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Decahydroquinolines

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. [Pg.390]

To return to a more historical development the mercuric acetate oxidation of substituted piperidines (77) should be discussed next. This study established that the normal order of hydrogen removal from the aW-carbon is tertiary —C—H > secondary —C—H > primary —C—H, an observation mentioned earlier in this section. The effect of substitution variations in the piperidine series can be summarized as follow s l-mcthyl-2,6-dialkyl and 1-methyl-2,2,6-trialkyl piperidines, as model systems, are oxidized to the corresponding enamines the 1,2-dialkyl and l-methyl-2,5-dialkyl piperidines are oxidized preferentially at the tertiary a-carbon the 1-methyl-2,3-dialkyl piperidines gave not only the enamines formed by oxidation at the tertiary a-carbon but also hydroxylated enamines as found for 1-methyl-decahydroquinoline (48) (62) l-methyl-2,2,6,6-tctraalkyl piperidines and piperidine are resistant to oxidation by aqueous mercuric acetate and... [Pg.71]

According to a report by Japanese authors, oxazirane rings are also formed by the action of silver oxide on perhydro-nitrogen heterocycles, e.g., decahydroquinoline (10) [Eq. (5)]. ... [Pg.88]

Reaction Kinetics of the Hydrodenitrogenation of Decahydroquinoline over NiMo(P)/Al203 Catalysts... [Pg.87]

Each of the three decahydroquinoline sulfonates shown below gives a different product composition on solvolysis. One gives 9-methylamino-E-non-5-enal, one gives 9-methylamino-Z-non-5-enal, and one gives a mixture of the two quinoline derivatives 14-D and 14-E. Deduce which compound gives rise to which product. Explain your reasoning. [Pg.1000]

An interesting synthesis of enantiopure cu-decahydroquinolines, which involves enol ether hydrolysis, double bond isomerization, and intramolecular 1,4-addition of an amino group across a cyclohexenone has been reported <06T9166>. The process is stereoselective, with the exclusive formation of both cu-isomers 176 (43% over 3 steps) and 177 (17% over 3 steps) of the decahydroquinoline ring. [Pg.337]

The supported complex [Rh(cod)(POLYDIPHOS)]PF6, obtained by stirring a CH2C12 solution of [RhCl(cod)]2 and Bu4NPF6 in the presence of a diphenyl-phosphinopropane-like ligand tethered to a cross-linked styrene/divinylbenzene matrix (POLYDIPHOS), forms an effective catalyst for the hydrogenation of quinoline (Fig. 16.8) [84]. Under relatively mild experimental conditions (80 °C, 30 bar H2), quinoline was mainly converted to THQ, though appreciable formation of both 5,6,7,8-THQ and decahydroquinoline also occurred (Scheme 16.20). [Pg.480]

SAM, samandarines BTX, batrachotoxins HTX, histrionicotoxins PTX, pumiliotoxins aPTX, allopumiliotoxins hPTX, homopumiliotoxins DHQ, 2,5-disubstituted decahydroquinolines 3,5-P, 3,5-d [substituted pyrrolizidines 3,5-1 and 5,8-1, disubstituted indolizidines 1,4-Q, 1,4-disubstituted quinolizidines Epi, epibatidine Pseudophry, pseudophrynamines. With the exception of 3,5-P and 3,5-1, these alkaloids are not known to occur in arthropods (see text). Histrionicotoxins may occur in Minyobates and Mantella, but the evidence is not conclusive. [Pg.29]

In an effort to identify possible sources of the 16 alkaloids found in the skin of the Panamanian poison frog Dendrobates auratus, ants from a total of 61 terrestrial nests were analyzed [124]. The alate queens of one species of myr-micine ants (Solenopsis (Diplorhoptrum) sp.) collected at Cerro Ancon were found to contain the decahydroquinoline (-)-ds-195A (112) which was also present as a minor alkaloid in the skin of the microsympatric population of D. auratus. Moreover, from wingless ants of two nests collected at Isla Taboga and identified as Megalomyrmex silvestrU the same workers isolated the stereo-isomeric 3,5-disubstituted pyrrolizidines rfs-251 K (117) and trans-251 K (118) in the same ratio 3 1 that was present in the skin of a microsympatric population of D. auratus (Fig. 20) [124]. [Pg.203]

The electrochemical oxidation of amines to imines and nitriles typically utilize a chemical mediator. The use of both Al-oxyl radicals [12, 13] and halogens has been reported for this process [14]. For example, the conversion of benzyl amine (14a) into nitrile (15a) and aldehyde (16a) has been accomplished using the M-oxyl radical of a decahydroquinoline ring skeleton as the mediator (Scheme 5). The use of acetonitrile as the solvent for the reaction generated the nitrile product. The addition of water to the reaction stopped this process by hydrolyzing the imine generated. A high yield of the aldehyde was obtained. In the case of a secondary amine, the aqueous... [Pg.282]

The active principle of dart frog poisons is alkaloids. The study of the den-drobatid poisons led to the discovery of over 200 new alkaloids, including batrachotoxins Pig. 10.5), pumiliotoxins, histrionicotoxins, gephyrotoxins, and decahydroquinolines (Daly et al., 1994). The most common compounds have the basic structure of piperidine and include histrionotoxin. In Phyllobates, the synthesis of other alkaloids is suppressed in favor of batrachotoxins. These are... [Pg.252]

These conclusions are reinforced by measurement of natural abundance 15N chemical shifts in piperidines and decahydroquinolines (77JA8406,78JA3882,78JA3889). Lack of correlation between 13C shifts of cyclohexanes and 1SN shifts of piperidines bearing the same methyl substituents are attributed to, among other factors, solvent effects and the difference between H-lone pair and H-H interactions. Protonation served to cancel these stereoelec-tronic effects. Correspondence between 1SN shifts in N- and C- methyl substituted piperidines and decahydroquinoline hydrochlorides and the analogous 13C values were, however, generally much closer than for saturated aliphatic amines. [Pg.161]


See other pages where Decahydroquinolines is mentioned: [Pg.281]    [Pg.281]    [Pg.184]    [Pg.185]    [Pg.99]    [Pg.89]    [Pg.101]    [Pg.101]    [Pg.102]    [Pg.33]    [Pg.34]    [Pg.35]    [Pg.36]    [Pg.36]    [Pg.37]    [Pg.247]    [Pg.1016]    [Pg.202]    [Pg.203]    [Pg.112]    [Pg.273]    [Pg.58]    [Pg.692]    [Pg.58]    [Pg.293]    [Pg.160]    [Pg.160]    [Pg.161]    [Pg.161]   
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See also in sourсe #XX -- [ Pg.615 ]

See also in sourсe #XX -- [ Pg.207 , Pg.235 , Pg.238 , Pg.245 ]




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2.5- Disubstituted decahydroquinolin

2.5- Disubstituted decahydroquinoline

Amphibian alkaloids 2,5-disubstituted decahydroquinolines

Decahydroquinoline

Decahydroquinoline

Decahydroquinoline alkaloid

Decahydroquinoline derivatives

Decahydroquinoline type

Decahydroquinoline, hydrogenation

Decahydroquinolines, conformation

Decahydroquinolines, from quinoline

Quinoline decahydroquinoline

Stereodivergent process decahydroquinoline-type dartpoison frog synthesis

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