Benzenoid rings

Ha.logena.tlon, One review provides detailed discussion of direct and indirect methods for both mono- and polyhalogenation (20). As with nitration, halogenation under acidic conditions favors reaction in the benzenoid ring, whereas reaction at the 3-position takes place in the neutral molecule. Radical reactions in the pyridine ring can be important under more vigorous conditions. 

Substituents on benzene or benzenoid rings in fused pyridazines, i.e. in cinnolines and phthalazines, usually exhibit reactivity which is similar to that found in the correspondingly substituted fused aromatic compounds, such as naphthalene, and is therefore not discussed here. 

When activating substituents are present in the benzenoid ring, substitution usually becomes more facile and occurs in accordance with predictions based on simple valence bond theory. When activating substituents are present in the heterocyclic ring the situation varies depending upon reaction conditions thus, nitration of 2(177)-quinoxalinone in acetic acid yields 7-nitro-2(177)-quinoxalinone (21) whereas nitration with mixed acid yields the 6-nitro derivative (22). The difference in products probably reflects a difference in the species being nitrated neutral 2(177)-quinoxalinone in acetic acid and the diprotonated species (23) in mixed acids. 

Conflicting reports on the nitration of phenazine have appeared, but the situation was clarified by Albert and Duewell (47MI21400). The early work suggested that 1,3-dinitroph-enazine could be prepared in 66% yield under standard nitration conditions however, this proved to be a mixture of 1-nitrophenazine and 1,9-dinitrophenazine (24). As with pyrazines and quinoxalines, activating substituents in the benzenoid rings confer reactivity which is in accord with valence bond predictions thus, nitration of 2-methoxy- or 2-hydroxy-phenazine results in substitution at the 1-position. 

The reactions of haloquinoxalines in which the halogen atom is bonded to the benzenoid ring have not been well studied, but by analogy with examples in the phenazine series it would seem probable that they are unlikely to be displaced with the same ease as those bonded directly to the heterocyclic ring. It is evident from the foregoing discussion that A-oxidation has a pronounced effect on their reactivity, and, by this means, considerable latitude in the specific functionalization of dihalo or polyhalo derivatives may be exercised. 

The fusion of a benzene ring to pyrazine results in a considerable increase in the resistance to reduction and it is usually difficult to reduce quinoxalines beyond the tetrahydroquinoxa-line state (91). Two possible dihydroquinoxalines, viz. the 1,2- (92) and the 1,4- (93), are known, and 1,4-dihydroquinoxaline appears to be appreciably more stable than 1,4-dihydropyrazine (63JOC2488). Electrochemical reduction appears to follow a course anzdogous to the reduction of pyrazine, giving the 1,4-dihydro derivative which isomerizes to the 1,2- or 3,4-dihydroquinoxaline before subsequent reduction to 1,2,3,4-tetra-hydroquinoxaline (91). Quinoxaline itself is reduced directly to (91) with LiAlH4 and direct synthesis of (91) is also possible. Tetrahydroquinoxalines in which the benzenoid ring is reduced are well known but these are usually prepared from cyclohexane derivatives (Scheme 30). 

Annelation increases the complexity of the spectra just as it does in the carbocyclic series, and the spectra are not unlike those of the aromatic carbocycle obtained by formally replacing the heteroatom by two aromatic carbon atoms (—CH=CH—). Although quantitatively less marked, the same trend for the longest wavelength band to undergo a bathochromic shift in the heteroatom sequence O < NH < S < Se < Te is discernible in the spectra of the benzo[Z>] heterocycles (Table 17). As might perhaps have been anticipated, the effect of the fusion of a second benzenoid ring on to these heterocycles is to reduce further the differences in their spectroscopic properties (cf. Table 18). The absorption of the benzo[c]... 

In general, substituents removed from the ring by two or more saturated carbon atoms undergo normal aliphatic reactions, and substituents attached directly to fused benzene rings or aryl groups undergo the same reactions as do those on normal benzenoid rings. 

In compounds with a fused benzene ring, electrophilic substitution on carbon usually occurs in the benzenoid ring in preference to the heterocyclic ring. Frequently the orientation of substitution in these compounds parallels that in naphthalene. Conditions are often similar to those used for benzene itself. The actual position attacked varies compare formulae (341)-(346) where the orientation is shown for nitration sulfonation is usually similar for reasons which are not well understood. 

Alkyl groups attached to heterocyclic systems undergo many of the same reactions as those on benzenoid rings. 

Protons of substrueture B and C are assigned by means of the mesomerie effeet of the aldehyde group whieh deshields the protons in o-position of the attaehed p-disubstituted benzenoid ring and in p-position of the eentral CC double bond ort/io-protons of the monosubstituted benzenoid ring D split into a doublet beeause of one ortho eoupling ( 7.5 Hz) while the meta-protons split into a triplet beeause of two ortho eouplings. 

The C NMR spectrum of the metabolite shows 16 signals instead of 8 as expected from the elemental composition determined by high-resolution mass spectrometry. Moreover, aromaticity of the 2,6-xylenol is obviously lost after metabolism because two ketonic carbonyl carbon atoms (5c = 203.1 and 214.4) and four instead of twelve carbon signals are observed in the shift range of trigonal carbon nuclei (5c = 133.1, 135.4, 135.6 and 139.4) in the C NMR spectra. To conclude, metabolism involves oxidation of the benzenoid ring. 

Both phenanthrene and anthracene have a tendency to undergo addition reactions under the eonditions involved in eertain eleetrophilic substitutions. For example, in the nitration of anthracene in the presence of hydrochloric acid, an intermediate addition product can be isolated. This is a result of the relatively close balance in resonance stabilization to be regained by elimination (giving an anthracene ring) or addition (resulting in two benzenoid rings). 

