Cyclohexanone, piperidine

The only kinetic data reported are in a Ph.D. thesis (41). Integral order kinetics were usually not obtained for the reaction of a number of ketones with piperidine and a number of secondary amines with cyclohexanone. A few of the combinations studied (cyclopentanone plus piperidine, pyrrolidine, and 4-methylpiperidine, and N-methylpiperazine plus cyclohexanone) gave reactions which were close to first-order in each reactant. Relative rates were based on the time at which a 50% yield of water was evolved. For the cyclohexanone-piperidine system the half-time (txn) for the 3 1 ratio was 124 min and for the 1 3 ratio 121 min. It appears that an... 

Cyclohexanone, piperidine, 58, 119 Cyclohexanones, 2-alkyl-5-methyl-, 56, 56 Cyclohexene, 56, 34 57, 11 58, 45, 51 Cyclohexene, 1,6-dibromo-, 56, 34 CYCLOHEXENE, 3-METHYL-, 56, 101 Cyclohexene, 1-phenyl-, 56, 106 5-Cyclohexene-1,4-dione, 2,3-dichloro-2,5-di-fe/Y-butyl, 55, 32 5-Cyclohexene-l,4-dione, 2,3,5-tnchloro... 

Reaction of the pyrrolidine enamine of cyclohexanone with phenyl vinyl sulfone afforded a 9 1 mixture of the tri- and tetrasubstituted isomers (2(5). The preference of the less substituted isomer in this case is in keeping with the greater overlap requirement between the n electrons of the double bond and the electron pair on the nitrogen atom, since the double bond exo to the five-membered ring is much more favored than the double bond exo to the six-membered ring. It is, however, hard to explain the formation of largely the trisubstituted isomer with the piperidine enamine of cyclohexanone, where both of the rings involved are six-membered. 

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 piperidine, pyrrolidine, and morpholine enamines of cyclohexanone substituted in the 3-position by methyl, phenyl, and l-butyl have been prepared (49). The complexity of the NMR spectra in the ethylenic hydrogen region indicated a mixture of isomeric enamines. Estimation of the per cent of each isomer by examination of the NMR spectra was not possible, nor were the isomeric enamines separable by vapor-phase chromatography. 

Experimental evidence, obtained in protonation (3,6), acylation (1,4), and alkylation (1,4,7-9) reactions, always indicates a concurrence between electrophilic attack on the nitrogen atom and the -carbon atom in the enamine. Concerning the nucleophilic reactivity of the j3-carbon atom in enamines, Opitz and Griesinger (10) observed, in a study of salt formation, the following series of reactivities of the amine and carbonyl components pyrrolidine and hexamethylene imine s> piperidine > morpholine > cthyl-butylamine cyclopentanone s> cycloheptanone cyclooctanone > cyclohexanone monosubstituted acetaldehyde > disubstituted acetaldehyde. 

The formation of bicyclic imines (263,264) from piperidine enamines and y-bromopropyl amines may appear at first sight to be a simple extension of the reactions of enamines with alkyl halides. However, evidence has been found that the products are formed by an initial enamine exchange, followed by an intramolecular enamine alkylation. Thus y-bromodiethylamino-propane does not react with piperidinocyclohexene under conditions suitable for the corresponding primary amine. Furthermore, the enamine of cyclopentanone, but not that of cyclohexanone, requires a secondary rather than primary y-bromopropylamine, presumably because of the less favorable imine to enamine conversion in this instance. 

The reactions of dichlorocarbene with morpholine and piperidine enamines derived from cyclopentanone and cyclohexanone have been reported to lead to ring expanded and a-chloromethylene ketone products (355,356). Similarly a-chloro-a, -unsaturated aldehydes were obtained from aldehyde derived enamines (357). Synthesis of aminocyclopropanes (353,359) could be realized by the addition of diphenyldiazomethane (360) and the methylene iodide-zinc reagent to enamines (367). 

Fusion of an all cyclic ring onto the piperidine so as to form a perhydroisoquinoline is apparently consistent with analgesic activity. Synthesis of this agent, ciprefadol (68), starts with the Michael addition of the anion from cyclohexanone 56 onto acrylonitrile (57). Saponification of the nitrile to the corresponding acid ( ) followed by Curtius rearrangement leads to isocyanate Acid... 

Treated with ZnBr2 followed by enamines, phenyl thioethers 829 derived from aryl aldehydes are converted to (l-(phenylthio)alkyl ketones or aldehydes 830 in moderate to good yields (Equation 19). Enamines used in these syntheses are (1) morpholine enamine derived from diethyl ketone, (2) diethylamine enamine of propiophenone, (3) piperidine enamine derived from isovaleraldehyde, and (4) pyrrolidine enamine of cyclohexanone <2000H(53)331>. 

