Intramolecular electrophilic aromatic substitutions

The selectivity relationship merely expresses the proportionality between intermolecular and intramolecular selectivities in electrophilic substitution, and it is not surprising that these quantities should be related. There are examples of related reactions in which connections between selectivity and reactivity have been demonstrated. For example, the ratio of the rates of reaction with the azide anion and water of the triphenylmethyl, diphenylmethyl and tert-butyl carbonium ions were 2-8x10 , 2-4x10 and 3-9 respectively the selectivities of the ions decrease as the reactivities increase. The existence, under very restricted and closely related conditions, of a relationship between reactivity and selectivity in the reactions mentioned above, does not permit the assumption that a similar relationship holds over the wide range of different electrophilic aromatic substitutions. In these substitution reactions a difficulty arises in defining the concept of reactivity it is not sufficient to assume that the reactivity of an electrophile is related... 

Detailed mechanistic studies by Fodor demonstrated the intermediacy of both imidoyl chlorides (6) and nitrilium salts (7) in Bischler-Napieralski reactions promoted by a variety of reagents such as PCI5, POCI3, and SOCh)/ For example, amide 1 reacts with POCI3 to afford imidoyl chloride 6. Upon heating, intermediate 6 is converted to nitrilium salt 7, which undergoes intramolecular electrophilic aromatic substitution to afford the dihydroisoquinoline 2. Fodor s studies showed that the imidoyl chloride and nitrilium salt intermediates could be generated under mild conditions and characterized spectroscopically. Fodor also found that the cyclization of the imidoyl chlorides is accelerated by the addition of Lewis acids (SnCU, ZnCh), which provides further evidence to support the intermediacy of nitrilium salts. ... 

A more practical solution to this problem was reported by Larson, in which the amide substrate 20 was treated with oxalyl chloride to afford a 2-chlorooxazolidine-4,5-dione 23. Reaction of this substrate with FeCL affords a reactive A-acyl iminium ion intermediate 24, which undergoes an intramolecular electrophilic aromatic substitution reaction to provide 25. Deprotection of 25 with acidic methanol affords the desired dihydroisoquinoline products 22. This strategy avoids the problematic nitrilium ion intermediate, and provides generally good yields of 3-aryl dihydroisoquinolines. 

Intramolecular electrophilic aromatic substitution to give tricyclic products 142 is also a viable process, with trapping efficiency related to the electron density of the arene trap (equation 3)67. With a simple phenyl group pendant, rearrangement to the 2-pyrone was... 

Presumably, the oxidative cyclization of 3 commences with direct palladation at the a position, forming o-arylpalladium(II) complex 5 in a fashion analogous to a typical electrophilic aromatic substitution (this statement will be useful in predicting the regiochemistry of oxidative additions). Subsequently, in a manner akin to an intramolecular Heck reaction, intermediate 5 undergoes an intramolecular insertion onto the other benzene ring, furnishing 6. (i-Hydride elimination of 6 then results in carbazole 4. 

Thus /i-carbolincs can be obtained in a tandem hydroformylation/Pictet-Spengler-type intramolecular electrophilic aromatic substitution of polymer bound olefins (Scheme 26) [80]. 

In a similar fashion, hydroformylation of N-allyl-pyrrols leads to 5,6-dihydroindolizines via a one-pot hydroformylation/cyclization/dehydration process (Scheme 27) [81,82]. The cyclization step represents an intramolecular electrophilic aromatic substitution in a-position of the pyrrole ring. This procedure was expanded to various substrates bearing substituents in the al-lyl and in the pyrrole unit. 

Dibenzo[f,. ]cinnolines 259 have been obtained from 2-naphthylanilines 258 via diazotization followed by intramolecular electrophilic aromatic substitution (Equation 65) <2003BMC1475>. 

A nucleophilic attack of an N-tethered phenethyl substituent is shown in Scheme 50. The protonated thiazine ring brings about an intramolecular electrophilic aromatic substitution on the aryl substituent, whether this is a phenyl <1992CHE832> or a veratryl ring <1980JHC449>. 

An equally important general type of synthesis which proceeds via heterocyclization with formation of a ring bond y to the heteroatom involves acid-catalyzed intramolecular electrophilic aromatic substitution, especially those in which a carbonyl group functions as the electrophile. The most common structural requirements are summarized in (18)-(2l) ... 

