Aminals alkylation reactions, pyrrolidine

At higher temperatures the mixture of 10 and methyl vinyl ketone yields the 1,4-carbocyclic compound as described previously. Methyl isopropenyl ketone (5), ethyl acetylacrylate (d), 2-cyclohexenone (21), and 1-acetyl-1-cyclohexene (22) also undergo this type of cyclization reaction with enamines at higher temperatures. This cycloalkylation reaction occurs with enamines made of strongly basic amines such as pyrrolidine, but the less reactive morpholine enamine combines with methyl vinyl ketone to give only a simple alkylated product (7). Chlorovinyl ketones yield pyrans when allowed to react with the enamines of either alicyclic ketones or aldehydes (23). 

Catalytic hydrogenation of (23-12) over palladium on charcoal results in the scission of the weak N—O bond and the formation of amino alcohol (24-1). This is converted to a pyrrolidine by an internal alkylation reaction. Thus, reaction of the intermediate with carbon tetrabromide and triphenyl phosphine presumably converts the alcohol to a bromide internal displacement by the primary amine forms the five-membered ring (24-2). Alkylation of that amine with the complex bromo amide (24-3) then affords the endothehn antagonist atrasentan (24-4) [25]. 

Condensation of ethyl anthranHates with isothiocyanates provides entry to a closely related compound in which the carbonyl at the 2 position is replaced by a thione. The sequence starts with the alkylation of pyrrolidine nitrogen in (92-1) with 2-bromoethylamine. Reaction of the primary amine in the product (92-2) with thiophosgene leads to the isothiocyanate derivative (92-3). Reaction of that reactive intermediate with methyl anthranilate (92-4) leads initially to the transient... 

Oxidative reactions at carbon predominate in the biotransformation of cyclic amiiies, and an important consequence of this is often the cleavage of the carbon-nitrogen bond. For example, A-dealkylation of N- alkyl substituted pyrrolidine (or piperidine, morpholine, etc.) involves an initial oxidative attack at the a- alkyl carbon atom to yield an N hydroxyalkyl derivative (carbinolamine), which is then metabolized to a secondary amine and the corresponding aldehyde. The metabolic conversion of nicotine to nornicotine (30 see Scheme 3) probably involves this mechanism, although the iminium ion (31) has also been suggested as an intermediate in the biotransformation (76JMC1168). Carbinolamines are unstable intermediates and have been identified only in a few cases, e.g. A-hydroxymethylcarbazole... 

Enamines are the stable products of a similar reaction between secondary amines (such as pyrrolidine or morpholine) and aldehydes and ketones.218 These vinylamines are reactive reagents of value in synthesis they function as specific enol equivalents of carbonyl compounds, readily undergoing alkylation and acylation processes (e.g. Section 5.9.2, p. 632). 

A ruthenacyclopentane 48 has been proposed as an intermediate in this reaction, after coordination of the allene and enone. Exocyclic /1-hydride elimination led to the 1,3-dienes. This ruthenacycle possessed a o-bound ruthenium allyl, allowing nucleophilic additions by alcohols or amines. Alkylative cycloetherification [29] (Eq. 20) and synthesis of pyrrolidine and piperidine [30] were thus achieved. 

These A -alkylations are potentially applicable to the preparation of nitrogen heterocy-cles. For examples, reactions of amines with 1,5-pentadiol [136], 1,4-pentadiol [137], or 2-butyne-1.4-diol [138] give A -alkyl piperidine, pyrrolidine, or pyrrole, respectively, in high yield (Scheme 10.16). 

Azomethine yUdes. These ylides can be prepared from A -alkylglycine" or. V-alkyl(trimethylsilylmethyl)amines by reaction with (HCHO) . The reactive species are trapped as 1,3-dipolar cycloadducts, namely, and 3,4-disubstituted pyrrolidines. 

In 2004, Vignola and List [111] demonstrated the ability of proline-derived catalysts to overcome drawbacks associated with the stoichiometric alkylation of preformed aldehyde enolates when they described an elegant amino acid catalyzed intramolecular a-alkylation reaction of haloaldehydes. The reaction furnished substituted cyclopentanes, cyclopropanes, and pyrrolidines in good yields and good enantio-selectivities (Scheme 8.23), when commercially available (5)-a-methyl proline (LV) as catalyst was used. The presence of a stoichiometric amount of additional base (tertiary amine) was required, not only to trap the hydrogen halide produced in the reaction but also because it has also significant effect on the stereoselectivity of the C—C bond-formation process by stabilizing the ant/ -TS of the /ra 5-enamine intermediate. Nevertheless, an intermolecular version of the reaction remains still elusive, mainly because of the deactivation of the amine catalyst by A -alkylation with the alkyl halide [112]. 

Finally, Kibayashi used aqueous versions of the intramolecular acyl-nitroso Diels-Alder reaction to good effect in his stereocontrolled syntheses of (-)-swainsonine (6.28) [78] and (-)-pumiliotoxin C (6.34) [79] (Schemes 1.13 and 1.14). In each case, oxazinolactam cycloadducts (cf. 6.32 and 6.38) served as key functional chiral building blocks for the remaining synthetic operations. For example, retrosynthetic analysis of the trihydroxy-indohzidine system of swainsonine (6.28) reveals that the pyrrolidine ring of this target can be formed by amine alkylation (cf. 6.29) while the vicinal diol can be installed via substrate-controlled cw-hydroxylation of a (Z)-allyl... 

