Hydroxyketones cyclic

The 1,6-difunctional hydroxyketone given below contains an octyl chain at the keto group and two chiral centers at C-2 and C-3 (G. Magnusson, 1977). In the first step of the antithesis of this molecule it is best to disconnect the octyl chain and to transform the chiral residue into a cyclic synthon simultaneously. Since we know that ketones can be produced from add derivatives by alkylation (see p. 45ff,), an obvious precursor would be a seven-membered lactone ring, which is opened in synthesis by octyl anion at low temperature. The lactone in turn can be transformed into cis-2,3-dimethyicyclohexanone, which is available by FGI from (2,3-cis)-2,3-dimethylcyclohexanol. The latter can be separated from the commercial ds-trans mixture, e.g. by distillation or chromatography. 

These reductions of lactols with Et3SiH 84b in combination of BE3 -OEt2, TfOH, or TMSOTf 20 have become standard reactions for synthesis of cyclic ethers [62-69]. Thus even co-hydroxyketones such as 1837 cyclize readily with excess EtsSiH 84b in the presence of TMSOTf 20, in high yields, via the lactols 1838, to give cyclic ethers such as the substituted oxepane 1839 in 90% yield [65] (Scheme 12.18). 

As an extension of this work, the same authors explored such methodology for the synthesis of 2,6-disubstituted dihydropyrans using secondary homopropargylic alcohols (Scheme 10, route E). Surprisingly, the treatment of pent-4-yn-2-ol and 3-methylbutanal in the presence of FeCls led to unsaturated ( )-(3-hydroxyketone and ( )-a,p-unsaturated ketone in 2.5 1 ratio and 65% yield, without any trace of the expected Prins-type cyclic product (Scheme 22) [36]. To test the anion influence in this coupling, FeCE and FeBrs were used in a comparative study for the reaction of pent-4-yn-2-ol (R = R" = H, = Me) and several aldehydes. A range of aldehydes except for benzaldehyde was transformed into unsaturated (3-hydroxy-ketones in moderate to good yields. 

The well established chemistry of acyclic secondary-alkyl peroxides 12> suggested that bases should catalyse the isomerization of related bicyclic peroxides to cyclic hydroxyketones 62 via abstraction of bridgehead hydrogen and heterolysis of the peroxide bond (Eq. 48). 

The reaction of ADC compounds with carbenes and their precursors has already been discussed in Section IV,A- In general, the heterocyclic products are not the result of 1,2-addition but of 1,4-addition of the carbene to the —N=N—C=0 system.1 Thus the ADC compound reacts as a 4n unit in a cheletropic reaction leading to the formation of 1,3,4-oxadiazolines. Recent applications include the preparation of spiro-1,3,4-oxadiazolines from cyclic diazoketones and DEAZD as shown in Eq. (14),133 and the synthesis of the acyl derivatives 85 from the pyridinium salts 86.134 The acyl derivatives 85 are readily converted into a-hydroxyketones by a sequence of hydrolysis and reduction reactions. 

Cyclic thiourea derivatives like l,3,4,5-tetramethylimidazole-2(3H)-thione— prepared by condensation of substituted thioureas with a-hydroxyketones—can be converted into the corresponding imidazolin-2-ylidene by desulfurization with sodium or potassium [Eq. (23)]. This method was used to prepare and isolate l,3-bis-neo-pentylbenzimidazolin-2-ylidene with Na/K. With LDA as the base it is also possible to generate free benzimidazolin-2-ylidenes in solution. ... 

The products obtained in tetrahydropyran-2-one reactions with RLi were mixtures of the corresponding hydroxyketones and their cyclic tautomers (90JA2746). In CDCI3 solution, when R = Me, Kj = 0.22 when R = Bu, Kj = 0.2 and when R = Ph, Kj = 0.1. 

TS-1 zeolites have been used in the presence of H2O2 to perform the BV reaction on cyclic and aromatic ketones . Cyclohexanone and acetophenone can be oxidized at 80 °C with selectivities lower that 60%, due to the formation of a-hydroxyketones and other undesired products. The observed modest results seem to be associated with the poor selectivity of the active Ti-peroxo species. In this respect, Corma and coworkers developed new Sn-based heterogeneous catalysts able to selectively activate the ketone instead of 11202 . Cyclic ketones are transformed into the corresponding lactones and unsaturated cyclic ketones like 110 are oxidized to unsaturated lactones in very high chemoselectivitjf , unusual for other oxidizing systems (equation 75). As expected, the authors failed to detect the presence of metal-peroxo derivatives in their systems . ... 

Terashima et al. 231) reported an asymmetric halolactonization reaction. This highly stereoselective reaction permits the synthesis of intermediates for the preparation of chiral a,a-disubstituted a-hydroxycarboxylic acids (227)231c), a-hydroxyketones (228) 231c), functionalized epoxides (229) 231d,e) and natural products 231h,j). Only amino acids have so far been used as a source of the chiral information in the asymmetric halolactonization reaction. Again, the best results have been obtained by using cyclic imino acid enantiomers, namely proline. 

All y- and <5-hydroxyaldehydes and -hydroxyketones are in equilibrium with their cyclic hemiacetals, the position of equilibrium depending on... 

In 1974, David18 reported that cyclic stannylenes (97), formed by reaction of 1,2-diols (96) with dibutyltin oxide— -Bu2SnO—in refluxing benzene with azeotropic elimination of water, reacted with Br2 in solution at room temperature at titrating speed, leading to a-hydroxyketones (98). 

Just recently, a cyclo-cyanosilylation has been described321. Ryu and his coworkers have taken dicyanodimethylsilane (J>43)310) as a reagent under the conditions of the common cyanosilylation and obtained cyclic silyl enol ether (544,545) when (S-hydroxyketones or j8-diketones were employed (Scheme 87). 

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