Building-block rings (e.g. benzenoid) which are terminal are not disconnected central benzenoid rings in a polycyclic system may be eligible for disconnection especially if adjacent rings are benzenoid or not readily disconnectible. 

The reduction of a benzenoid ring, except in benzoic acid derivatives, occurs only in the presence of a proton donor having a pKa of 19 or less (pKa of ammonia is about 33). With the exception of the vinyl group, the other functional groups listed above do not require a proton donor of this acidity in order to be reduced, although the course of reduction may then be complex, e.g. as with esters. " Consequently, a variety of functional groups should be capable of selective reduction in the presence of a benzenoid ring if the reaction medium does not contain an acid of pKa <19. A few examples of such selective reductions have been reported in the steroid literature. 

The chemical reactions of 3-aminopyridines, 3-aminoquinoIines, etc. in which the amino group is beta to the hetero atom or is attached to a benzenoid ring are similar to those of aniline (cf. references 282, 290), and it has been generally accepted that these compounds exist overwhelmingly in the amino form. 2-Aminoacridine was not considered to exist as 231 (R = H), because 231 (R Me) shows reac-... 

Similar problems arise with the four isomeric dibenzazepines 4-7. since only 5//-dibenz-[6,d]azepine (4) and 5//-dibenz[/>,./]azepine (7) can be drawn as fully benzenoid ring structures. Even so, 5//-dibenz[/ ,t/]azepines are rare and are known only as the 7-oxo derivatives.4 In contrast, 5//-dibenz[6,e azepine (5) and 6//-dibenz[r,t>]azepine (6) exist only as the 11//- 5a and 5H- 6a isomers, respectively. In fact, there is no chemical or spectrosopic evidence for the isomerization of 5//-dibenz[e,e]azepine,5 or its 6-oxide,6 to the 6//-dibenz[r, e]azcpinc isomer (6). In addition, an X-ray crystal structure of 7-methoxy-5//-dibenz[e,e]azepine supports unequivocally the benzenoid rather than the quinonoid form.7 9//-Tribenz[6,d /]azepine (8) has only recently been prepared.8... 

The greater intensity of the band of the metabolite at 220 mis probably due to the presence of a second, superimposed chromophore which could also account for the shift of the minimum. On the other hand, the band near 300 m/u. has the expected intensity. Its broadness and displacement towards longer wavelength are probably due to the presence of a substituent on the double bond or benzenoid ring. That the assignment to a coumaroyl chromophore is essentially correct is evidenced by the fact that both M and the model compound underwent the same type of reaction on irradiation in the near-ultraviolet (Figure 4). The observed isosbestic points imply that the photoreaction is a simple one, such as A -> B or A = B, and is obviously the well-known light-induced trans- to c/r-isomerization (7) of cinnamic acid derivatives. 

The photolytic degradation of the fluoroquinolone enrofloxacin involves a number of reactions that produce 6-fluoro-7-amino-l-cyclopropylquinolone 2-carboxylic acid that is then degraded to CO2 via reactions involving fission of the benzenoid ring with loss of fluoride, dealkylation, and decarboxylation (Burhenne et al. 1997a,b) (Figure 1.9). 

The enzymes from Comamonas testosteroni for hydroxylation of quinoline to quinol-2-one (quinoline 2-oxidoreductase) and the dioxygenase responsible for the introduction of oxygen into the benzenoid ring (2-oxo-l,2-dihydroquinoline 5,6-dioxygenase) have been described (Schach et al. 1995). 

White or colored gels are obtained with poly (vinyl alcohol) 26), by using the water-soluble salt of an aromatic amide where the hydroxy and carbonyl groups of the amide are attached to the same benzenoid ring. Several such compounds are illustrated in Figure 3. 

Unstable dienes can be generated in situ in the presence of a dienophile. Among the most useful examples are the orf/ioquinodimethanes. These compounds are exceedingly reactive as dienes because the cycloaddition reestablishes a benzenoid ring and results in aromatic stabilization.51... 

The active component of a carrier formulation is generally a nonionic compound of Mr 150-200 containing a benzenoid ring system. A comprehensive review listed the classes of compounds used together with their general properties, ideal requirements and the mechanisms that have been proposed for carrier action [115]. Carrier compounds fall into four main classes phenols, primary arylamines, aryl hydrocarbons and aryl esters. Major... 

Synthetic routes to the benzocyclazines are analogues of those which lead to the cyclazines themselves. Representatives of the benzoh ]cycl[3.2.2]azine (indolizi no [3,4,5- ] isoindole, 365) ring system result from cycloaddition of, for example, DMAD to pyrido[2,l-tf]isoindole-6-carbonitrile 370 <1986H(24)3071> (Scheme 100). An alternative synthesis, which starts from the cyclazine 371 and involves construction of the additional benzenoid ring by a double Horner-Wadsworth-Emmons type of reaction, apparently gives the tetracyclic product 365 in only very low yields (Scheme 101) <1988H(27)2251>. 

Thus, although the initial X-ray study of Cotton, Dollase and Wood (21) was interpreted (22) in terms of a uniform C—C distance and an overall D6h symmetry, Jellinek (23, 24) concluded from his crystallographic data that the benzenoid rings showed alternating C—C bond lengths, with an effective symmetry no higher thanZ)3d. Finally however more accurate low temperature crystal data due to Keulen and Jellinek (25), and electron diffraction measurements by Haoland (26) showed conclusively that bis-benzenechromium has in fact sixfold, D6h, symmetry in both crystal and the gas phase. 

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