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. 

Replacement of the ketone by an amide leads to Increased potency. Hydrolysis of nitrile, 133 (obtained by alkylation of diphenylacetonitrile with the morpholine analog of the chloro-amine used in the original preparation of methadone), affords acid, 134. Conversion to the acid chloride followed by reaction with pyrrolidine affords racemoramide (135) Separation of the (+) isomer by optical resolution gives dextromoramide, an analgesic an order of magnitude more potent than methadone. 

Inclusion of the carbon atoms of an aromatic ring in the side chain sequence is apparently quite consistent with antlmalarial activity. Thus, reaction of p-acetamidophenol with formaldehyde and diethylamine affords the Mannich product, 79. This is then converted to the diamine (80) by saponification. Alkylation with the chloroquinoline, 70, affords amidoquine (81). The same sequence starting with the Mannich product in which pyrrolidine has been used as the amine (82) gives amopyroquine (83). 

When enamines are treated with alkyl halides, an alkylation occurs that is analogous to the first step of 12-14. Hydrolysis of the imine salt gives a ketone. Since the enamine is normally formed from a ketone (16-12), the net result is alkylation of the ketone at the a position. The method, known as the Stork enamine reaction is an alternative to the ketone alkylation considered at 10-105. The Stork method has the advantage that it generally leads almost exclusively to monoalkylation of the ketone, while 10-105, when applied to ketones, is difficult to stop with the introduction of just one alkyl group. Alkylation usually takes place on the less substituted side of the original ketone. The most commonly used amines are the cyclic amines piperidine, morpholine, and pyrrolidine. 

The carbonylation of the sp3 C-H bond adjacent to a nitrogen atom is also possible by means of chelation-assisted C-H bond activation.121 The carbonylation reaction of A-(2-pyridyl)pyrrolidine occurs at the a-position of the pyrrolidine ring by using [RhCl(cod)]2 as a catalyst and 2-propanol as a solvent. Cyclic amines exhibit a high reactivity (up to 84%) (Equation (93)), while acyclic amines show relatively low reactivity (18%). The use of Ru3(CO)i2 as a catalyst does not result in a carbonylation reaction, but instead the addition of the sp3 C-H bond across the olefin bond to give an alkylation product, as mentioned before (Section 10.05.4). 

Aromatic amines RNH2 (R = Ph, 2-MeCgH4 or 4-MeOCgH4) are phenylated by triphenylbismuth in the presence of 0.5 equivalent of copper(II) acetate to yield diarylamines RNHPh. Butylamine yields a mixture of TV-butylaniline and N-butyldiphenylamine in this reaction and piperidine gives TV-phenylpiperidine36. A similar alkylation of the secondary amines pyrrolidine, piperidine and morpholine with trimethylbismuth or tris(2-phenylethyl)bismuth in the presence of copper(II) acetate affords tertiary amines, e.g. 14. The reaction proceeds by way of transient pentavalent bismuth compounds37. 

After epoxidation of the terminal olefin in syn-89 the pyrrolidine 91 was formed by reductive cleavage of the Cbz-protection and concomitant Sn2 cyclization of the free amine to epoxide 90. In five additional steps (+)-preus-sin (2) was synthesized with an overall yield of 19%. After AT-methoxycar-bonylation and oxidation of the alcohol to an aldehyde the alkyl side chain was introduced by a Wittig reaction. 

N-Methyl-, N-ethyl, N-isopropyl- and N-ferf-butyl-pyrrolidines, which are readily available from the reaction of dichloro- or dibromobutanes and their corresponding amines, all gave N-alkyl dichloropentathiepinopyrroles 214 as the main products in low-to-moderate yield (16-31%). Additionally,... 

Many synthetic methods have been reported for the pyrrolidine alkaloids, including procedures based on the Hofmann-Loffler reaction 132,412), the metal hydride reduction of pyrrolines 413,414), the a-alkylation of N-nitro-sopyrrolidine 412,415), the catalytic hydrogenation of pyrroles 133), the reductive amination of 1,4-diketones 25,138), the direct alkylation of 1-methoxy-carbonyl-3-pyrroline 416), the versatile synthesis from the Lukes-Sorm dilac-... 

This reaction can furthermore be applied on chiral aminals, affording a straightforward route to optically pure frawi-2,5-pyrrolidines or chiral alkyl-substituted 1,3-oxazoUdines. This method was used for the en an tio selective synthesis of substituted piperidines . 

The dibasic side chain at position 7 can be alternatively provided by a substituted amino alkyl pyrrolidine. Preparation of that diamine in chiral form starts with the extension of the ester function in pyrrolidone (46-1) by aldol condensation with ethyl acetate (46-2). Acid hydrolysis of the (3-ketoester leads to the free acid that then decarboxylates to form an acetyl group (46-3). The carbonyl group is next converted to an amine by sequential reaction with hydroxylamine to form the oxime, followed by catalytic hydrogenation. The desired isomer (46-4) is then separated... 

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