Lactones diols

Removal of the unsaturated side-chain appendage from C-8 in 22 provides diol lactone 23 and allylic bromide 24 as potential precursors. In the synthetic direction, a diastereoselective alkylation of a hydroxyl-protected lactone enolate derived from 23 with allylic bromide 24 could accomplish the assembly of 22, an intermediate that possesses all of the carbon atoms of PGF2o- It was anticipated that preexisting asymmetry in the lactone enolate would induce the... 

Ag2C03/Celite (Fetizon s reagent) (silver carbonate on Celite) Hexane benzene chloroform RT, Reflux 2 alcohol—) ketone diols—) lactones... 

RT 1° alcohol—) aldehyde 2° alcohol—) ketone diol-) lactone Cleaves 1,2-diols Sulphides—) sulphones... 

Racemic hydroxy ester 225 was converted, via a Sharpless kinetic resolution, to the enantiomerically pure epoxide 226. This epoxide was then converted to the diol "/-lactone by intramolecular attack of the ester, assisted by nucleophilic dealkylation with iodide ion. Deprotonation and methylation anti to the alkoxide followed by acetonide formation afforded 227 in 56% yield. Dibal reduction, protection of the resulting aldehyde as the terminal olefin, silylation of the tertiary alcohol, and liberation of the aldehyde via ozonolysis provided a 45% yield of the C-9 to C-15 fragment 228. 

Chiraldex B -PM Carboxylic acids, alcohols, barbital s, diols, lactones, terpines and tertiary amines. 

Complementary to the oxidative diol lactonization approach, a substrate containing both ketone and ester functionalities may undergo reduction to liberate the desired lactone product following ring closure. Noyori and coworkers demonstrated that Ru-BINAP complexes were excellent catalysts for the asymmetric reduction of ketones with neighboring carboxylic acid and ester functionalities capable of undergoing the desired lactonization in high yields and selectivities (Scheme 2.50) [103, 104],... 

The intramolecular oxidative earbonylation has wide synthetie applieation. The 7-lactone 247 is prepared by intramolecular oxycarbonylation of the alke-nediol 244 with a stoichiometric amount of Pd(OAc)2 under atmospheric pres-sure[223]. The intermediate 245 is formed by oxypalladation, and subsequent CO insertion gives the acylpalladium 246. The oxycarbonylation of alkenols and alkanediols can be carried out with a catalytic amount of PdCl2 and a stoichiometric amount of CuCb, and has been applied to the synthesis of frenolicin(224] and frendicin B (249) from 248[225]. The carbonylation of the 4-penten-l,3-diol 250, catalyzed by PdCl2 and CuCl2, afforded in the c -3-hydroxytetrahydrofuran-2-aeetie acid lactone 251[226J. The cyclic acetal 253 is prepared from the dienone 252 in the presence of trimethyl orthoformate as an accepter of water formed by the oxidative reaction[227]. 

Lipase-catalyzed intermolecular condensation of diacids with diols results in a mixture of macrocycUc lactones and liuear oligomers. Interestingly, the reaction temperature has a strong effect on the product distribution. The condensation of a,(D-diacids with a,(D-dialcohols catalyzed by Candida glindracea or Pseudomonas sp. Upases leads to macrocycUc lactones at temperatures between 55 and 75°C (91), but at lower temperatures (<45°C) the formation of oligomeric esters predorninates. Optically active trimers and pentamers can be produced at room temperature by PPL or Chromobacterium viscosum Upase-catalyzed condensation of bis (2,2,2-trichloroethyl) (+)-3-meth5ladipate and 1,6-hexanediol (92). 

Chiral Alcohols and Lactones. HLAT) has been widely used for stereoselective oxidations of a variety of prochiral diols to lactones on a preparative scale. In most cases pro-(3) hydroxyl is oxidized irrespective of the substituents. The method is apphcable among others to tit-1,2-bis(hydroxymethyl) derivatives of cyclopropane, cyclobutane, cyclohexane, and cyclohexene. Resulting y-lactones are isolated in 68—90% yields and of 100% (164,165). 

The reaction involves nucleophilic substitution of for OR and addition of R MgX to the carbonyl group. With 1,4-dimagnesium compounds, esters are converted to cyclopentanols (40). Lactones react with Grignard reagents and give diols as products. 

The next key step, the second dihydroxylation, was deferred until the lactone 82 had been formed from compound 80 (Scheme 20). This tactic would alleviate some of the steric hindrance around the C3-C4 double bond, and would create a cyclic molecule which was predicted to have a greater diastereofacial bias. The lactone can be made by first protecting the diol 80 as the acetonide 81 (88 % yield), followed by oxidative cleavage of the two PMB groups with DDQ (86% yield).43 Dihydroxylation of 82 with the standard Upjohn conditions17 furnishes, not unexpectedly, a quantitative yield of the triol 84 as a single diastereoisomer. The triol 84 is presumably fashioned from the initially formed triol 83 by a spontaneous translactonization (see Scheme 20), an event which proved to be a substantial piece of luck, as it simultaneously freed the C-8 hydroxyl from the lactone and protected the C-3 hydroxyl in the alcohol oxidation state. 

Cleavage of the imidazolidine moiety by acidic hydrolysis led to chiral lactols 17, which can be further oxidized to lactones 19 or reduced to diols 1848. 

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