Coupling reactions, silyl enol ether

The coupling of an allyl or acyl moiety onto carbon atoms is achieved by anodic oxidation of a-heteroatom substituted organostannanes or Oj -acetals in the presence of allylsilanes or silyl enol ethers. The reaction probably involves carbocations as intermediates that undergo electrophilic addition to the double bond [245c]. 

The in situ cyanosilylation of p-an1saldehyde is only one example of the reaction which can be applied to aldehydes and ketones in general. - The simplicity of this one-pot procedure coupled with the use of inexpensive reagents are important advantages over previous methods. The silylated cyanohydrins shown in the Table were prepared under conditions similar to those described here. Enolizable ketones and aldehydes have a tendency to produce silyl enol ethers as by-products in addition to the desired cyanohydrins. The... 

All alkyl halides used in the couplings were primary, although some of them were branched or had an ester functionality. Some of the dialkylzincs had a functional group without affecting the outcome of the reaction. For example, organozinc derivative 302 with a silyl enol ether group reacted with alkyl iodide 303, affording the desired product 304 in 65% yield (Scheme 153). 

Dialkyl(trimethylsilyl)phosphines undergo 1,4-addition to a,/3-unsaturated ketones and esters to give phosphine-substituted silyl enol ethers and silyl ketene acetals, respectively. A three-component coupling reaction of a silylphosphine, activated alkenes, and aldehydes in the presence of a catalytic amount of GsF affords an aldol product (Scheme 76).290 291... 

The first promising asymmetric aldol reactions through phase transfer mode will be the coupling of silyl enol ethers with aldehydes utilizing chiral non-racemic quaternary ammonium fluorides,1371 a chiral version of tetra-n-butylammonium fluoride (TBAF). Various ammonium and phosphonium catalysts were tried138391 in the reaction of the silyl enol ether 41 of 2-methyl-l-tetralone with benzaldehyde, and the best result was obtained by use of the ammonium fluoride 7 (R=H, X=F) derived from cinchonine,1371 as shown in Scheme 14. 

In all of the cyclization reactions, Moeller has found only a small difference between the use of alkyl and silyl enol ethers. Since both styrenes and enol ethers have similar oxidation potentials, even the styrene moiety could function as the initiator for oxidative cyclization reactions. The anodic oxidation of simple styrene type precursors leads to low yields of cyclized products so that enol ether moiety seems to be the more efficient initiator for intramolecular anodic coupling reactions [93]. 

The cationic iridium complex [Ir(cod)(PPh3)2]OTf, when activated by H2, catalyzes the aldol reaction of aldehydes 141 or acetal with silyl enol ethers 142 to afford 143 (Equation 10.37) [63]. The same Ir complex catalyzes the coupling of a, 5-enones with silyl enol ethers to give 1,5-dicarbonyl compounds [64]. Furthermore, the alkylation of propargylic esters 144 with silyl enol ethers 145 catalyzed by [Ir(cod)[P(OPh)3]2]OTf gives alkylated products 146 in high yields (Equation 10.38) [65]. An iridium-catalyzed enantioselective reductive aldol reaction has also been reported [66]. 

Tin enolates of ketones can be generated by the reaction of the enol acetate 733 with tributyltin methoxide[601] and they react with alkenyl halides via transmetallation to give 734. This reaction offers a useful method for the introduction of an aryl or alkenyl group at the o-carbon of ketones[602]. Tin enolates are also generated by the reaction of silyl enol ethers with tributyltin fluoride and used for coupling with halides[603]. 

The conjugate addition of bis(iodozincio)methane to -unsaturated carbonyl compound gives y-zincio substituted enolate. As shown in equation 31, bis(iodozincio)methane reacts with. v-cis a,/3-unsaturated ketone in the presence of chlorotrimethylsilane to afford the silyl enol ether carrying a C—Zn bond. These zinc-substituted silyl enolates can be used for further coupling reactions (equation 32)54. 

