2- -1-piperideine

Some of the partially and fully reduced heterocyclic six-membered rings are sufficiently important to have trivial names with which the reader should be familiar. Thus hexahy-dropyridine (38) is known as piperidine, and tetrahydro-l,4-oxazine (39) is morpholine. Tetrahydropyridines are also sometimes referred to as piperideines, with the position of the double bond denoted by a A, but this system is obsolescent (at the least). 

A -Piperideine — see Pyridine, 2,3,4,5-tetrahydro-A -Piperideine — see Pyridine, 1,2,3,4-tetrahydro-A -Piperideine — see I ridine, 1,2,3,6-tetrahydro-Piperideines — see Pyridines, tetrahydro-Piperidine, 1-acryIoyI-polymers, 1, 284 Piperidine, JV-acyl-... 

Alkyl-/l -pyrrolines (8, n = 1) and 2-alkyl-/l -piperideines (8, n = 2) are readily formed by the methods used to prepare y- and S-amino ketones (3-6). The reaction of corresponding halogeno ketones with ammonia belongs to the classical reactions of this type. 

By use of potassium phthalimide we can isolate the intermediate. a-Oxo-S-aminovaleric (9, = 1) and a-oxo-e-aminocaproic acids (9, = 2) readily yield 2l -pyrroline-2-carboxylic acid (10, =1) and. d -piperideine-2-carboxylic acids (10, n = 2), respectively (7-10). The equilibria of the acids with their cyclic forms was observed in water solutions (11,12). 

Phenols and phenol ethers can be acylated with y- or S-amino acids in the presence of polyphosphoric acid to form 2-aryl-2d -pyrrolines (11, = 1) or 2-aryl-/l -piperideines (11, n = 2), respectively (13). 

The use of primary amines instead of ammonia affords l,2-dialkyl-/l -pyrrolines or l,2-dialkyl-/l -piperideines. Amino ketones with a primary amino group are intermediates in the reduction of y-nitropropylalkyl ketones (14,15) or S-nitrobutylalkyl ketones (16-18) by catalytic hydrogenation over Raney nickel or with zinc and hydrochloric acid (Scheme 1). 

Alkyl-/l -piperideines were obtained on treatment of imino ethers with Grignard reagent (37,38). 

Lukes studied the reaction of N-methyl lactams with Grignard reagents. With the five- (39-42) and six-membered (43-47) rings, 2,2-dialkylated bases (16, = 1,2) are formed as by-products in addition to the l-methyl-2-alkyl pyrrolines (15, = 1) or l-methyl-2-alkyl piperideines (15, =2). Aromatic Grignard reagents afford only the unsaturated bases, probably because of steric factors (48,49). Separation of enamines and 2,2-dialkylated amines from each other can be easily achieved since the perchlorates of the enamines and the picrates of 2,2-dialkylated bases crystallize readily. Therefore enamines can be isolated as crystalline perchlorates and the 2,2-dialkylated bases as crystalline picrates. Some authors who repeated the reactions isolated only pyrrolines (50,57) or, by contrast, 2,2-dialkylated bases (52). This can be explained by use of unsuitable isolation techniques by the authors. 

The reactivity of the methylene group adjacent to the lactam group affords the possibility of a Claisen condensation. Thus, treatment of 2-pyrrolidone or 2-piperidone with ethyl oxalate leads to the J -pyrroline-carboxylic (70) and, d -piperideine-2-carboxylic acids (71), respectively. N-methyl lactams furnish N-methyl derivatives (72,73) (Scheme 3). 

The treatment of esters of aromatic acids with l-alkyl-2-pyrrolidones and l-alkyl-2-piperidones is an extremely useful method for the preparation of simple pyrrolines and piperideines, respectively. The l-alkyl-3-aroyl-2-... 

A -Pyrroline has been prepared in low yield by oxidation of proline with sodium hypochlorite (71), persulfate (102), and periodate (103). A -Pyrroline and A -piperideine are products of enzymic oxidation via deamination of putrescine and cadaverine or ornithine and lysine, respectively (104,105). This process plays an important part in metabolism and in the biosynthesis of various heterocyclic compounds, especially of alkaloids. 

The best procedure for the preparation of zl -pyrroline (31, n = l)and /I -piperideine (31, = 2) consists of dehydrohalogenation of N-chloro-pyrrolidine and N-chloropiperidine, respectively, by means of potassium hydroxide (106). 

