Quinoline nucleophilic aromatic substitution

Recently37, the importance of CT complexes in the chemistry of heteroaromatic N-oxides has been investigated in nucleophilic aromatic substitutions. Electron acceptors (tetracyanoethylene and p-benzoquinones) enhance the electrophilic ability of pyridine-N-oxide (and of quinoline-N-oxide) derivatives by forming donor-acceptor complexes which facilitate the reactions of nucleophiles on heteroaromatic substrates. 

Chloropyrazolo[3,4- ]quinoline, 3-chloropyrazolo[3,4-acid-induced nucleophilic aromatic substitution (SnH) of H-3 in A -hydroxypyrazolo[3,4-first cases of nucleophilic aromatic substitution of a fused pyrazole <2002JOC585>. 

Nucleophilic aromatic substitution of hydrogen in syntheses of quinoline derivatives 01H(54)445. 

If the aromatic moiety of a cinnamylamine derivative has an ort/io-halogen substituent, 1,2-dihydroquinoline would be obtained yia the subsequent S Ar reaction. In the presence of catalytic amounts of tosylamide, MBH adduct 603 was rearranged to the thermodynamically more stable tosylamide derivative, which then could be easily subjected to nucleophilic aromatic substitution reaction at the ortho position, giving 1,2-dihydroquinoline 605 in 81% yield. Furthermore, using DBU as a base, elimination of p-toluenesulfinic acid afforded quinoline 606 in 69% yield (Scheme 4.178). However, interestingly, Xn-substituted MBH adducts 607 were directly converted into quinolines 608 in a one-pot reaction in moderate yields. The discrepancy between 604 and 607... 

Perfluoroarenes were also found to be highly reactive coupling partners in intermolecular direct arylation [68, 69]. A wide range of aryl halides can be employed, including heterocycles such as pyridines, thiophenes, and quinolines. A fluorinated pyridine substrate may also be cross-coupled in high yield and it was also found that the site of arylation preferentially occurs adjacent to fluorine substituents when fewer fluorine atoms are present. Interestingly, the relative rates established from competition studies reveal that the rate of the direct arylation increases with the amount of fluorine substituents on the aromatic ring. In this way, it is inversely proportional to the arene nucleophilicity and therefore cannot arise from an electrophilic aromatic substitution type process (Scheme 7). 

The azanaphthalenes (benzopyridines) quinoline and isoquinoline contain an electron-poor pyridine ring, susceptible to nucleophilic attack, and an electron-rich benzene ring that enters into electrophilic aromatic substitution reactions, usually at the positions closest to the heterocyclic unit. 

These systems nitrate aromatie eompounds by a proeess of electro-philie substitution, the eharacter of whieh is now understood in some detail ( 6.1). It should be noted, however, that some of them ean eause nitration and various other reactions by less well understood processes. Among sueh nitrations that of nitration via nitrosation is especially important when the aromatic substrate is a reactive one ( 4.3). In reaetion with lithium nitrate in aeetie anhydride, or with fuming nitrie aeid, quinoline gives a small yield of 3-nitroquinoline this untypieal orientation (ef. 10.4.2 ) may be a eonsequenee of nitration following nucleophilic addition. ... 

A variety of aryl systems have been explored as substrates in the Knorr quinoline synthesis. Most notable examples are included in the work of Knorr himself who has demonstrated the high compatibility of substituted anilines as nucleophilic participants in that reaction. In the case of heteroaromatic substrates however, the ease of cyclization is dependent on the nature and relative position of the substituents on the aromatic ring." For example, 3-aminopyridines do not participate in ring closure after forming the anilide... 

To derive the maximum amount of information about intranuclear and intemuclear activation for nucleophilic substitution of bicyclo-aromatics, the kinetic studies on quinolines and isoquinolines are related herein to those on halo-1- and -2-nitro-naphthalenes, and data on polyazanaphthalenes are compared with those on poly-nitronaphthalenes. The reactivity rules thereby deduced are based on such limited data, however, that they should be regarded as tentative and subject to confirmation or modification on the basis of further experimental study. In many cases, only a single reaction has been investigated. From the data in Tables IX to XVI, one can derive certain conclusions about the effects of the nucleophile, leaving group, other substituents, solvent, and comparison temperature, all of which are summarized at the end of this section. 

Nucleophilic reagents attack pyridine at the a-position to form an adduct that rearomatizes by dissociation (Scheme 1). Only very strong nucleophiles, e.g. NH2-, RLi, LAH, Na-NH3, react, and for the second step to afford a substitution product (5), conditions that favour hydride loss are required. Adducts formed with hydride ions (from LAH) or carbanions (from lithium alkyls) are relatively more stable than the others at low temperature, and dihydropyridines (6) can be obtained by careful neutralization. Fusion of a benzene ring to pyridine increases reactivity towards nucleophiles, and attack is now found at both a- and y-positions in quinoline (7) and at C-l in isoquinoline (8). This may be attributed to a smaller loss of aromaticity in forming the initial adduct than in pyridine, and thus a correspondingly decreased tendency to rearomatize is also observed. Acridine reacts even more easily, but nucleophilic attack is now limited to the y -position (9), as attachment of nucleophiles at ring junctions is very rare. 

Quinolines have also been prepared on insoluble supports by cyclocondensation reactions and by intramolecular aromatic nucleophilic substitution (Table 15.26). Entry 10 in Table 15.26 is an example of a remarkable palladium-mediated cycloaddition of support-bound 2-iodoanilines to 1,4-dienes. Reduction of the nitro group of polystyrene-bound 2-nitro-l-(3-oxoalkyl)benzenes with SnCl2 (Entry 11, Table 15.26) leads to the formation of quinoline /Y-oxides. These intermediates can be reduced to the quinolines on solid phase by treatment with TiCl3. 4-Quinolones have been prepared by thermolysis of resin-bound 2-(arylamino)methylenemalonic esters [311]. 

Oxidation of the pyridine nitrogen increases the propensity of the aromatic ring for nucleophilic attack at the 2- and 4-positions. a-Benzotriazolyl-substituted pyridines, quinolines, and isoquinolines may be prepared by treatment of the A -oxide with 1-tosylbenzotriazole in the presence of triethylamine in toluene or xylene under reflux <2001H1703> (Equation 78). 

An important use of the traditional Skraup synthesis is to make 6-methoxy-8-nitroquinoline from an aromatic amine with only one free ortho position, glycerol, the usual concentrated sulfuric acid, and the oxidant arsenic pentoxide. Though the reported procedure uses 588 grams of As2Os, which might disconcert many chemists, it works well and the product can be turned into other quinolines by reduction of the nitro group, diazotization, and nucleophilic substitution (Chapter 23). 

V-Hclcrocyclic aromatic compounds such as pyridines and quinolines can be converted into their /V-oxidcs by oxidation with hydrogen peroxide or peracid. Pyridine /V-oxidcs are reactive not only toward electrophilic substitution but also toward nucleophilic substitution, and, unlike pyridine, may be substituted preferentially at the 2 and 4 positions.214 Since the /V-oxidcs can readily be reduced to reproduce the parent bases, various 2- and 4-substituted pyridines and quinolines, as well as other substituted /V-helerocyclic bases, have been prepared through their N-oxides. 

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