Enol silyl ethers electrophilic intermediates

As mentioned earlier, metal complexation not only allows isolation of the QM derivatives but can also dramatically modify their reactivity patterns.29o-QMs are important intermediates in numerous synthetic and biological processes, in which the exocyclic carbon exhibits an electrophilic character.30-33 In contrast, a metal-stabilized o-QM can react as a base or nucleophile (Scheme 3.16).29 For instance, protonation of the Ir-T 4-QM complex 24 by one equivalent of HBF4 gave the initial oxo-dienyl complex 25, while in the presence of an excess of acid the dicationic complex 26 was obtained. Reaction of 24 with I2 led to the formation of new oxo-dienyl complex 27, instead of the expected oxidation of the complex and elimination of the free o-QM. Such reactivity of the exocyclic methylene group can be compared with the reactivity of electron-rich enol acetates or enol silyl ethers, which undergo electrophilic iodination.34... 

The wide diversity of the foregoing reactions with electron-poor acceptors (which include cationic and neutral electrophiles as well as strong and weak one-electron oxidants) points to enol silyl ethers as electron donors in general. Indeed, we will show how the electron-transfer paradigm can be applied to the various reactions of enol silyl ethers listed above in which the donor/acceptor pair leads to a variety of reactive intermediates including cation radicals, anion radicals, radicals, etc. that govern the product distribution. Moreover, the modulation of ion-pair (cation radical and anion radical) dynamics by solvent and added salt allows control of the competing pathways to achieve the desired selectivity (see below). 

Snider and Kwon use either cupric triflate and cuprous oxide or ceric ammonium nitrate and sodium bicarbonate as single-electron oxidants to convert d,s- and ,C-unsaturated enol silyl ethers 9 stereoselectively to the tricyclic ketones 14 in excellent yields [83, 84]. Based on comparison with other experimental data and literature results, the authors try to distinguish between several possible intermediates and propose the following mechanism with a very electrophilic radical cation 10 as the key intermediate. 

The equilibrium between a-silyl alkoxides and silojq carbanions can be shifted toward the carbanion side by introduction of a conjugating group into either or both the acylsilane and the nucleophile. In 1980, Reich et al. reported that treatment of all l-substituted acylsilanes with vinyllithium followed by a variety of electrophiles affords a-substituted enol silyl ethers 22 via a siloxy allyllithium intermediate 21 fScheme 8.1Similar reactions using phenyllithium give products in which electrophilic quenching occurred at the benzylic position. 

Hydrosilylation in the presence of a carbon electrophile is often accompanied by C-C bond formation. For example, three-component coupling of hydrosilane, alkyne, and y unsaturated aldehyde is suggested to proceed via oxanickelacycle intermediate to give (Z)-enol silyl ether (Scheme 3-28). Hydrosilylation of alkenes under a carbon monoxide atmosphere allows carbonyl incorporation, giving silyl enol ethers by using a cobalt or iridium catalyst (Schemes 3-29 and 3-30). Under similar reaction conditions in the presence of a rhodium catalyst, alkynes are converted to y silyl-substituted acroleins (Scheme 3-31). ... 

The enolate intermediate, generated by the addition of higher-order cyanocuprates to enones, has been trapped with several electrophiles. Thus the addition of trimethylsilyl chloride, diethyl or diphenyl phosphorochloridate and M-phenyltrifluoro methane-sulphonamide affords the corresponding vinyl silyl ethers, vinyl phosphates and vinyltri-flates. " ... 

A more interesting situation arises with a substituent already on C-5 20. The cuprate then adds anti to that substituent (the intermediate is here trapped as a silyl ether anti-21) and trapping with electrophiles introduces a second anti relationship anti, anti-22. The stereoselectivity arises by axial attack both during the conjugate addition and on the enolate (chapter 21). 

