Intramolecular electrophilic induced

Benzo-fused pyridopyrrolizines can be prepared by an acid-induced cyclodehydration of the appropriately substituted hydroxypyrrolopyridines. In the case of 124 (Equation 7), this is best rationalized as an intramolecular electrophilic substitution at the o-carbon of the benzyl substituent <1988CC623, 1990J(P1)1757, 2001J(P1)1446>. 

Intramolecular electrophilic cyclization of methyl selenoate gives only a 12% yield of benzo[/]pyrrolo[2,l- ][l,3]thiazepin-9(10H)-one 285, while cyclization of an acetate derivative under a variety of the conditions failed (Scheme 61 (1998JMC3763)). An alternate route from pyrrole ketones 286 by oxidation and TFAA induced cyclization proved to be advantageous providing a 40% yield of 285. 

The electrophile-induced cyclization of heteroatom nucleophiles onto an adjacent alkene function is a common strategy in heterocycle synthesis (319,320) and has been extended to electrophile-assisted nitrone generation (Scheme 1.62). The formation of a cyclic cationic species 296 from the reaction of an electrophile (E ), such as a halogen, with an alkene is well known and can be used to N-alkylate an oxime and so generate a nitrone (297). Thus, electrophile-promoted oxime-alkene reactions can occur at room temperature rather than under thermolysis as is common with 1,3-APT reactions. The induction of the addition of oximes to alkenes has been performed in an intramolecular sense with A-bromosuccinimide (NBS) (321-323), A-iodosuccinimide (NIS) (321), h (321,322), and ICl (321) for subsequent cycloaddition reactions of the cyclic nitrones with alkenes and alkynes. 

Manganese(III) can oxidize carbonyl compounds and nitroalkanes to carboxy-methyl and nitromethyl radicals [186]. With Mn(III) as mediator, a tandem reaction consisting of an intermolecular radical addition followed by an intramolecular electrophilic aromatic substitution can be accomplished [186, 187). Further Mn(III)-mediated anodic additions of 1,3-dicarbonyl and l-keto-3-nitroalkyl compounds to alkenes and alkynes are reported in [110, 111, 188). Sorbic acid precursors have been obtained in larger scale and high current efficiency by a Mn(III)-mediated oxidation of acetic acid acetic anhydride in the presence of butadiene [189]. Also the nitromethylation of benzene can be performed in 78% yield with Mn(III) as electrocatalyst [190]. A N03 radical, generated by oxidation of a nitrate anion, can induce the 1,4-addition of aldehydes to activated olefins. NOj abstracts a hydrogen from the aldehyde to form an acyl radical, which undergoes addition to the olefin to afford a 1,4-diketone in 34-58% yield [191]. 

The second set of examples involves the use of thionium ions as electrophiles in inter- and intramolecular processes to obtain a-substituted sulfides (see 24 25, Scheme 20.7T which is the most common type of Pummerer reaction. Applications of this classical Pummerer rearrangement are exemplified in the synthesis of trans-solamin, the synthesis of indolizidine alkaloids, and the synthesis of the CDE ring of erinacine E. The first exanple fScheme 20.10 uses Pummerer chemistry in the generation of a thionium ion, which reacts in an intermolecular tin-mediated ene reaction the second one fScheme 20.11 uses Pummerer chemistry to introduce a nitrogen-containing heterocycle by intramolecular addition to form the coniceine core and the third example fScheme 20.12 is an intramolecular silicon-induced Pummerer reaction with oxygenated nucleophiles applied to the synthesis of a precursor of erinacine. Details of these Pummerer-based strategies are discussed below. 

A final type of oxidative carbon-carbon bond forming dearomatization process involves electrophile-induced dearomatization. The most common variant of this reaction entails activation of an alkyne or alkene moiety with an electrophilic halide source to initiate intramolecular dearomatization accompanied by formal arene oxidation (Scheme 15.26) [72]. Proper positioning of an electron-donating methoxy group is crucial for success of this transformation. Other examples of halocyclization-dearomatization reactions involving appropriately substituted arenes tethered to alkynes and alkenes have been reported, along with an intramolecular Pummerer-type dearomatization initiated by an electrophilic thionium ion [73, 74]. 

