Silyl enol ethers, oxidative coupling

This vanadium method enables the cross-coupling only in combinations of silyl enol ethers having a large difference in reactivity toward radicals and in their reducing ability. To accomplish the crosscoupling reaction of two carbonyl compounds, we tried the reaction of silyl enol ethers and a-stannyl esters based on the following consideration. a-Stannyl esters (keto form) are known to be in equilibrium with the enol form such as stannyl enol ethers, but the equilibrium is mostly shifted toward the keto form. When a mixture of an a-stannyl ester such as 45 and a silyl enol ether is oxidized, it is very likely that the stannyl enol ether will be oxidized preferentially to the silyl enol ether. The cation radical of 45 apparently cleaves immediately giving an a-keto radical, which reacts with the silyl enol ether selectively because of the low concentration of the stannyl enol... 

Phophonate Pinacol coupling Reductive deconjugation Ring-opening oxidation Silyl enol ether Silyl ketene acetal Tautomerism Vanadium bromoperoxidase Vanadium catalyst Vinyl phosphonate... 

When identical silyl enol ethers are used in the coupling reaction (Rj = R/, R = R ), homocoupling to symmetrical 1,4-diketones can be achieved (Scheme 11). For the synthesis of unsymmetrical 1,4-diketones, the two silyl enol ethers must differ significantly in terms of their oxidation potentials. This can be realized by selecting monosubstituted silyl enol ethers (R = H) and 1,2-disubstituted silyl enol ethers for the coupling reaction. Another possible way to reduce the oxidation potential is by the use of mesomeric stabilization vide supra).In the coupling reactions presented so far, the reactivity of silyl enol ethers is twofold. The component that is more easily oxidized forms the radical cation and consequently the a-carbonyl radical. In contrast, the second component acts as an electron-rich double bond in the radical addition reaction. 

Schafer reported that the electrochemical oxidation of silyl enol ethers results in the homo-coupling products. 1,4-diketones (Scheme 25) [59], A mechanism involving the dimerization of initially formed cation radical species seems to be reasonable. Another possible mechanism involves the decomposition of the cation radical by Si-O bond cleavage to give the radical species which dimerizes to form the 1,4-diketone. In the case of the anodic oxidation of allylsilanes and benzylsilanes, the radical intermediate is immediately oxidized to give the cationic species, because oxidation potentials of allyl radicals and benzyl radicals are relatively low. But in the case of a-oxoalkyl radicals, the oxidation to the cationic species seems to be retarded. Presumably, the oxidation potential of such radicals becomes more positive because of the electron-withdrawing effect of the carbonyl group. Therefore, the dimerization seems to take place preferentially. 

Since enol silyl ethers are readily accessible by a number of methods in a regioselective manner and since the trialkylsilyl moiety as a potential cationic leaving group facilitates the termination of a cyclization sequence, unsaturated 1-trialkylsilyloxy-1-alkenes represent very promising substrates for radical-cation cyclization reactions. Several methods have been reported on the synthesis of 1,4-diketones by intermolecular oxidative coupling of enol silyl ethers with Cu(II) [76, 77], Ce(IV) [78], Pb(IV) [79], Ag(I) [80] V(V) [81] or iodosoben-zene/BFa-etherate [82] as oxidants without further oxidation of the products. 

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]. 

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. 

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. 

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] ... 

The low oxidation potentials of stannyl compounds gave us a clue to develop the selective cross-coupling reaction between the a-posi-tions of two carbonyl compounds. Generally, silyl enol ethers or ketene silyl acetals are employed for this purpose to prepare 1,4-di-... 

The stemona alkaloid stemonamide (49) was synthesized starting from a-stannyl acetate 47 and 2-stannyl pyrrolidine 48. The oxidative coupling of stannyl acetate 47 with acetylenic silyl enol ether affords the functionalized C-7 unit which corresponds to the side arm of the pyrrolidine ring. Then, introduction of the C-7 unit to the pyrrolidine ring is performed by the oxidative generation of acyliminium ion. The carbon skeleton of stemonamide was thus constructed efficiently as shown in Scheme 19 by employing organotin compounds. ... 

