Acetals, aldolization-cyclization

Treatment of the ketone (105) with methanolic KOH led to hydrolysis of the acetate group, retro-aldol reaction and aldol cyclization, which eventually afforded a mixture of epimeric alcohols (106) 33). This strategy was used to construct the basic skeletons of various alkaloids, e.g. talatisamine 34), atisine 35) and chasmanine36). 

In the first method, a dialkylzinc reagent bearing an acetal moiety at the d-posi-tion is used (Scheme 7.25(b)). The catalytic 1,4-addition is followed by acetal hydrolysis and aldol cyclization of the 4-substituted cycloalkanone, affording 6,6- (92), 6,7-, (93) and 6,8- (94) annulated ring systems with high enantioselectivities (>96% ees) [80]. In addition, dimethyl-substituted decalone 95, with a structure frequently found in natural products, is readily obtained in enantiomerically pure form. 

Intramolecular Mukaiyama aldol condensation.5 The silyl ketene acetal 1 cyclizes to the tetrahydrofuran 2 in 32% yield on exposure to TiCl4 (1 equiv.) in CH2C12 at 0°. The product is convertible into 3, an analog of cycloleucine. 

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. 

Diacetone alcohol is obtained by the Aldol condensation of two moles of acetone in the presence of barium hydroxide. On dehydration diacetone alcohol yields mesityl oxide, which upon amination gives diacetoneamine. This on treatment with diethyl acetal imdergoes cyclization with the elimination of two moles of ethanol to give vinyl diacetoneamine. The cyclized product on reduction followed by benzoylation and treatment with hydrogen chloride yields benzamine hydrochloride. 

Reaction of thieno[3,4- ] compound 79 (X = Z = CH, Y = S) with acetic acid and polyphosphoric acid resulted in two products the C-3-methylated 477-benzo-l-thia-2,4-diazine 1,1-dioxide 97 (21% yield) and the thienopyridone 98 (33% yield). The latter is considered to be formed by initial acylation at N-4 of the benzo-l-thia-2,4-diazine ring followed by ring cleavage and intramolecular aldol cyclization (Equation 7) <2004JHC45>. 

To extend the scope of the carbometallative aldol cycloreduction, the feasibility of Cu-catalyzed conjugate addition-aldol cyclization process was examined. Cu-catalyzed addition of organozinc compounds to o ,jS-unsaturated carbonyl compounds has been well established (169-171,187-189). Trapping of the Zn-enolates using aldehydes (169,188,190) and acetals/ketals (191) has been reported however, the use of ketones as electrophiles to trap Zn-enolates failed in the absence of strong Lewis acids (191). Rrische and co-workers reported the first successful example of Cu-catalyzed tandem conjugate addition-aldol cyclization with ketones, esters, and nitriles as electrophiles (Scheme 107) (192). In this cyclization process, enone-ketones 237 and 239 afforded products in good to excellent... 

A green chemistry variation makes use of solventless conditions to minimize the waste stream from reactions of this type. To a mortar are added aldehyde 67, ketone 68 and solid sodium hydroxide. The mixture is ground and within 5 minutes aldol product 69 is produced. Addition of the second ketone and further grinding affords the 1,5-diketone 70, which can be isolated and cyclized to pyridine 71 with ammonium acetate. The authors report that this method can substantially reduce the solid waste (by over 29 times) and is about 600% more cost effective than previously published procedures. 

As expected, some sequences also occur where a domino anionic/pericyclic process is followed by another bond-forming reaction. An example of this is an anionic/per-icyclic/anionic sequence such as the domino iminium ion formation/aza-Cope/ imino aldol (Mannich) process, which has often been used in organic synthesis, especially to construct the pyrrolidine framework. The group of Brummond [450] has recently used this approach to synthesize the core structure 2-885 of the immunosuppressant FR 901483 (2-886) [451] (Scheme 2.197). The process is most likely initiated by the acid-catalyzed formation of the iminium ion 2-882. There follows an aza-Cope rearrangement to produce 2-883, which cyclizes under formation of the aldehyde 2-884. As this compound is rather unstable, it was transformed into the stable acetal 2-885. The proposed intermediate 2-880 is quite unusual as it does not obey Bredf s rule. Recently, this approach was used successfully for a formal total synthesis of FR 901483 2-886 [452]. 

The zinc chloride-mediated tandem Mukaiyama aldol-lactonization reaction of aldehydes 21 and thiopyridylketene acetals 22 gave mainly the trans isomer 23. However, if the catalyst is stannic chloride and the reaction is carried out at -78 °C, then the cyclization is highly diastereoselective and yields the cis-isomer 24 <990L1197>. 

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