures of 3-bromo- and 3,5-dibromo-pyridine may be produced by heating a pyridine-bromine complex at 200 °C, by addition of bromine to pyridine hydrochloride under reflux, and by heating pyridine hydrochloride perbromide at 160-170 °C (B-67MI20500). 

Pyrazines are more resistant to electrophilic substitution reactions at the ring carbon atoms than the corresponding pyridines. Electrophilic attack normally takes place on the ring nitrogen atoms thus pyrazines form mono- and disalts with proton acids and mono- and... 

In Summary The azanaphthalenes quinoline and isoquinoline may be regarded as benzo-pyridines. Electrophiles attack the benzene ring, nucleophiles attack the pyridine ring. 

Despite its V excessive character (340), thiazole, just as pyridine, is resistant to electrophilic substitution. In both cases the ring nitrogen deactivates the heterocyclic nucleus toward electrophilic attack. Moreover, most electrophilic substitutions, which are performed in acidic medium, involve the protonated form of thiazole or some quaternary thiazolium derivatives, whose reactivity toward electrophiles is still lower than that of the free base. 

The N-oxide function has proved useful for the activation of the pyridine ring, directed toward both nucleophilic and electrophilic attack (see Amine oxides). However, pyridine N-oxides have not been used widely ia iadustrial practice, because reactions involving them almost iavariably produce at least some isomeric by-products, a dding to the cost of purification of the desired isomer. Frequently, attack takes place first at the O-substituent, with subsequent rearrangement iato the ring. For example, 3-picoline N-oxide [1003-73-2] (40) reacts with acetic anhydride to give a mixture of pyridone products ia equal amounts, 5-methyl-2-pyridone [1003-68-5] and 3-methyl-2-pyridone [1003-56-1] (11). 

Pyrazine and quinoxaline fV-oxides generally undergo similar reactions to their monoazine counterparts. In the case of pyridine fV-oxide the ring is activated both towards electrophilic and nucleophilic substitution reactions however, pyrazine fV-oxides are generally less susceptible to electrophilic attack and little work has been reported in this area. Nucleophilic activation generally appears to be more useful and a variety of nucleophilic substitution reactions have been exploited in the pyrazine, quinoxaline and phenazine series. 

The pyrazole molecule resembles both pyridine (the N(2)—C(3) part) and pyrrole (the N(l)—C(5)—C(4) part) and its reactivity reflects also this duality of behaviour. The pyridinic N-2 atom is susceptible to electrophilic attack (Section 4.04.2.1.3) and the pyrrolic N-1 atom is unreactive, but the N-1 proton can be removed by nucleophiles. However, N-2 is less nucleophilic than the pyridine nitrogen atom and N(1)H more acidic than the corresponding pyrrolic NH group. Electrophilic attack on C-4 is generally preferred, contrary to pyrrole which reacts often on C-2 (a attack). When position 3 is unsubstituted, powerful nucleophiles can abstract the proton with a concomitant ring opening of the anion. 

Structures that incorporate the —N = CH— unit, such as pyridine, are rr-deflcient and are deactivated to electrophilic attack. Again, a resonance interpretation is evident. The nitrogen, being more electronegative than carbon, is a net acceptor of n electron density. 

However, treatment of cortisone 3,20-bissemicarbazone with acetic anhydride and pyridine removes the 20-semicarbazone group preferentially. Selective removal of a protecting group can be also achieved by a selective reaction to give a new intermediate which can be converted into the desired product ketone. Thus progesterone 20-monoenol acetate (42) is prepared from the 3,20-bisenol acetate (40) via selective electrophilic attack of iodine at C-6 followed by reductive dehalogenation of (41). ... 

Draw and compare Lewis structures for benzene and pyridine. How many 7C electrons does each molecule have Where are the most accessible electrons in each Display the electrostatic potential map for pyridine and compare it to the corresponding map for benzene. Would you expect electrophilic attack on pyridine to occur analogously to that in benzene If so, should pyridine be more or less susceptible to aromatic substitution than benzene If not, where would you expect electrophilic attack to occur Explain. 

Pyridine is thus referred to as a n-deficient heterocycle and, by analogy with a benzene ring that carries an electron-withdrawing substituent, e.g. N02 (p. 151), one would expect it to be deactivated towards electrophilic attack. Substitution takes place, with difficulty, at the 3-position because this leads to the most stable Wheland intermediate (63) the intermediates for 2- and 4-attack (64 and 65, respectively) each has a canonical state in which the charge is located on divalent N—a highly unstable, i.e. high energy, state ... 