Silyl enol ethers can be dimerized to symmetrical 1,4-diketones by treatment with Ag20 in dimethyl sulfoxide or certain other polar aprotic solvents.465 The reaction has been performed with R2, R-1 = hydrogen or alkyl, though best yields are obtained when R2 = R1 = H. In certain cases, unsymmetrical 1,4-diketones have been prepared by using a mixture of two silyl enol ethers. Other reagents that have been used to achieve either symmetrical or cross-coupled products are iodosobenzene-BFy-EtiO.466 ceric ammonium nitrate,467 and lead tetraacetate.m If R1 = OR (in which case the substrate is a ketene silyl acetal), dimerization with TiCL, leads to a dialkyl succinate (32, R1 = OR).4 9... 

Since silyl enol ethers have a silyl group ji to the jr-system, anodic oxidation of silyl enol ethers takes place easily. In fact, anodic oxidation of silyl enol ethers proceeds smoothly to provide the homo-coupling products, 1,4-diketones (equations 37 and 38)42. This dimerization of the initially generated cation radical intermediate is more likely than the reaction of acyl cations formed by two electron oxidation of unreacted silyl enol ethers in these anodic reactions. 

The TiCU-induced three-component coupling reaction of an a-haloacylsilane, allylsilane and another carbonyl compound gives 48 in good yield. A silyl enol ether intermediate is suggested (equation 31)82. The reaction of a cyclopropyl ketone with allylsilane yields a mixture of skeletal rearranged products83. 

Silyl enol ethers undergo cross-coupling with allylsilane in the presence of a Lewis acid. For example, an oxovanadium(V) complex can induce such condensation reactions (equation 81)150. 

Intramolecular Lewis acid-promoted reaction of coordinated propargylic ether with the silyl enol ether in 158 has been applied successfully to the construction of the highly strained 10-membered cyclic enediyne system 159, present in esperamycin and calicheamycin [39,40]. The enediyne system 157 was prepared by the Pd-catalysed Sonogashira coupling of (Z)-l,2-dichloroethylene (154) with two different terminal alkynes 155 and 156. 

Diones,1 CAN effects cross-coupling between 1,2-disubstituted silyl enol ethers and a 1-substituted silyl enol ether to give a 1,4-dione. The reaction involves oxidation of 1 to a (1-oxo radical,R CHCOR2, which adds to the 1-substituted silyl enol ether (2) to form an adduct that is oxidized to the dione. 

Modem variants of the Mukaiyama aldol addition start from silyl enol ethers, not from enol ethers, and use an aldehyde instead of the acetal as the electrophile. Mukaiyama aldol additions of this kind have been included in the C,C coupling reactions that build the basic repertoire of modem synthetic chemistry and can even be performed in a catalytic enantioselective fashion. 

In contrast, Fleming and coworkers proposed another mechanism involving a Brook rearrangement coupled with desilylative /J-elimination for similar reactions of a-siloxy ketones 131 with phenyldimethylsilyllithium to give silyl enol ethers 132 (equation 87) no trimethylsilyl enol ether 133 was detected in the reaction mixture203. 

Furstner and coworkers found that the McMurry coupling of aroylsilanes 147 gave silyl enol ethers 149 via the Brook rearrangement in addition to the normal McMurry coupling products 148 (equation 94)212. The product ratio 148/149 was dependent on the reaction conditions, especially on the catalyst. The coupling reactions of aliphatic acyltrimethylsilanes were unsuccessful. 

This reaction of cyclohexene with (PhI + )20 2BF4 and lithium perchlorate gave exclusively the cz s-bis-perchlorate adduct (92%). Also, silyl enol ethers underwent efficient oxidative coupling to 1,4-diketones [24] ... 

Under these reaction conditions, adducts of the type 374 can also be obtained by three-component coupling reaction of 2-methoxyaniline with an aldehyde and a silyl enol ether. This method was utilized in a short total synthesis of enantiomerically pure (—)-sedamine 377 from aldehyde 375 via the adduct 376 (Scheme 109).320... 

These silyl enol ethers are probably the best way of carrying out crossed aldol reactions with an aldehyde as the enol partner. An example is the reaction of the enol of the not very enolizable iso-butyraldehyde with the very enolizable 3-phenylpropanal. Mixing the two aldehydes and adding base would of course lead to an orgy of self-condensation and cross-couplings. 

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