Reduced Quinolines

Second, for cobalt phthalocyanines, CCT and Cl are dependent upon the addition of quinoline.136 294 Addition of low concentrations (0.1-0.001 M) of quinoline reduces the rate of CCT by cobalt phthalocyanines. Higher concentrations of quinoline increased Cl and slowed CCT, converting CCT catalysts into Cl catalysts. These observations were interpreted in favor of eq 31. 

These compounds can be malodorous as in the case of quinoline, or they can have a plecisant odor as does indole. They decompose on heating to give organic bases or ammonia that reduce the acidity of refining catalysts in conversion units such as reformers or crackers, and initiate gum formation in distillates (kerosene, gas oil). 

Lindlar Catalyst ( Pd/BaS04/ quinoline)- partially poisoned to reduce activity will only reduce the most reactive functional groups. 

The heterocyclic rings in quinoline (116) and isoquinoline are selectively reduced by Pd on carbon-catalyzed reaction of ammonium formatc[107]. Some benzene rings are also reduced. For example, nitrobenzene is reduced to cyclohexylamine (117) with formic acid. It is important to use a sevenfold excess of formic acid[108]. 

In many instances, beginning a synthesis with quinoline N-oxide [1613-37-2] faciHtates the preparation of difficult compounds. Quinoline is converted to the N-oxide using hydrogen peroxide in acetic acid, and later reduced to the substituted quinoline. Warm mixed acid gives 4-rutroquinoline... 

Oxidation. The synthesis of quinolinic acid and its subsequent decarboxylation to nicotinic acid [59-67-6] (7) has been accompHshed direcdy in 79% yield using a nitric—sulfuric acid mixture above 220°C (25). A wide variety of oxidants have been used in the preparation of quinoline N-oxide. This substrate has proved to be useful in the preparation of 2-chloroquinoline [612-62-4] and 4-chloroquinoline [611 -35-8] using sulfuryl chloride (26). The oxidized nitrogen is readily reduced with DMSO (27) (see Amine oxides). 

Reduction. Quinoline may be reduced rather selectively, depending on the reaction conditions. Raney nickel at 70—100°C and 6—7 MPa (60—70 atm) results in a 70% yield of 1,2,3,4-tetrahydroquinoline (32). Temperatures of 210—270°C produce only a slightly lower yield of decahydroquinoline [2051-28-7]. Catalytic reduction with platinum oxide in strongly acidic solution at ambient temperature and moderate pressure also gives a 70% yield of 5,6,7,8-tetrahydroquinoline [10500-57-9] (33). Further reduction of this material with sodium—ethanol produces 90% of /ra/ j -decahydroquinoline [767-92-0] (34). Reductions of the quinoline heterocycHc ring accompanied by alkylation have been reported (35). Yields vary widely sodium borohydride—acetic acid gives 17% of l,2,3,4-tetrahydro-l-(trifluoromethyl)quinoline [57928-03-7] and 79% of 1,2,3,4-tetrahydro-l-isopropylquinoline [21863-25-2]. This latter compound is obtained in the presence of acetone the use of cyanoborohydride reduces the pyridine ring without alkylation. 

The catalyst commonly used in this method is 5 wt % palladium supported on barium sulfate inhibited with quinoline—sulfur, thiourea, or thiophene to prevent reduction of the product aldehyde. A procedure is found in the Hterature (57). Suitable solvents are toluene, benzene, and xylene used under reflux conditions. Interestingly, it is now thought that Rosenmund s method (59) originally was successful because of the presence of sulfur compounds in the xylene used, since the need for an inhibitor to reduce catalyst activity was not described until three years later (60). 

When two fused six-membered rings (naphthalene analogues) are considered, possibilities become very numerous, partly on account of the reduced symmetry of naphthalene, compared with benzene, and also because of the larger number of positions available for substitution. Thus, there are two monoazanaphthalenes, quinoline (8) and isoquinoline (9), four benzodiazines [cinnoline (10), phthalazine (11), quinazoline (12) and quinoxaline(13)], with the two nitrogen atoms in the same ring, and six naphthyridines (e.g. (14), named and... 