An alternative approach to thienothienopyridines involves intramolecular electrophilic attack at C-3 of the thiophene ring. In this way, the thienothiophene 82 can be cyclized to the benzothieno[2,3-/]thieno[2,3-c]pyridine 83 upon treatment with polyphosphoric acid (PPA) at 150°C (Equation 3). Similarly, treatment of the amide 84 with POCI3 gives the corresponding 1-alkyl-3,4-dihydro-benzothieno[3,2-g]thieno[3,2-f]pyridine 85 <1999PS(153)401> (Equation 4). 

The methyl groups on the pyridine ring result in a major difference in the reactivity of lutidines. In 3,5-lutidine the methyl groups act as electron donors tending to increase the stability of the tt-bonds, and activating the ring for electrophilic attack at the a-positions. The MOs in 3,5-lutidine show the it-levels pushed to lower energy... 

Imidazo[l,5-tf]pyridines are aromatic systems in which the bridgehead nitrogen N-4 contributes to the aromaticity with its lone pair. Therefore, this nitrogen atom is not nucleophilic and electrophilic attacks occur at the N-2 position. SgAr occurs at C-l, but also sometimes at C-3, depending on the conditions used (Figure 3). 

Methyl[l,2,3]diazaphospholo[l,5- ]pyridine 41 undergoes electrophilic attack at N-2 (Scheme 12). Dimethyl sulfate in the absence of nucleophile led to the salt 42, whereas upon treatment with water, protonation of the same atom was followed by nucleophilic attack at phosphorus and consecutive ring opening to produce 43 <1995S173>. 

Diazines are generally resistant to electrophilic attack on carbon, and, as for pyridine, addition on nitrogen is observed. Alkyl halides give mono-quaternary salts di-quatemary salts are not formed under normal conditions. Of conrse, if the diazine ring carries a snbstitnent that makes the starting... 

From the resonance description you might conclude that although the primary site for electrophilic attack is at N-1, reactions at carbon C-3(5) might be possible, even if not as likely. However, an important point to remember is that the N atom of pyridine carries a lone pair of electrons these electrons are NOT part of the jc-system. As a result, pyridine is a base 5.2), reacting with acids, Lewis acids and other electrophiles (E ) to form stable pyridinium salts (Scheme 2.2), in which the heterocycle retains aromatic character. 

Electrophilic addition to 9-vinylcarbazole occurs in the Markovnikov sense, thus hydrogen chloride,hydrogen bromide,chlorine, and bromine in carbon tetrachloride, and iodine chloride in pyridine are recorded as adding with initial electrophilic attack at the methylene. Mercuric acetate in methanol gave 9-(2-acetoxymercuri-l-methoxyethyl)carbazole. Although 9-vinylcarbazole gave an iodohydrin, comparable reaction with methanolic sodium hypochlorite led to 9-(2-chlorovinyl)carbazole. Catalytic reduction of the latter produced 9-(2-chloroethyl)carbazole. Tri-phenyltin hydride gave 96. ... 

A surface for which the electrostatic potential is negative (a negative potential surface) delineates regions in a molecule which are subject to electrophilic attack, for example, above and below the plane of the ring in benzene, and in the ring plane above the nitrogen in pyridine. 

Pyridinones and quinolinones undergo electrophilic attack at the (3 -position (12,13) fairly easily and disubstitution is well known in the pyridine series. Pyridinones are more easily halogenated than benzene, but the highly acidic conditions used for nitration and sulfonation makes these less easy reactions. Electrophiles also attack at the oxygen (14), but this is considered as a substituent reaction and therefore will be dealt with in Chapter 2.06. 

Pyridine 1-oxide is remarkable in that it reacts easily with both electrophiles (as its free base) and nucleophiles. Activation toward electrophilic attack (at C-4) derives from donation of a pair of electrons by the iV-oxide oxygen and the involvement of a relatively stable Wheland intermediate (20) (equation 3). 

In the case of mercuration (soft electrophile), attack at the 2-position is favoured. These observations accord with predictions based on molecular orbital calculations, that hard electrophiles (nitronium ions) should attack at C-4 and soft electrophiles (e.g. HgS04) at C-2 (68JA223). Furthermore, very hard electrophiles (e.g. S03) are predicted to attack at C-3. This is hard to verify because pyridine 1-oxide reacts at C-3 as its conjugate acid (or... 

A few years ago an old reaction, that of the thermal decomposition of arylsulfonyl azides in pyridines, was re-examined (Scheme 42) (72JOC2022). Among the products identified was the 3-phenylsulfonamido derivative (96), which was proposed to arise by an electrophilic attack by phenylsulfonylnitrene. 

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