Palladium ketene additions

Unsaturated acetals and orthoesters undergo a palladium-catalysed addition of organoalanes (Scheme 32). An jj2 -type displacement is observed and in the case of orthoesters the reaction proceeds to give an ester ketene acetals are not observed. 

Entry 6 is an example of application of the chiral diazaborolidine enolate method (see p. 572). Entry 7 involves generation of the silyl ketene acetal by silylation after conjugate addition of the enolate of 3-methylbutanoyloxazolidinone to allyl 3,3,3-trifluoroprop-2-enoate. A palladium catalyst improved the yield in the rearrangement... 

Addition of ketene silyl acetals to aldehydes and ketones is also mediated by achiral palladium(ll) acetate-diphosphine complexes (Equation (109)).46S,46Sa Although the precise mechanism is still unclear, high catalytic activity may be ascribed to the intermediacy of palladium enolates. 

Cyclization of halogenoaryl-substituted /3-lactams can be mediated by palladium(n) derivatives. The formation of the lactam from a ketene-imine addition and subsequent cyclization of the product can be carried out as a one-pot process. As an example, in situ generation of the ketene from the acid chloride and formation of the /3-lactam followed by addition of palladium(ll) acetate, triphenylphosphine, and thalium carbonate gave 495 in 54% yield (Equation 79) <1995TL9053>. 

CONJUGATE ADDITION (3-Bromopropion-aldehyde ethylene acetal. 1-r-Butylthio-1 -trimethylsilyloxyethylene. Cryptates. l-EthylsuIfinyl-3-pentanone. HexamethyF phosphoric triamide. Ketene bis-(methylthio)ketal monoxide. Organo-lithiuni compounds. Palladium(II) chloride. Phase-transfer catalysts. 

Copper-, rhodium-, palladium-, and ruthenium-catalyzed cyclopropanation with diazoacetic esters is possible for a wide range of electron-rich alkenes, including alkylated acyclic alkenes, cycloalkenes, styrenes, 1,3-dienes, enol ethers, enol acetates, and ketene acetals (examples are given in this section, in Houben-Weyl Vol.E19b, ppl099-1155 and in refs 2, 152, 155 and 184). Furthermore, the construction of cyclopropanes with additional strain is possible, for example ... 

Cyclopropane formation can be dramatically enhanced by addition of Ai,iV,Af, A -tetrame-thylethylenediamine as an additional ligand or cosolvent. This was first reported in stoichiometric conversions of 7r-allylpalladium complexes and can also be applied to palladium-catalyzed processes." Thus allyl bromides with ketene acetals in the presence of thallium(I) acetate and 7i-allylpalladium(II)(TMEDA) acetate as catalyst gives cyclopropanes 9 with trans geometry of the substituents." " Similar results are observed with platinum catalysts vide infra). 

A reported diastereoselective synthesis of precursor A of vitamin D3 involved the use of 2-methylcyclopent-2-enone as starting material. The Mukaiyama-Michael conjugate addition of ketene acetal 269 in the presence of trityl hexachloroaniimonate afforded the adduct 270. The lateral chain was introduced, according the procedure of Tsuji, by the treatment of crude 270 with allyl carbonate and palladium dibenzylideneacetone " (Scheme 63). The expected product 271 was obtained in 63% yield from 269. Reduction of 271 with LAH afforded a mixture of diols that was selectively tosylated at the primary hydroxy group. The secondary hydroxy group was protected with the methoxymethyl group and further functional modifications afforded the lactone 272. The reaction of lithium dimethyl methylphosphonate with the lactone 272 completed the synthesis of the AB-des-cholestane derivative 273. 

At the time the chemistry of main group enolates flourished already for a while, that of late transition metals had a shadowy existence in synthetic organic chemistry. Their stoichiometric preparation and the sluggish reactivity - tungsten enolates, for example, required irradiation to undergo an aldol addition [24a] - did not seem to predestine them to become versatile tools in asymmetric syntheses [27]. The breakthrough however came when palladium and rhodium enolates were discovered as key intermediates in enantioselective catalyses. After aldol reactions of silyl enol ethers or silyl ketene acetals under rhodium catalysis were shown to occur via enolates of the transition metal [8] and after the first steps toward enantioselective variants were attempted [28], palladium catalysis enabled indeed aldol additions with substantial enantioselectivity... 

The protocols for the utilization of ketone-derived silyl enol ethers in Tsuji-Trost reactions were preceded by a report of Morimoto and coworkers on the enantioselective allylation of sUyl ketene acetals 88. Without external activation, they reacted with the allylic substrate 19d in the presence of the palladium complex derived from the amidine ligand 89 to give y,5-unsaturated esters 90 in moderate chemical yield but high enantiomeric excess (Scheme 5.29) [46]. Presumably, the pivalate anion hberated during the oxidative addition functions as an activator of the silyl ketene acetal. The protocol is remarkable in view of the fact that asymmetric allylic alkylations of carboxylic esters are rare. Interestingly, the asymmetric induction originates from a ligand with an uncomplicated structure. The protocol seems however rather restricted with respect to the substitution pattern of allylic component and sUyl ketene acetal. 

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