Practically all pyridazine-carboxylic and -polycarboxylic acids undergo decarboxylation when heated above 200 °C. As the corresponding products are usually isolated in high yields, decarboxylation is frequently used as the best synthetic route for many pyridazine and pyridazinone derivatives. For example, pyridazine-3-carboxylic acid eliminates carbon dioxide when heated at reduced pressure to give pyridazine in almost quantitative yield, but pyridazine is obtained in poor yield from pyridazine-4-carboxylic acid. Decarboxylation is usually carried out in acid solution, or by heating dry silver salts, while organic bases such as aniline, dimethylaniline and quinoline are used as catalysts for monodecarboxylation of pyridazine-4,5-dicarboxylic acids. 

Reactions of 6-aminouracils with various 2-substituted cyclohexanones such as the aldehyde (264) give reduced pyrimido[4,5-f ]quinolines (265) (57BRP774095, 58JA3449), and other cyclohexanone derivatives used include the 2-dimethylaminomethyl (Mannich) bases (78AP542) and the 5-benzylidenedimedones (266) formed in situ from dimedone and aldehydes (67KGS395, cf. 67KGS406). 

Acylation of -ones and -diones appears to occur mainly at oxygen, but in the fused pyridazino[4,5-6]quinoline (312) the O-acyl derivative (313) was formed via an iV,0-diacyl derivative (72BSF1588). Reduced derivatives, however, are acylated at nitrogen. 

Dried with Linde type 5A molecular sieves or Na2S04 and fractionally distd at reduced pressure. Alternatively, it was refluxed with, and distd from, BaO. Also purified by fractional crystn from the melt and distd from zinc dust. Converted to its phosphate (m 135°) or picrate (m 223°), which were purified by crystn and the free base recovered and distd. [Packer, Vaughn and Wong J Am Chem Soc 80 905 1958.] The procedure for purifying via the picrate comprises the addition of quinoline to picric acid dissolved in the minimum volume of 95% EtOH to yield yellow crystals which are washed with EtOH and air dried before recrystn from acetonitrile. The crystals are dissolved in dimethyl sulfoxide (previously dried over 4A molecular sieves) and passed through a basic alumina column, on which picric acid is adsorbed. The free base in the effluent is extracted with n-pentane and distd under vacuum. Traces of solvent are removed by vapour phase chromatography. [Mooman and Anton J Phys Chem 80 2243 1976.]... 

In 1931 Ing pointed out that formula (II) and (III) do not contain methyl or potential methyl groups in j ositions 6 and 8 which they occupy in cytisoline. Further, a partially reduced quinoline ought to oxidise easily to a benzenecarboxylic acid and so far the only simple oxidation, products recorded from cytisine were ammonia, oxalic acid and isovaleric acid. Distillation of cytisine with zinc dust or soda-lime yields pyrrole and pyridine, but no quinoline. On these grounds Ing suggested that cytisine should be formulated without a quinoline nucleus, and that the reactions which indicate the presence of an aromatic nucleus in the alkaloid can be accounted for by an a-pyridone ring. This a-pyridone nucleus can... 

Ewins suggests that deacetylaspidospermine is a secondary-tertiary base, and that aspidospermine is a derivative of a reduced quinoline. 

Other secondary amines such as pyrrolidine, di- -butylamine, tetrahydro-quinoline, n-benzylamine, and piperidine were also found to be capable of effecting this reduction. Interestingly, morpholine does not reduce enamines as readily (47) and its acid-catalyzed reaction with norbornanone was reported (45) to give only the corresponding enamine (93), although trace amounts of the reduction product were detected when cyclohexanone was treated with morpholine under these conditions (47a). The yield of morpholine reduction product was increased by using higher temperatures. 

The lithium- -propylamine reducing system has been found capable of reducing julolidine (113) to /d -tetrahydrojulolidine (114, 66% yield) and 1-methyl-1,2,3,4-tctrahydroquinoline to a mixture of enamines (87% yield), l-methyl-J -octahydroquinoline (115) and 1-methyl-al -octahydro-quinoline (116) 102). This route to enamines of bicyclic and tricyclic systems avoids hydroxylation, which occurs during mercuric acetate oxidation of certain bicyclic and tricyclic tertiary amines 62,85 see Section III.A). 

Derivatives of 1 -ethy l-7-alkylamino-6-nitro-4-oxo-1,4-dihydroquinoline-3-carboxylic acid 137 have been reduced to corresponding diamines 138 and afterwards converted exclusively to linearly annelated imidazo[4,5-g]quinoline-7-carboxylic acid derivatives 139 (Scheme 43) (88KFZ33). 

Synthesis of pyrazolo[l,5-<2]quinolines and related reduced derivatives 97H(45)1839. 

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