Other Carbocyclic Aromatic Compounds

Other Carbocyclic Aromatic Compounds Reduction of Carbocyclic Rings... 

Aromatic chemistry, in terms of the production of derivatives of benzene and, to a less extent, other carbocyclic aromatic compounds, is of immense industrial importance and is the mainstay of many chemical companies. Derived products are in general use across such diverse industries as pharmaceuticals, dyestuffs, and polymers. 

In many ways, the electron-rich five-membered aromatic heterocycles behave very much like carbocyclic aromatic compounds when it comes to lithiation. Lithiation a to O or S of furan and thiophene is straightforward (Scheme 130) . The usual selection of orf/io-directing groups allows lithiation at other positions and some examples... 

Among the photochemical reactions of aromatic compounds, the photocycloadditions are most frequently applied to the synthesis of complex polycyclic compounds [6, 9]. The [2+3] or meta photocycloaddition of aromatic compounds and alkenes is the most prominent example [10]. This transformation also demonstrates complementarities between photochemical and ground state reactions since such reactions are almost impossible using conventional activation. A [2+2] ot ortho photocycloaddition between carbocyclic aromatic compounds and alkenes is observed as well. It is often competitive with other cycloaddition modes, in particular the [2+3] mode [11]. Many of these reactions are reversible, and photostationary equilibria are involved. This reaction was much less applied to organic synthesis. Recently, it was found that an acidic reaction medium may have an influence on the outeome of the reaction. The intramolecular photocycloaddition of resorcinol derivatives such as 1 is difficult due to its reversibility (Scheme 29.1). However, in an acidic reaction medium, the cycloadducts 2a,b are protonated at the oxygen atom of the tetrahydrofuran moiety... 

The crucial structural feature which underlies the aromatic character of benzenoid compounds is of course the cyclic delocalised system of six n-electrons. Other carbocyclic systems similarly possessing this aromatic sextet of electrons include, for example, the ion C5Hf formed from cyclopentadiene under basic conditions. The cyclopentadienide anion is centrosymmetrical and strongly resonance stabilised, and is usually represented as in (7). The analogous cycloheptatrienylium (tropylium) cation (8), with an aromatic sextet delocalised over a symmetrical seven-membered ring, is also demonstrably aromatic in character. The stable, condensed, bicyclic hydrocarbon azulene (Ci0H8) possesses marked aromatic character it is usually represented by the covalent structure (9). The fact that the molecule has a finite dipole moment, however, suggests that the ionic form (10) [a combination of (7) and (8)] must contribute to the overall hybrid structure. 

The purpose of present review is to summarize the application of different classes of iodine(III) compounds in carbon-carbon bond forming reactions. The first two sections of the review (Sects. 2 and 3) discuss the oxidative transformations induced by [bis(acyloxy)iodo] arenes, while Sects. 4 through 9 summarize the reactions of iodonium salts and ylides. A number of previous reviews and books on the chemistry of polyvalent iodine discuss the C-C bond forming reactions [1 -10]. Most notable is the 1990 review by Moriarty and Vaid devoted to carbon-carbon bond formation via hypervalent iodine oxidation [1]. In particular, this review covers earlier literature on cationic carbocyclizations, allyla-tion of aromatic compounds, coupling of /1-dicarbonyl compounds, and some other reactions of hypervalent iodine reagents. In the present review the emphasis is placed on the post 1990s literature. 

Another isomerization reaction of arene oxides is equilibrium with oxe-pins [5], Here, the fused six-membered carbocycle and three-membered oxirane merge to form a seven-membered heterocycle, as shown in Fig. 10.2. An extensive computational and experimental study involving 75 epoxides of monocyclic, bicyclic, and polycyclic aromatic hydrocarbons has revealed much information on the structural factors that influence the reaction rate and position of equilibrium [11], Thus, some compounds were stable as oxepins (e.g., naphthalene 2,3-oxide), while others exhibited a balanced equilibrium... 

The C-2 and C-3 hydroxy derivatives of pyrrole are special in the sense that the tautomeric equilibria favor the pyrrolinone structures (see Section 3.04.6.2). Furthermore, the general synthetic methods are not usually applicable so that we will call attention in this section not only to the methods of directly introducing these substituents, which are rare, but also to those ring construction processes which specifically give the pyrrolinones and indolinones. The indole derivatives have widely used trivial names, oxindole (5) for indolin-2-one and indoxyl (6) for indolin-3-one, Carbocyclic hydroxy substituents in indole and carbazole, on the other hand, for the most part act as normal aromatic phenolic groups. These compounds are usually prepared by application of the standard ring syntheses. 

Many 1,2,3-selenadiazoles have been prepared as intermediates for the ultimate preparation of other organic compounds or for biological activity evaluation [6], The most general, extensively applied method is based on the oxidation of semicar-bazones, mostly derived from aromatic and carbocyclic ketones, by selenium dioxide [6, 14, 188-191], Synthesis of 4-(2-naphthyl)-l,2,3-selenazole (117) from semicarbazone (116) is an example (Scheme 36). 

Several other important compounds found in the common aromatic amino acid pathway whose overproduction has been studied are shikimic acid (61) and, to a lesser extent, quinic acid (62) (Scheme 19.41).323 Both 61 and 62 are naturally occurring, highly functionalized carbocyclic rings with asymmetric centers, which can be used as starting material for the synthesis of GS4104 (63), a neuraminidase inhibitor discovered by Gilead Sciences and developed by Roche Pharmaceuticals under the trade name of Tamiflu .324 325 Manipulation of the aromatic amino acid pathway in E. coli has allowed for numerous strains to be assembled that produce both 61 and 62 as well as other intermediates.326 327 As reported by Chandran and co-workers, an E. coli strain has been constructed that synthesized 87 g/L (0.5m) of 61 in 36% (mol/mol) yield with a maximum productivity of 5.2 gL- lr1.328... 

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