Oxidative coupling of silyl enol ethers as a useful synthetic method for carbon-carbon bond formation has been known for a long time. Several oxidants have been successfully applied to synthesize 1,4-diketones from silyl enol ethers, e.g. AgjO [201], Cu(OTf)2 [202], Pb(OAc)4 [203] and iodosobenzene/BFj EtjO [204]. Although some of these reagents above are known to react as one-electron oxidants, the potential involvement of silyl enol ether radical cations in the above reactions has not been studied. Some recent papers, however, have now established the presence of silyl enol ether radical cations in similar C-C bond formation reactions under well-defined one-electron oxidative conditions. For example, C-C bond formation was reported in the photoinduced electron transfer reaction of 2,3-dichIoro-1,4-naphthoquinone (98) with various silyl enol ethers 99 [205], From similar reactions with methoxy alkenes [206,207] it was assumed that, after photoexcitation, an ion radical pair is formed. 

The key element of this protocol is the initial addition of cationic electrophiles such as rerr-alkyl or acyl cations to the double bond of a DCHC complex of the conjugated enyne 118, which results in the formation of the substituted propargylic cation intermediate 119, Subsequent reaction with pre-selected external nucleophiles, for example allylsilanes or silyl enol ethers, leads to the formation of the final adducts 120. The reaction is carried out as a one-pot, three-component coupling and can be used for the creation of two novel C-C bonds. It is a process somewhat complementary to the stepwise Michael addition described earlier (Scheme 2.31), with a reverse order of E and Nu addition. Oxidative decomplexation of 120 yields the product 121. The overall... 

The corresponding silyl enol ethers are likewise readily available carbonyl umpolmg substrates which can be oxidized by a variety of chemical oxidants and also by cathodic oxidation. If not trapped by nucleophiles, the radical cations can dimerize and subsequently hydrolyze to give 1,4-dicarbonyl (homo)coupling products [195]. 

Aliphatic amines are mainly converted to a-substituted products [99,100], whereby especially the a-methoxylation leads to valuable reagents for synthesis. The intermediate iminium salts can be directly trapped by silyl enol ethers to form Mannich bases [108]. If the a-position is blocked or steric conditions favor it, N,N coupling to hydrazo or azo compounds occurs (Table 5, numbers 17-19). 1,1-Disubstituted hydrazines are dimerized to tetrazenes in fair to excellent yields (Table 5, numbers 20-24). The intermediate diaze-nium ions can attack enolizable carbonyl compounds to form aza-Mannich bases [109]. Arylazonaphthols undergo anodic oxidation, producing radical cations. These couple to biphenylbisazo compounds (up to 34%) or can be trapped by anisidine to form azodiphe-nylamines (up to 74%) [110a]. 

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 total synthesis of (+)- -onocerin via four-component coupling and tetracyclization steps was achieved in the laboratory of E.J. Corey. The farnesyl acetate-derived acyl silane was treated with vinyllithium, which brought about the stereospecific formation of a (Z)-silyl enol ether as a result of a spontaneous Brook rearrangement. In the same pot, the solution of I2 was added to obtain the desired diepoxide via oxidative dimerization. 

Oxidative cyclization. The one-electron oxidant converts a silyl enol ether into electron acceptor. Interaction with a nucleophilic moiety in the same molecule leads to cyclized product. Unsymmetrical coupling of silyl enol ethers is also realized. 

This ligand coupling method was quite efficient for acetophenone and rerf-butylketone derivatives. However, coupling of the TMS ether of cyclohexanone (121) failed. The oxidative coupling of the TMS ether of cyclohexanone (121) to give 2,2 -bicyclohexanone was successful only when this silyl enol ether was treated with the iodosobenzene-tetrafluoroborate complex.230,231... 

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