A -Piperideine-N-oxide was obtained along with a dimeric product by oxidation of N-hydroxypiperidines with mercuric acetate or potassium ferricyanide (107-109). 2l -Pyrroline-N-oxide is formed by oxidation of N-ethylpyrrolidine with hydrogen peroxide with simultaneous formation of ethylene (110). 

As pointed out in the introduction, if one of the substituents on the nitrogen atom is a hydrogen atom, tautomeric equilibrium between enamino and imino forms strongly favors the latter form 18,140,141). According to physiochemical measurements, the occurrence of simply substituted /1 -pyrrolines and zl -piperideines is very improbable. The formulation of this type of compound with a double bond in the position (used mainly by early authors) was of formal meaning only, having no experimental evidence (142-144). 

The piperideine derivatives have not been studied as extensively as the analogous pyrrolines (151,152). The imino structure has been established, for example, for the alkaloid y-coniceine (146) (46). The great influence of conjugation on the structure is seen with l-(a-picolyl)-6,7-methylenedioxy-3,4-dihydroisoquinoline (47), possessing an enamine structure, whereas the analogous 1-methyl derivative (48) possesses an imine structure according to infrared spectra (152,153). 

In contrast to the five-membered ring, conformational factors would be expected to influence the equilibrium between the imine and enamine forms in the case of the six-membered-ring piperideine derivatives (154). 

Tertiary pyrrolines (49, = 1) and piperideines (49, = 2) (if R = H and the enamine can exist in the monomeric form or if R = aryl) evidently possess an endocyclic -double bond (79,155,156). The stretching frequency of the double bond can be lowered to 1620-1635 cm by conjugation with an aromatic substituent. The double bond of an analogous compound with aliphatic substituents in position 2 may occupy either the endo or the exo position. Lukes and co-workers (157) have shown that the majority of the five-membered-ring compounds, traditionally formulated with the double bond in a position, possess the structure of 2-alkylidene derivatives (50) with an exocyclic double bond, infrared absorption at 1627 cm . Only the 1,2-dimethyl derivative (51) is actually a J -pyrroline, absorbing at 1632 cm . For comparison, l,3,3-trimethyl-2-methylene pyrrolidine (52) with an unambiguous exocyclic double bond has been prepared (54). 

Five- (70, = 1) and six-membered (70, n = 2) enamines substituted in position 2 generally exist in the cyclic form. Lukes and co-workers observed that partial ring-opening occurs with the pyrroline 157) or piperideine 163,164) derivatives by atmospheric moisture. This leads to the formation... 

Physicochemical investigations of enamines and their salts have shown that the addition of a proton occurs almost exclusively at the /3-carbon atom of the enamine grouping. This means that salts of pyrrolines (82), piperideines (83), and enamines of 1-azabicycloalkanes (84) possess immon-ium structures. 

An explanation of the exclusive N methylation of 1,2-dimethyl-J -piperi-deine by means of methyliodide is more difficult. Pyrrolines and piperideines which are not alkylated on the nitrogen atom afford only quaternary ammonium salts on alkylation (203-205), for example 119. 

Reaction of 2-alkyl- -pyrrolines and 2-alkyl- -piperideines with acid chlorides leads to ring-opening and formation of N-acylated amino ketones (131, = 1, 2) (211-213). Ketene reacts with J -piperideine to form a tricyclic derivative (132) (214). 

In a similar addition to l-methyl-2-alkyl-J -piperideines, l-methyl-8-alkyl-1,2,3,4-tetrahydroquinolines (134) were obtained (Scheme 10) (163). 

The addition of ethyl acrylate to 1,2-dimethyl- -piperideine 163), l-methyl-2-ethyl-zJ -piperideine 164), and 1,2-dimethyl- -pyrrolidine 216,217) occurs, yielding both possible enamine structures (138 and 139, n=I,2). 

Addition to 1,2-dimethyl- -piperideine or 1,2-dimethyl- -pyrroline is followed by intramolecular alkylation by the ester group as a side reaction to give 140 and 141 ( = 1, 2), respectively. Cyclization products 142 and... 

Reduction of l-methyl-2-alkyl-.d -pyrroline and l-methyl-2-alkyl-.d -piperideine perchlorates with complex hydrides prepared in situ by partial decomposition of lithium aluminum hydride with the optically active alcohols (—)-menthol and (—)-borneol affords partially optically active l-methyl-2-alkyl pyrrolidines (153, n = 1) and 1-methy 1-2-alkyl piperideines (153, n = 2), respectively (241,242). 

