Ketones, addition derivatives defined

Samarium enolates 60 can be easily prepared by reduction of ct-bromocarboxylic acid esters with SmT. These enolates mediated well-defined synthesis of star-shaped block co-polymers 61 (Scheme 21 ).32 32l Sml3 also mediated the formation of samarium enolates. Phenacyl thiocyanate 6233 and cr-haloketone 6434 are converted to samarium(lll) enolate intermediates 63 and 65, respectively, which undergo addition to benzaldehyde derivatives affording the corresponding oy i-unsaturatcd ketones as shown in Schemes 22 and 23. 

Boron enolates bearing menthol-derived chiral ligands have been found to exhibit excellent diastereo- and enantio-control on reaction with aldehydes34 and imines.35 Highly diastereo- and enantio-selective aldol additions of geometrically defined trichlorosilyl ketone enolates (31) and (32) have been achieved by promoting the reactions with chiral Lewis bases, of which (,S., S )-(33) proved to be the most effective.36 Moderate enantiomeric excesses have been achieved by using chiral ammo alcohols as catalysts for the Baylis-Hillman condensation of aldehydes with methyl vinyl ketone the unexpected pressure effect on the reaction has been rationalized.37... 

The addition reactions of hydrazinesprovide a number of useful solid derivatives of well-defined melting point, such as the phenylhydrazones, the 2,4-dinitrophenylhydrazones (Scheme 3.45a) and the semicarbazones (Scheme 3.45b). These are used to characterize aldehydes and ketones. In each case the reaction takes place at the most nucleophilic nitrogen. 

Evans et al. recently reported the use of structurally well-defined Sn(II) Lewis acids for the enantioselective aldol addition reactions of a-heterosubstituted substrates [47]. These complexes are readily assembled from Sn(OTf)2 and C2-symmetric bis(oxazoline) ligands. The facile synthesis of these ligands commences with optically active 1,2-diamino alcohols, which are themselves readily available from the corresponding a-amino acids. The Sn(II)-bis(oxazoline) complexes were shown to function optimally as catalysts for enantioselective aldol addition reactions with aldehydes and ketone substrates that are suited to putatively chelate the Lewis acid. For example, use of 10 mol % Sn(II) catalyst, thioacetate, and thiopropionate derived silyl ketene acetals added at -78 °C in dichloromethane to glyoxaldehyde to give hydroxy diesters in superb yields, enantioselectivity, and diastereoselectivity (Eq. 27). The process represents an unusual example wherein 2,3-ant/-aldol adducts are obtained stereoselec-tively. 

Nickel-catalyzed ketone and aldehyde hydrosilylations have been developed with well-defined Ni(II) hydrides using phosphine anilide ligands (Scheme 3-84). This process is tolerant of a variety of functional groups including aryl halides. In mechanistically distinct processes, nickel(O) complexes of NHCs were shown to catalyze ketone hydrosilylations using carbohydrate-derived silanes in a process that allows reductive glycosylations of ketones. Chemoselectivity of the latter method was optimal in the presence of Ti(OR)4 additives. 

The next stage of the synthesis required reduction of the Cj-Cs double bond with control over stereochemistry at Cs- The tactics ultimately used to accomplish this transformation involved conjugate addition of thiophenoxide to the enone to provide 58 with Cj stereochemistry that was never established. The critical stereochemistry (Cs), however, was clean and presmnably controlled by kinetic protonation of the intermediate enolate. Reduction of the C9 ketone was followed by esterification to provide acetate 59 as a single stereoisomer (C7 stereochemistry still not defined). Reduction of the C7 thiol was followed by excision of the extra carbon in the usual manner to provide aldehyde 60. The final carbons of the seco- dA were introduced via crossed condensation of the enolate derived from a thioester of propionic acid, with aldehyde 60. This reaction provided the proper stereochemistry at C3, but the undesired stereoisomer at C2. The C2 stereochemistry was corrected by kinetic protonation of the enolate derived from 61 with acetic acid. The structure of the resulting seco-zcid derivative (62) was established by X-ray crystallography. 

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