The first example of this type of transformation was reported in 1974 [76]. Three catalysts were investigated, namely [Co2(CO)8], [Co(CO)g/PBu ], and [Rh6(CO)i6]. The [Co OJg/PBu ] catalyst showed activity for reductive animation using ammonia and aromatic amines. The [Rh6(CO)16] catalyst could be used for reductive animation using the more basic aliphatic amines that were found to poison the cobalt catalyst. This early report pointed out that the successful reductive animation of iso-butanal (Me2CCHO) with piperidine involves selective enamine hydrogenation, that reductive animation of cyclohexanone with isopropylamine probably involves imine hydrogenation, and that reductive amination of benzaldehyde with piperidine would presumably involve the reduction of a carbinolamine. 

Compound 197 has been treated with carbonyl-containing derivatives such as cyclohexanone and 3-methyl-l-phenylpyrazol-5-one, in refluxing ethanol containing some drops of piperidine as catalyst, in order to promote Michael additions leading to spiro derivatives 198 and 199, where an acetyl group has been eliminated during the process (Scheme 8) <2000FES641>. 

Comparison of the configuration of the stannane with the prodncts of reaction reveals that primary alkyl halides that are not benzyhc or a to a carbonyl react with inversion at the lithium-bearing carbon atom. In the piperidine series, the best data are for the 3-phenylpropyl compound, which was shown to be >99 1 er. In the pyrrolidine series, the er of the analogous compound indicates 21-22% retention and 78-79% inversion of configuration. Activated alkyl halides such as benzyl bromide and teri-butyl bromoacetate afford racemic adducts. In both the pyrrolidine and piperidine series, most carbonyl electrophiles (i.e. carbon dioxide, dimethyl carbonate, methyl chloroformate, pivaloyl chloride, cyclohexanone, acetone and benzaldehyde) react with virtually complete retention of configuration at the lithium-bearing carbon atom. The only exceptions are benzophenone, which affords racemic adduct, and pivaloyl chloride, which shows some inversion. The inversion observed with pivaloyl chloride may be due to partial racemization of the ketone product during work-up. 

Organoaluminum-promoted Beckmann rearrangement/methylation of cyclohexanone oxime mesylate, followed by allylation of ketimine 40a and Mannich cyclization of the intermediate iminium-allylsilane, provides piperidine 40b possessing cxo-unsaturation (08BKC1669). 

Platinum sulfide appeared superior to palladium for the reductive alkylation of piperidine with acetone. A more carefully controlled comparison of platinum sulfide with palladium and with platinum is shown in Table 2 for the reaction of N-ethylcyclohexylamine with cyclohexanone. Platinum gave a very poor conversion of the starting secondary amine (27%) and a correspondingly low yield of the tertiary amine product (22%), although the yield based on conversion was good (81%). The... 

The fixed geometry of a, 3-unsaturated ketones in the S-cis form, as observed in arylidene alkanones, influences their reactivity. For example, the reaction of arylhydrazines with 3,5-diarylidene-4-piperidones, 2-arylidene-l-tetralones, 2,6-diarylidenecyclohexanones and 2-arylideneindan-l,3-diones requires stronger conditions than for the case of their noncyclic analogues [76, 77, 78, 79, 80, 81, 82, 83, 84]. However, arylidene derivatives of cyclohexanone, 1-indanone, 4-chromanone, 4-thiochromanone and TV-methyl-4-piperidone hydrochloride react with hydrazines more easily [85,86,87,88], It is interesting to note that the more complicated and sterically hindered unsaturated ketones of the spiro type 64 react with hydrazine and phenylhydrazine very easily in the presence of piperidine, leading to pyrazoles 65 in high yields [89] (Scheme 2.16). 

Two other nucleophilic substitution reactions of pyridine iV-oxides deserve mention and further study to determine the effects of substituents. Pyridine N-oxide, benzoyl chloride, and the piperidine enamine of cyclohexanone give a good yield of 2-(2 -pyridyl)cyclo-hexanone (155) (63%).360 When W-methoxy-4-picolinium methyl... 

Cyclohexylidenecyanoacetic acid has been prepared by the condensation of cyclohexanone and cyanoacetic acid in the presence of piperidine 4-5 and by the hydrolysis of ethyl cyclohexyl-idenecyanoacetate.4... 

Cyclohexenylacetonitrile has been prepared by the decarboxylation of cyclohexylidenecyanoacetic acid 4-5 by the dehydration of 1-cyclohexenylacetamide 5 by the condensation of cyclohexanone and cyanoacetic acid in the presence of piperidine 6 by the condensation of cyclohexanone and ethyl cyano-acetate in the presence of sodium ethoxide 4-7 and by the condensation of cyclohexanone and cyanoacetic acid in the presence of ammonium acetate followed by decarboxylation.8 Ammonium acetate also has been used as a catalyst for the condensation of ketones with ethyl cyanoacetate.3-9... 

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