Lactams, conjugated preparation

The above bicyclization could be extended to functionalized diynes, permitting the preparation of lactams or lactones having a fused exocyclic conjugated diene, a representative example of which is shown in Eq. 9.53 [98],... 

Tautomerism involving substituents is not favored and even the 3-hydroxy compounds for which lactam tautomers can be proposed (Scheme 3) react exclusively in the conjugated from. Thus N-ethyl-l,2,5-oxadiazol-3(2/ -one (49) is prepared via a 3-silyloxy derivative rather than by direct alkylation of lactam (50) <93T5905>. 

While sluggish under thermal conditions,274-275 the asymmetric conjugate addition of amines to alkyl crotonates is achieved at room temperature under high pressure (15 kbar).276 Thus, benzylamine can be added to the crotonate derived from 8-p-naphthyl menthol, with virtually complete diastereoselectivity. A related intramolecular 1,4-addition of an amine to a chiral enoate was used in a total synthesis of the alkaloid (-)-tylophorine.277 Additions of amines to chiral iron complexes of type (116) proceed with excellent selectivity and allow the preparation of homochiral p-lactams.l27128,l3() l32 In contrast, the addition of amine nucleophiles to chiral vinylic sulfoxides278-2811 and to chiral vinylsulfoximines281 proceeds with comparably low selectivities. 

With the procedure for constructing the quaternary carbon stereocenter in hand, the conversion of the ris-form to the trans form was explored in accordance with the synthetic plan shown in Scheme 9. The ketone moiety of the 1,4-conjugated adduct 61 was protected by an acetal group, followed by decarboxylation of compound 65 using sodium ethylthiolate to yield lactam trans-62 and cis-62 as an 8 1 diastereomixture [31]. The reason why the lactam trans-62 was obtained as a major product is that the subsequent protonation after decarboxylation proceeded kinetically. This assertion is supported by experimental results in which the trans- and cis-lactam diastereomixture (8 1) in ethanol was refluxed in the presence of potassium hydroxide to afford a 1 5 mixture [15,32,33]. The mixture of the lactam trans-62 and cis-62 was reduced with DIBALH, followed by treatment with sodium hydroxide to give bicyclic enamine 63. The kinetic iminium salt prepared from bicyclic enamine 63 with hydrochloric acid was reduced with sodium cyanoborohydride, leading to the frans-decahydroisoquinoline structure [22], The acetal moiety of the resultant 67 was removed to provide the objective ketones 68a and 2c. This method enabled the construction of the tra s-decahydroisoquinoline structure without an intermediate resembling the neurotoxic MPTP, and in fewer steps. 

This strategy allows the preparation of macrocyclic carbinols, lactones, and lactams. For example, highly regioselective and stereoselective macrocyclization has been found for ketoprofen-tetrahydrofuran (THF) conjugates, due to exclusive H-abstraction from the less-substituted carbon and a preferred cisoid ring junction over the transoid junction (Scheme 9.40) [67]. 

An extension and expansion upon this process was reported by Marco and co-workers in their preparation of conjugated 8-lactams via the RCM of unsaturated amides <02T1185> (Scheme 22). Excellent yields are observed when the reacting alkene is unsubstituted. No RCM is observed, however, when the reacting alkene is internally substituted (isobutenyl), even with... 

Propargyl alcohol was first monoaminocarbonylated leading to 4-hydroxy-2-ynamide 111. This first stage is followed in situ by conjugate addition of dialkylamine to the triple bond of the ynamide to yield 112 which gives spontaneously an intramolecular lactonization to afford the furanone 113. Similarly, lactams have been prepared using propargyl amines [99]. 

The synthesis of unnatural (+)-mesembrine (387) through the asymmetric synthesis of methyl (i )-l-[(3,4-dimethoxy)phenyl]-4-oxocyclohex-2-enyl acetate (390) by cycloaddition of enantiomerically pure vinyl sulfoxide with dichloroketene has been performed 189) (Scheme 43). Vinyl sulfoxide 388 [prepared by conjugate addition of enantiopure acetylenic sulfoxide with (3,4-dimethoxy)phenylcopper] reacted with trichloroacetyl chloride in the presence of freshly prepared zinc-copper couple in THF at 0°C to produce a mixture of mono- and dichloro lactones 389. Reduction of 389 with zinc in acetic acid followed by cyclization and methylation afforded methyl IR-[(3,4-dimethoxy)phenyl]-4-oxocyclohex-2-enyl acetate (390), treatment of which with methylamine brought about amidation and concomitant intramolecular Michael addition to provide 2-oxo-mesembrine (391). Successively, 391 was transformed to (+)-mesembrine (387) in 79% yield (three steps ketalization of an oxo group, reduction of lactam, and deketali-zation)(/S9). 

The precursor to amidoacrolein 64, 1,3-dioxin 66, was prepared as follows [39] the imine derived from the condensation of 2,2-dimethyl-l,3-dioxan-5-one with aminoacetaldehyde dimethyl acetal was acetylated with acetic anhydride/triethylamine to afford dioxin 66 in 83% yield (Scheme 24). Retro Diels-Alder of dioxin 66 in warm benzonitrile (120 C, 16 h) generated the amidoacrolein 64, which was trapped in situ with the silyloxydiene 65 to afford the desired cycloadduct 63 (64%). An aldol cyclization between the acetamide and neighboring aldehyde functionalities within 63 proceeded smoothly (2 equiv. of KCh-Bu, 10 equiv. of EtOAc, THF, 0 °C, 40 min) and directly afforded the corresponding conjugated lactam. This product was of sufficient purity for the second aldol reaction, which was best accomplished under acidic conditions, presumably proceeding through the achiral keto aldehyde intermediate 62 enroute to the desired, but racemic, (3-hydroxy ketone 61 obtained in 79% yield after the two consecutive ring closures. 

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