By far the most common methods for the preparation of dibenzoselenophenes and 2-benzoselenophenes, like the synthesis of 1-benzoselenophenes, rely upon the annulation of the heterocyclic ring system onto a preformed benzene ring and mostly involve the formation of one or two Se-C bonds as their key steps, with only a few exceptions [1, 119, 120], Intramolecular electrophilic aromatic substitution of biphenyl-2-yl trifluoromethylselenide to 5-(trifluoromethyl)dibenzoselenopheni um triflate (62) [99, 143] and synthesis of tetramethoxydibenzoselenophene (95) (Scheme 26) [144, 145] are examples. 

Comparison of results from the gas-phase proton-induced unimolecular isomerization of (R)- -d -3-(p-fluorophcnyl )bulanc (11) with the positional selectivity of the corresponding gas-phase bimolecular arene alkylation confirms the presence of non-covalent j-type intermediates and their important role in determining the intramolecular selectivity of gas-phase electrophilic aromatic substitutions.20... 

Again, % electrons are involved, but the reaction is now electrophilic aromatic substitution (Chapter 22) rather like an intramolecular Friedel-Crafts alkylation with a delocalized intermediate often termed a phenonium ion. 

The imine salt is perfectly placed for an intramolecular electrophilic aromatic substitution by the electron-rich dihydroxyphenyl ring. This closes the isoquinoline ring in a Mannich-like process (Chapter 27) with the phenol replacing the enol in the pyrrolidine alkaloid biosynthesis. 

Electrophilic aromatic substitution also occurs intramolecularly to generate polymers with indanyl end groups [Eq, (93)] entropy strongly favors this unimolecular reaction. 

Participation by aromatic rings is also possible and there are now several examples of electrophilic aromatic substitution involving Pummerer intermediates. Equation (20), the alkylation of benzene with dimethyl sulfoxide in trifluoroacetic anhydride, illustrates the process in its simplest form. As with al-kenes, reaction with aromatics has been more widely exploited in intramolecular versions for the construction of carbocycles and heterocycles. In many cases the sulfoxide precursor is of the P-keto variety, thus ensuring regiospecificity in the point of cyclization. Equation (21) (formation of a six-member carbocycle), equation (22) (foimation of a six-membered sulfur heterocycle), equation (23) (formation of a six-membered nitrogen heterocycle) and equation (24) (foimation of a seven-membered nitrogen, sulfur heterocycle) provide illustrations of the versatility of this form of intramolecular aromatic alkylation. 

Treatment of P3C3Bu 3 with [(CO)sW <—PMe], generated / si/u by thermal decomposition of 56b (R = Ph) at 110°C, furnished a 2 1 mixture of quadricyclane 58b and the tricyclic compound 59, which were separated by fractional crystallization as colorless or yellow crystals in 39% and 25% yield, respectively. The presence of a three-membered ring in 59 agrees with an initial attack of the phosphinidene complex at a P=C bond of the triphosphinine to give transient 60. An intramolecular electrophilic aromatic substitution furnished product 59, whereas rearrangement of 60 to tetraphosphanorbornadiene 57a and its intramolecular [2+2] cycloaddition would rationalize the formation of 58b (Scheme 22) <2001CEJ3545>. 

Example 4.21. A metal-catalyzed, intramolecular, electrophilic aromatic substitution. 

Similar intramolecular electrophilic aromatic substitution reactions are common, especially when five- or six-membered rings are formed. 

SCHEME 7.27 C-Glycosidation via intramolecular electrophilic aromatic substitutions. 

Oxidation of benzoylacetanilide in MeCN gives a good yield of 2,4-dioxo-l-phenyl-1,2,3,4-tetrahydroquinoline. The reaction is reported to be an intramolecular coupling between an amidyl radical and the radical cation of the benzoyl group [83], but an electrophilic aromatic substitution by the amidyl cation or an addition of the amidyl radical to the phenyl ring (followed by an oxidation) could also be considered. 

With Mn(OAc)3, generated by oxidation of Mn(OAc)2 as mediator, a tandem reaction consisting of an intermolecular radical addition followed by an intramolecular electrophilic aromatic substitution can be accomplished [Eq. (21b)] [225b]. Further Mn(III)-mediated additions of 1,3-dicarbonyl compound to olefins are shown in Table 11 (numbers 8b,c, and 9a). Mediated by in situ generated Mn(III), methyl dibromoacetate, trichloro-bromomethane, perfluoroctyl iodide, dimethyl bromomalonate, and active methylene compounds have been added via radicals to olefins [225d]. 

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