Heterocyclic enamines A -pyrroline and A -piperideine are the precursors of compounds containing the pyrrolidine or piperidine rings in the molecule. Such compounds and their N-methylated analogs are believed to originate from arginine and lysine (291) by metabolic conversion. Under cellular conditions the proper reaction with an active methylene compound proceeds via an aldehyde ammonia, which is in equilibrium with other possible tautomeric forms. It is necessary to admit the involvement of the corresponding a-ketoacid (12,292) instead of an enamine. The a-ketoacid constitutes an intermediate state in the degradation of an amino acid to an aldehyde. a-Ketoacids or suitably substituted aromatic compounds may function as components in active methylene reactions (Scheme 17). 

The simplest compounds, -pyrroline and -piperideine,donotexistin the monomeric form. Schdpf et al. (29S) described two geometric isomers of J -piperideine trimer and called them a- and -tripiperideines (182). An equilibrium exists between A -piperideine and both trimers which, therefore, react as typical aldehyde ammonia. The trimer rearranges at pH 9-10 in an almost quantitative yield to isotripiperideine (183) which, in turn, is in equilibrium with tetrahydroanabasine (184) and -piperideine. 

Isotripiperideine and a-tripiperideine structures differ from each other in a new C—C bond formed in is otripiperideine by an aldol reaction (296, 297). In aqueous media at pH 2-13, two molecules of -piperideine yield tetrahydroanabasine (297). 

The last isomer, the so-called aldotripiperideine (185), is obtained by the action of acid catalysts on a-tripiperideine at its boiling point (298,299), or in aqueous solution at pH 9.2 and 100°C. Further aldol reaction between tetrahydroanabasine and A -piperideine obviously occurs. Hydrogenolysis of this compound gives dihydroaldotripiperideine (186) which is convertible into matridine (187), a reduction product of the alkaloid matrine. 

Curiously, neither J -piperideine nor tetrahydroanabasine undergo aldolization in strongly acidic or strongly alkaline media the reaction occurs only at pH 2-13, when both the free base and its salt are present (295). This relation between the rate of aldolization and pH indicates that aldolization occurs by condensation of the methylene group of the immonium salt with the free base. 

Condensation of -pyrroline with pyrrole readily affords 2-(2-pyrro-lidyl)pyrrole (82). The dimerizations of some derivatives of A -piperideine, e.g., zl -pyrroiine and -piperideine-2-carboxylic acids, take a similar course (301). 

The only stable monomeric form of l-methyl-.d -piperideine is as the immonium salt. 

The dimer of 1-methyl- -pyrroline (39) was obtained by reduction of N-methylpyrrole with zinc and hydrochloric acid (132) and, together with the trimer, by mercuric acetate dehydrogenation of N-methylpyrrolidine (131). J -Pyrroline-N-oxides form dimers in a similar manner (302). Treatment of 1,2-dimethyl-zl -piperideine with formaldehyde, producing l-methyl-3-acetylpiperidine (603), serves as an example of a mixed aldol reaction (Scheme 18). 

In the six-membered series the alkaloids of Punica gr ana turn, isopelletier-ine and methylisopelletierine, have been obtained by treatment of enamines with acetoacetic acid. Isopelletierine (194, R = H) was prepared also by Schopf et al. from d -piperideine (309-311). The reversibility of aldol dimerization (124,131) of enamines has been established by the synthesis of methylisopelletierine (194, R = Me) from dimethyltetrahydroanabasine, accomplished by Lukes and Kovaf (101) (Scheme 19). 

The acetylation of isotripiperideine by means of a ketone in nonpolar media affords a compound which decomposes in acidic media to piperideine and a monoacety.l derivative of the enamine form of tetrahydro-anabasine (195). This monoacetyl derivative is identical with the alkaloid amodendrine (312). A similar acylation with cinnamoylchloride affords the alkaloid orensine (196) (313), the optically active form of which is the natural alkaloid adenocarpine (314). The hydrolysis of alkaloid santiaguine gives a-truxilic acid (314). 

From a vast number of alkaloids containing the /I -pyrroline or piperideine ring in the molecule, alkaloids myosmine (197) and lobinaline (i/5) (198) of Lobelia cardinalis L. may be mentioned. 

The reaction of 2-(a-pyridyl)alkylmalonic acid with J -piperideine leading to formation of 3-((x-pyridyl)quinolizidine-l-carboxylic acid on decarboxylation, has been used by Van Tamelen and Foltz (316) for the syntheis of the alkaloid lupanine (Scheme 20). A very elegant synthesis of matrine has been accomplished by Bohlmann et al. (317). 

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