Nucleophilic substitutions quinoline derivatives

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. 

Quinoxalinyl, 4-cinnolinyl, and 1-phthalazinyl derivatives, which are all activated by a combination of induction and resonance, have very similar kinetic characteristics (Table XV, p. 352) in ethoxylation and piperidination, but 2-chloroquinoxaline is stated (no data) to be more slowly phenoxylated. In nucleophilic substitution of methoxy groups with ethoxy or isopropoxy groups, the quinoxaline compound is less reactive than the cinnoline and phthalazine derivatives and more reactive than the quinoline and isoquinoline analogs. 2-Chloroquinoxaline is more reactive than its monocyclic analog, 2-chloropyrazine, with thiourea or with piperidine (Scheme VI, p. 350). 

The nitration of l,2,5-selenadiazolo[3,4-/] quinoline 77 with benzoyl nitrate affords the 8-nitro derivative 78, whereas methylation with methyl iodide or methyl sulfate afforded the corresponding 6-pyridinium methiodide 79 or methosulfate 80, respectively (Scheme 29). The pyridinium salt 80 was submitted to oxidation with potassium hexacyanoferrate and provided 7-oxo-6,7-dihydro derivative 81 or, by reaction of pyridinium salt 79 with phenylmagnesium bromide, the 7-phenyl-6,7-dihydro derivative 82. Nucleophilic substitution of the methiodide 79 with potassium cyanide resulted in the formation of 9-cyano-6,9-dihydroderivative 83, which can be oxidized by iodine to 9-cyano-l,2,5-selenadiazolo [3,4-/]quinoline methiodide 84. All the reactions proceeded in moderate yields (81IJC648). 

Additions to quinoline derivatives also continued to be reported last year. Chiral dihydroquinoline-2-nitriles 55 were prepared in up to 91% ee via a catalytic, asymmetric Reissert-type reaction promoted by a Lewis acid-Lewis base bifunctional catalyst. The dihydroquinoline-2-nitrile derivatives can be converted to tetrahydroquinoline-2-carboxylates without any loss of enantiomeric purity <00JA6327>. In addition the cyanomethyl group was introduced selectively at the C2-position of quinoline derivatives by reaction of trimethylsilylacetonitrile with quinolinium methiodides in the presence of CsF <00JOC907>. The reaction of quinolylmethyl and l-(quinolyl)ethylacetates with dimethylmalonate anion in the presence of Pd(0) was reported. Products of nucleophilic substitution and elimination and reduction products were obtained . Pyridoquinolines were prepared in one step from quinolines and 6-substituted quinolines under Friedel-Crafts conditions <00JCS(P1)2898>. 

Synthesis of quinolines by nucleophilic substitution of nitrogen atom in oxime derivatives was described by Narasaka and coworkers. /3-Aryl ketone oximes 297 in the presence of trifluoroacetic anhydride and 4-chloranil afforded quinolines 298 in 72-82% yield (equation 128). However, interaction of oxime 299 with 48% HBr at 105 °C proceeded with elimination of hydroxyimino group and gave 2,3-dimethoxynaphtho[l,2-fc]quinolizinium bromide (300) in 45% yield (equation 129). ... 

QUINAPHOS ligands are usually synthesized in a one-pot-procedure from readily available 8-substituted quinolines [8] via nucleophilic addition of a lithium reagent [9] to the azomethinic double bond and direct quenching of the resulting 1,2-dihydroquinoline amide 1 with a phosphorochloridite derived from enantio-merically pure binaphthol (1) or from 3,3 -di-t-butyl-5,5 -dimethoxybiphenyl-2,2 -diol (m) [10] (Scheme 2.1.5.1, Method A). Alternatively, the anion 1 can be reacted with an excess (in order to avoid multiple substitution) of phosphorous trichloride to obtain the corresponding phosphorous dichloridite 2, which can be isolated (Scheme 2.1.5.1, Method B). In a second step, 2 is converted into 4 by reaction with the desired diol in the presence of triethylamine. 

A-Acylpyridinium salts are more reactive than the A-alkyl derivatives and afford more stable dihydropyridine products on addition of nucleophiles. Organocuprates are utilized for entry into 2-alkynyl-substituted quinoline systems (Equation 53) <2005TL8905>. They have the advantage of superior selectivity over Grignard reagents, which yield a mixture of the 2- and 4-substituted products. The reaction has been expanded to include isoquinolines and pyridines. 

Substituted quinoline N-oxides have been prepared via the base-induced cyclization of alkylidene derivatives of O-nitroarylacetonitriles, which are readily available via the vicarious nucleophilic substitution cyanomethylation of nitroarenes followed by Knoevenagel condensation [9]. 

Again, as expected, pyridine A-oxides are very susceptible to nucleophilic attack. Unlike the situation usually prevalent with the quaternary pyridinium salts, the elimination stage of the two-step nucleophilic substitution can occur with relative ease, the oxide grouping serving as a good sink for the leaving hydride ion electron-pair and being itself eliminated in the process. Considerably more work has been carried out on quinoline and isoquinoline A-oxides than on pyridine A-oxide derivatives. 

In the simplest of these, jS-enaminones are synthesized (equation 129) by the addition of amines to 1,3-diketones or /3-ketoesters. The reaction has been apphed to the Friedlander synthesis of quinolines by condensation of the enaminone and other carbonyl present in the substrate. Substituted pyrroles in equation (130) can be obtained as well when a propargyl group is present, by addition of the enaminone to the triple bond. Alcohols, thiols, and secondary phosphines have been also tested as nucleophiles with good results. A particularly interesting case is found in the condensation of indoles with 1,3-diketones to give substituted indol derivatives in equation (131). ... 

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

Reviews published during the reporting period of this chapter include a publication by Makosza detailing the use of vicarious nucleophilic substitution of hydrogen as a tool for the synthesis of indole and quinoline derivatives <01H(54)445>. There also appeared a review of simple indole alkaloids and those with a nonrearranged monoterpenoid unit <01NPR66>. 

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