Enamides hydrolysis

The aqueous acidic medium produces the enamide hydrolysis, giving a p-diketone on positions 17-19. 

Asymmetric cyclization using chiral ligands has been studied. After early attempts[142-144], satisfactory optical yields have been obtained. The hexahy-dropyrrolo[2,3-6]indole 176 has been constructed by the intramolecular Heck reaction and hydroaryiation[145]. The asymmetric cyclization of the enamide 174 using (S j-BINAP affords predominantly (98 2) the ( )-enoxysilane stereoisomer of the oxindole product, hydrolysis of which provides the ( l-oxindole aldehyde 175 in 84% yield and 95% ec. and total synthesis of (-)-physostig-mine (176) has been achieved[146]. 

The allyl group was used to protect the nitrogen in a /3-lactam synthesis, but was removed in a four-step sequence. Whether a transition-metal-catalyzed isomerization to the enamide followed by hydrolysis is an effective cleavage procedure remains to be tested and warrants further study. ... 

Asymmetric hydrogenation of a cyclic enamide (Approach B) had very sparse literature precedents [7]. It should also be noted that preparation of these cyclic imines and enamides is not straightforward. The best method for the synthesis of cyclic imines involves C-acylation of the inexpensive N-vinylpyrrolidin-2-one followed by a relatively harsh treatment with refluxing 6M aqueous HC1, which accomplishes deprotection of the vinyl group, hydrolysis of the amide, and decarboxylation (Scheme 8.6) [8]. 

Oxidative conversion of palmatine, berberine, and coptisine to polycarpine, polyberbine, and its analog was described in Section II,B. These products were further transformed to aporphine alkaloids having a phenolic hydroxyl group at C-2 in the bottom ring (55). Hydrolysis with concomitant air oxidation of polyberbine (66) furnished 3,4-dihydrorugosinone, which was further air-oxidized in ethanolic sodium hydroxide to give rise to rugosinone (501) (Scheme 105). Successive reduction of the enamide 68 with lithium aluminum hydride and sodium borohydride afforded a mixture of ( )-norledecorine and (+ )-ledecorine (502). N-Methylation of the former with formaldehyde and sodium borohydride led to the latter. 

The utilization of the Robinson annellation method for the synthesis of cory-nanthe-type alkaloids has been thoroughly investigated by Kametani and coworkers (149-152). The tetracyclic ring system was efficiently formed via the Michael addition of dimethyl 3-methoxyallylidenemalonate (247) to the enamine derived from 3,4-dihydro-1 -methyl-(3-carboline (150). Alkylation of 248, followed by hydrolysis and decarboxylation, resulted in a mixture of stereosiomeric enamides 250 and 251. Hydrogenation of 250 afforded two lactams in a ratio of 2 1 in favor of the pseudo stereoisomer 253 over the normal isomer 252. On the other hand, catalytic reduction of 251 gave 254 as the sole product in nearly quantitative yield. Deprotection of 254, followed by lithium aluminum hydride reduction, yielded ( )-corynantheidol (255) with alio relative configuration of stereo centers at C-3, C-15 and C-20. Similar transformations of 252 and 253 lead to ( )-dihydrocorynantheol and ( )-hirsutinol (238), respectively, from which the latter is identical with ( )-3-epidihydrocorynantheol (149-151.). 

Only few general methods allow for the introduction of a substituent at the C-7 position. However, treatment of cyano-enamide 335 with LiTMP followed by reaction with electrophiles has been successfully used to introduce an alkyl chain at G-7. It is worth noting that the amide obtained by acidic hydrolysis of the cyano-enamide group can be further alkylated to form tricyclic hexahydro-oxazolo[3,2- ]pyridin-5-ones 337 (Scheme 92) <1998JOC1619>. 

A dissociative first step is anticipated exclusively in photolysis of the endo-cyclic enamide 181 (compare also 80 -a- 85 and 173 -> 174). The reaction is formulated through a ketene intermediate 182. The enamine 183 formed then undergoes hydrolysis to give the oxocarboxylic acid derivative 184 as the product. 

The favorable effect of the enamide function on asymmetric induction is indicated not only by the result with compound I, but also by later results summarized in Table I, where optical purities in the range of 70 to 80% were generally obtained for various derivatives of alanine, phenylalanine, tyrosine, and 3,4-dihydroxyphenylalanine (DOPA). The Paris group found that the Rh-(-)-DIOP catalyst yielded the unnatural R or d -amino acid derivatives, whereas l-amino acid derivatives could be obtained with a (+)-DIOP catalyst. Since the optical purity of the IV-acylamino acids can often be considerably increased by a single recrystallization (fractionation of pure enantiomer from racemate) and the IV-acetyl group can be removed by acid hydrolysis, this scheme provides an excellent asymmetric synthesis route to several amino acids. 

Zinc enamides such as 50 are reactive organozinc species, which can undergo addition to unactivated olefins with good to excellent yields. After trapping of the organozinc intermediate 51 with an electrophile and hydrolysis, a variety of functionalized primary, secondary, and tertiary a-alkylated ketones are isolated (Equation (100)).170... 

The pyrylium salts can be easily ring-opened by hydrolysis to yield 1,5-pentene-diones158. Consequently, 4-acylaminopyrylium salts 396 and 397 can be precursors to enamides 395. It should be expected that / -acylaminovinyl ketones (e.g. 207 and 278) obtained by other methods (e.g. by N-acylation of enaminones159,160) can be converted into 3-azapyrylium salts116 and, by the reaction described above, they can undergo the functionalization together with lengthening of the linear carbon chain. 

Similarly, acylation of imine 22 with nicotinoyl chloride afforded enamide 27 when one mole of the acid chloride was used, whereas acylation with an excessive amount of the acid chloride yielded the already cyclized dihydroazaberbine (28) in good yield, which was also obtained from the enamide by acylation (67). Hydrolysis of 28 afforded the corresponding azaberbine (26) (Scheme 26) (6 7). 

By using the p-methoxy-substituted enamide (192), Ninomiya et al. (54) succeeded in a simple synthesis of alloyohimbone (196) via the unconjugated lactam 194, which has an enol ether structure. Lithium aluminum hydride reduction of the lactam 194, followed by hydrolysis with hydrochloric acid and subsequent catalytic hydrogenation over platinum dioxide, yielded alloyohimbone (196) stereoselectively in an overall yield of 59% from harmalane (54) this was the most convenient synthesis of alloyohimbone (196) so far reported (Scheme 75). 

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