Pyrrolidine amine

EXTENSIONS AND COMMENTARY There are three pyrrolidine amines in this tryptamine compilation, and all three are simply weird and illogical. Both the simple "pyrrolidyl tryptamine" (pyr-T) and the 5-methoxy counterpart (5-MeO-pyr-T) caused physical distress, and this one (4-HO-pyr-T) seems to be a more of a stimulant rather than a psychedelic. In all three cases (and with the 5,6-methylenedioxy example as well) the other two ring systems that often accompany the pyrrolide example as a "set" were simply not explored. This is due, largely, to the unexpected and generally negative responses to the pyrrolidine archetype. The piperidine homologue (4-HO-pip-T) is a white crystalline solid with a mp of 180-181 °C. The morpholine analogue is also a white crystalline solid with a mp of 177-178 °C. 

Pyrrolidine Amines and Pyrrolidine Amine Salts as Catalysts for Michael-Type Addition of Ketones to Activated Olefins... 

Pyrrolidine-amine-based catalysts such as 18 and 19 can also mediate the addition of ketones to alkylidene malonates (Scheme 2.40) [14]. Aldehydes (e.g., isova-leraldehyde) do not react with vinylidenemalonate 16 under these conditions. 

Fig. 13.34. Enders SAMP method for the generation of enantiomerically pure a-alky-Lated carbonyl compounds SAMP, (S)-aminoprolinol methyl ether = (5)-2-methoxymethyl-l-pyrrolidin-amine, or S-l-amino-2-(methoxymethyl)pyrrolidine (which is the name according to IUPAC rules).

What stmctural features are required for the high-affin-ity binding of nicotine-related agents The nicotine stmc-ture is arbitrarily divided into several regions for purpose of discussion A, the chiral center B, the pyridine ring C, the pyrrolidine amine and its substituents D, the pyrrolidine ring (see Fig. 1). 

Scheme 9.48 Pyrrolidine-aminal Im-catalysed unprecedented rearrangement of sulfones.

The N-basicity of the commonly used amines (pyrrolidine > piperidine > morpholine) drops by 2-3 orders of magnitude as a consequence of electron pair delocalization in the corresponding enamines. This effect is most pronounced in morpholino enamines (see table below). Furthermore there is a tendency of the five-membered ring to form an energetically favorable exocyclic double bond. This causes a much higher reactivity of pyrroUdino enamines as compared to the piperidino analogues towards electrophiles (G.A. Cook, 1969). 

Progress has been made toward enantioselective and highly regioselective Michael type alkylations of 2-cyclohexen-l -one using alkylcuprates with chiral auxiliary ligands, e. g., anions of either enantiomer of N-[2-(dimethylamino)ethyl]ephedrine (E. J. Corey, 1986), of (S)-2-(methoxymethyl)pyrrolidine (from L-proline R. K. EHeter, 1987) or of chiramt (= (R,R)-N-(l-phenylethyl)-7-[(l-phenylethyl)iinino]-l,3,5-cycloheptatrien-l-amine, a chiral aminotro-ponimine G. M. Villacorta, 1988). Enantioselectivities of up to 95% have been reported. 

When allene derivatives are treated with aryl halides in the presence of Pd(0), the aryl group is introduced to the central carbon by insertion of one of the allenic bonds to form the 7r-allylpalladium intermediate 271, which is attacked further by amine to give the allylic amine 272. A good ligand for the reaction is dppe[182]. Intramolecular reaction of the 7-aminoallene 273 affords the pyrrolidine derivative 274[183]. 

Carbonylation of the tetrasubstituted bispropargyiic amine 23 using PdCP and thiourea under mild conditions affords the carboxylated pyrrolidine derivatives 24a and b in good yields. Thiourea is regarded as effective for the oxidative carbonylation of alkynes, but no oxidative carbonylation was observed in this case[21]. 

Photoelectron spectroscopic studies show that the first ionization potential (lone pair electrons) for cyclic amines falls in the order aziridine (9.85 eV) > azetidine (9.04) > pyrrolidine (8.77) >piperidine (8.64), reflecting a decrease in lone pair 5-character in the series. This correlates well with the relative vapour phase basicities determined by ion cyclotron resonance, but not with basicity in aqueous solution, where azetidine (p/iTa 11.29) appears more basic than pyrrolidine (11.27) or piperidine (11.22). Clearly, solvation effects influence basicity (74JA288). 

In aqueous solution, azetidine (p/sTa 11.29) is slightly more basic than pyrrolidine and larger-ring cyclic amines and appreciably more basic than aziridine. It forms an addition compound (m.p. - 9 to -6 °C) with trimethylboron which is more stable than that formed by pyrrolidine (50JA2926, 64HC(l9-2)885). Azetidinium salts are well known (Section 5.09.2.2.7). 

An interesting and useful property of enamines of 2-alkylcyclohexanones is the fact that there is a substantial preference for the less substituted isomer to be formed. This tendency is especially pronounced for enamines derived from cyclic secondaiy amines such as pyrrolidine. This preference can be traced to a strain effect called A or allylic strain (see Section 3.3). In order to accommodate conjugation between the nitrogen lone pair and the carbon-carbon double bond, the nitrogen substituent must be coplanar with the double bond. This creates a steric repulsion when the enamine bears a p substituent and leads to a... 

Secondary amines react smoothly with 3-ketones to give enamines and good selectivity is achieved in the presence of 7-, 12-, 17- and 20-ketones. With pyrrolidine the reaction takes place under very mild conditions and no catalyst is usually required. Hydrolysis occurs by simply heating in ethanol. 

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. 

Another interesting fact to be noted is that the bicyclic enamine (87) and its pyrrolidine analogue failed to undergo reduction with 98% formic acid, whereas the pyrrolidine enamine of 2-bicyclo[2.2.1]hepten-5-carboxalde-hyde (94), which exists largely in the transoid form (49), was readily reduced to (95). However, the saturated amine-substituted norbornane can be obtained directly from norbornanone under the more vigorous conditions of the Leuckart reaction (49a). 

Recently Stamhuis et al. (33) have determined the base strengths of morpholine, piperidine, and pyrrolidine enamines of isobutyraldehyde in aqueous solutions by kinetic, potentiometric, and spectroscopic methods at 25° and found that these enamines are 200-1000 times weaker bases than the secondary amines from which they are formed and 30-200 times less basic than the corresponding saturated tertiary enamines. The baseweakening effect has been attributed to the electron-withdrawing inductive effect of the double bond and the overlap of the electron pair on the nitrogen atom with the tt electrons of the double bond. It was pointed out that the kinetic protonation in the hydrolysis of these enamines occurs at the nitrogen atom, whereas the protonation under thermodynamic control takes place at the -carbon atom, which is, however, dependent upon the pH of the solution (84,85). The measurement of base strengths of enamines in chloroform solution show that they are 10-30 times weaker bases than the secondary amines from which they are derived (4,86). 

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