Enamines reaction with acrolein

A substituted a,/3-unsaturated aldehyde, cinnamaldehyde, has been observed to undergo the same type of two-step 1,3-cycloaddition reaction with a cyclohexanone enamine as acrolein does, forming in this case a stereo-isomeric mixture of substituted bicycloaminoketones in excellent yield (29a,31a,31b). 

Dihydropyrans have been produced by the 1,3 cycloaddition of methyl vinyl ketone (77) or acrolein (29-J7) with enamines (see Section II.A.2). S-Lactones have been formed as a side product in the reaction of dimethyl ketene with enamines (77), and as the primary products in the reaction of excess ketene with enamines derived from ketones (75) (see Section II.A.4). 

Villsmeier reaction on the dimethylacetal of methoxyacetaldehyde (141) with phosgene and dimethyIformamide affords the acrolein derivative, 142. Condensation of this with guanidine gives the pyrimidine, 143. (The enamine can be viewed as a latent aldehyde-the dimethylamino group is probably lost in the course of an addition elimination reaction with one of the guanidine groups.) This pyrimidine serves as starting material for sulfameter (111). ... 

Another synthesis of Lyral (51) consists of the reaction of myrcene with acrolein to give the myrac aldehyde [37677-14-8] (52). The aldehyde group, which is sensitive to acid hydration conditions with strong acids, has to be protected by formation of the morpholine enamine. The enamine is then hydrolyzed on workup after the acid-catalyzed hydration to produce Lyral (93—95). 

Two-step 1,4 cycloaddition of enamines, such as was observed with methyl vinyl ketone, is not possible with acrylate or maleate esters. This is due to the fact that, following the initial simple substitution, no side-chain carbanion is available for nueleophilic attack on the a carbon of the iminium ion. Likewise two-step 1,3 eycloaddition, such as that found when alicyclic enamines were treated with acrolein, is impossible with acrylate or maleate esters because transfer of the amine moiety from the original enamine to the side chain to form a new enamine just prior to the final cyclization step is not possible. That is, the reaction between a seeondary amine and an ester does not produce an enamine. 

A novel ring closure was discovered by Stork (6) in which the pyrrolidine enamine of a cycloalkanone reacts with acrolein. The scheme illustrates the sequence in the case of 1-pyrrolidino-l-cyclohexene, and the cyclopentane compound was found to undergo the reaction analogously. The procedure details the preparation of the bicyclo adduct and its cleavage to 4-cyclooctenecarboxylic acid. 

In a recently published report by MacMillan s group [121] on the enantioselective synthesis of pyrroloindoline and furanoindoline natural products such as (-)-flustramine B 2-219 [122], enantiopure amines 2-215 were used as organocatalysts to promote a domino Michael addition/cyclization sequence (Scheme 2.51). As substrates, the substituted tryptamine 2-214 and a, 3-unsaturated aldehydes were used. Reaction of 2-214 and acrolein in the presence of 2-215 probably leads to the intermediate 2-216, which cyclizes to give the pyrroloindole moiety 2-217 with subsequent hydrolysis of the enamine moiety and reconstitution of the imidazolid-inone catalyst. After reduction of the aldehyde functionality in 2-217 with NaBH4 the flustramine precursor 2-218 was isolated in very good 90 % ee and 78 % yield. 

Ring-closing metathesis seems particularly well suited to be combined with Passerini and Ugi reactions, due to the low reactivity of the needed additional olefin functions, which avoid any interference with the MCR reaction. However, some limitations are present. First of all, it is not easy to embed diversity into the two olefinic components, because this leads in most cases to chiral substrates whose obtainment in enantiomerically pure form may not be trivial. Second, some unsaturated substrates, such as enamines, acrolein and p,y-unsaturated aldehydes cannot be used as component for the IMCR, whereas a,p-unsaturated amides are not ideal for RCM processes. Finally, the introduction of the double bond into the isocyanide component is possible only if 9-membered or larger rings are to be synthesized (see below). The smallest ring that has been synthesized to date is the 6-membered one represented by dihydropyridones 167, obtained starting with allylamine and bute-noic acid [133] (Fig. 33). Note that, for the reasons explained earlier, compounds... 

This type of reaction is very common in the nitrogen equivalent pyridine system (the ready formation of enamines and the ready availability of 1,3-electrophiles, such as acrolein and their equivalents). With the phosphorus system, the not so common enamine equivalent makes it a not so common synthetic approach. However, with proper substituents 1,3-dinucleophilic P-C(2) fragments have been reacted with 1,3-electrophiles, and have been used in the synthesis of As-phosphinolines <1996CHEC-II(5)639>. 

Because of the conjugation of the free electron pair on the nitrogen atom with the double bond, enamines react very readily with double bonds activated by electronegative groups. Addition of acrolein to l-methyl-2-ethylidenepyrrolidine, followed by dehydrogenation, led to 1,7-dimethylindole.260 In a similar addition to l-methyl-2-alkyl-d2-piperideines, l-methyl-8-alkyl-l,2,3,4-tetrahydroquinolines (75) were obtained.38 In the reaction scheme, the starting bases are considered to react as the tautomeric l-methvl-2-alkvlidenepiperidines (74). 

Problem 23.17 What products would result (after hydrolysis) from reaction of the enamine prepared from cyclopentanone and pyrrolidine with the following a, -unsaturated acceptors (a) Ethyl propenoate (b) Propenal (acrolein)... 

The total synthesis of the phenolic sesquiterpene (+)-parviflorine was accomplished by L.A. Maldonado and co-workers. The key step in the synthetic sequence was the reaction of an enamine with acrolein to form a bicyclic intermediate, which was subjected to a Grob fragmentation to afford the eight-membered ring of the natural product. The bicyclic ketone substrate was refluxed in benzene using a Dean-Stark trap and the resulting enamine was taken to the next step as crude material. 

The observed excellent stereoselectivities (dr=91 9 to >95 5, 94 to >99% ee) could be ascribed to the steric hindrance created by the employed catalyst in each step of the catalytic cycle reported below (Scheme 2.56). Once the chiral amine (S)-70 activates the acrolein 131 as electrophile by generating the vinylogous iminium ion A, the indole 171 performs an intermolecular Friedel-Crafts-type reaction. The resulting enamine B acts as nucleophile in the Michael addition of the nitroalkene 140 leading to the iminium ion D, which upon hydrolysis liberates the catalyst and yields the intermediate aldehyde 173. The latter compound enters in the second cycle by reacting with the iminium ion A, previously formed by the free catalyst. The subsequent intramolecular enamine-mediated aldol reaction of E completes the ring closure generating the intermediate F, which after dehydration and hydrolysis is transformed in the desired indole 172. 

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