The ease of adduct formation depends largely on the electron density on the N atom of the imine and the electrophilicity of the center carbon atom of the isocyanate. Most reactive are persubstituted guanidines and amidines on one side and aryl isocyanates with electron withdrawing substituents on the other side. The initial attack occurs on the more nucleophilic center. Delocalization of the developing charges favors intermolecular [2-I-2-I-2] cycloaddition over intramolecular [2-1-2] cycloaddition or the exchange reaction. When a hydrogen shift can occur, the intramolecular isocyanate induced enurea reaction is faster than the intermolecular [2-I-2-I-2] cycloaddition reaction. Thermodynamically controlled equilibria are established above 100 °C and the thermodynamically more stable reaction product is isolated. 

The intramolecular Michael addition11 of a nucleophilic oxygen to an a,/ -unsaturated ester constitutes an attractive alternative strategy for the synthesis of the pyran nucleus, a strategy that could conceivably be applied to the brevetoxin problem (see Scheme 2). For example, treatment of hydroxy a,/ -unsaturated ester 9 with sodium hydride furnishes an alkoxide ion that induces ring formation by attacking the electrophilic //-carbon of the unsaturated ester moiety. This base-induced intramolecular Michael addition reaction is a reversible process, and it ultimately affords the thermodynamically most stable product 10 (92% yield). 

The selectivity for two-alkyne annulation can be increased by involving an intramolecular tethering of the carbene complex to both alkynes. This was accomplished by the synthesis of aryl-diynecarbene complexes 115 and 116 from the triynylcarbene complexes 113 and 114, respectively, and Danishefsky s diene in a Diels-Alder reaction [70a]. The diene adds chemoselectively to the triple bond next to the electrophilic carbene carbon. The thermally induced two-alkyne annulation of the complexes 115 and 116 was performed in benzene and yielded the steroid ring systems 117 and 118 (Scheme 51). This tandem Diels-Alder/two-alkyne annulation, which could also be applied in a one-pot procedure, offers new strategies for steroid synthesis in the class O—>ABCD. 

The reaction described above can also be carried out at higher concentration whereby the probability of intramolecular reaction (cyclization) vanishes. So called chain extension processes result from the stoichiometric reaction of a "living" bifunctional precursors with an efficient bifunctional electrophilic deactivator. This polycondensation reaction induces a very large increase of the molecular weight, but is also results in an enhanced polydispersity. - Fractionation is necessary if well defined substances are required. However the average distance between successive hinges along the chain fluctuates only very little. 

This hydroxylation-induced intramolecular migration, known as the NIH shift, was explained by the involvement of arene oxides formed by the attack of electrophilic oxoiron(V) porphyrin on the aromatic ring.753 Intermediate 98 was also suggested to be formed in hydroxylation by the Fenton and related reagents in aprotic media after initial oxidation with an oxoiron(V) complex followed by electron transfer.744 754... 

Electrophilic ring closure of aryl-substituted compounds such as alkenes, halides, alcohols, and carbonyl compounds called cyclialkylation can be induced by conventional Friedel-Crafts catalysts309 and by superacids. Examples are also known in which an intermolecular alkylation step is followed by intramolecular alkylation of the intermediate to furnish a cyclic product. 

Doubly acceptor-activated imines with an intramolecular alkene moiety such as 29 can cyclize according to an electrophilic mechanism to give pyrrolidine, piperidine or azepine derivatives. This reaction is induced by stoichiometric amounts of Lewis acids, preferably trialkylsilyl triflates [38]. In certain cases FeCl3 can also be used, for example for the preparation of azepinolactone 30 from imine 29 (Scheme 8.10) [39]. Catalytic amounts of FeCl3 are required for the addition of diethyl phosphite to an... 

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