At first, we considered the transformation of the carbamate moiety into more reactive functions. It was shown that Z-O-enecarbamate can be transformed into Z-silyl enol ether 10 by treatment of 8 with methyllithium and quenching of this intermediate lithium enolate 9 by electrophilic silicon reagents. Assuming this lithium enolate intermediate 9 would be able to react with other electrophile reagents, the preparation of more reactive functions including Z-vinyl phosphate and Z-vinyl triflate was considered. The remaining and important question was whether the Z-stereochemistry of this double bond would be preserved. 

Vinyl siloxonium ion 14 also serves as an important intermediate en route to conjugate adducts of unsaturated carbonyl compounds. For example, treatment of cyclohexenone (13) with reactive silyl electrophiles affords y-functionalized silyl enol ethers 15 and 16 suitable for subsequent synthetic transformations (eq 4). The temporary silicon tether (TST) strategy has been updated (2010) by an excellent review focusing upon metal-mediated reactions. The inception of this strategy is attributable to Nishiyama and Itoh who reported the radical cycUzation of acyclic bromomethyl silyl ethers to sUoxanes and their subsequent oxidation to 1,3-diols. Shortly thereafter, the group of Gilbert... 

Silyl enol ethers are powerful intermediates in organic synthesis. Reactions of silyl enol ethers with various electrophiles provide effective methods for the synthesis of various carbonyl compounds. In this section we will briefly touch on the electrochemical reactions of silyl enol ethers and related compounds. The electrochemical behaviour of silyl enol ethers is expected to be closely related to that of allylsilanes and benzylsilanes because silyl enol ethers also have a silyl group ft to the re-system. 

Silyl enol ethers have also been used as a trap for electrophilic radicals derived from a-haloesters [36] or perfluoroalkyl iodides [32]. They afford the a-alkylated ketones after acidic treatment of the intermediate silyl enol ethers (Scheme 19, Eq. 19a). Similarly, silyl ketene acetals are converted into o -pcriluoroalkyl esters upon treatment with per fluoro alkyl iodides [32, 47]. The Et3B/02-mediated diastereoselective trifluoromethylation [48,49] (Eq. 19b) and (ethoxycarbonyl)difluoromethylation [50,51] of lithium eno-lates derived from N-acyloxazolidinones have also been achieved. More recently, Mikami [52] succeeded in the trifluoromethylation of ketone enolates... 

Another rhodium vinylidene-mediated reaction for the preparation of substituted naphthalenes was discovered by Dankwardt in the course of studies on 6-endo-dig cyclizations ofenynes [6]. The majority ofhis substrates (not shown), including those bearing internal alkynes, reacted via a typical cationic cycloisomerization mechanism in the presence of alkynophilic metal complexes. In the case of silylalkynes, however, the use of [Rh(CO)2Cl]2 as a catalyst unexpectedly led to the formation of predominantly 4-silyl-l-silyloxy naphthalenes (12, Scheme 9.3). Clearly, a distinct mechanism is operative. The author s proposed catalytic cycle involves the formation of Rh(I) vinylidene intermediate 14 via 1,2-silyl-migration. A nucleophilic addition reaction is thought to occur between the enol-ether and the electrophilic vinylidene a-position of 14. Subsequent H-migration would be expected to provide the observed product. Formally a 67t-electrocyclization process, this type of reaction is promoted by W(0)-and Ru(II)-catalysts (Chapters 5 and 6). 

The functionalized silyl enol ethers 156 are useful synthetic intermediates since electrophiles can now be introduced either directly in the P-position by known methodology 55) or in the opposition after deprotonation with LDA to an allyl anion (Eq. 70)61>. Both pathways should enormously widen the scope of specifically substituted y-oxoesters and their derivatives obtained via siloxycyclopropanes. 

Second only to lithium enolates in usefulness are silyl enol ethers. Silicon is less electropositive than lithium, and silyl enol ethers are more stable, but less reactive, than lithium enolates. They are made by treating an enolate with a silicon electrophile. Silicon electrophiles invariably react with enolates at the oxygen atom firstly because they are hard (see p. 237) and secondly because of the very strong Si-O single bond. The most common silicon electrophile is trimethylsilyl chloride (Me3SiQ), an intermediate made industrially in bulk and used to make the NMR standard tetramethyl silane (Me4Si). 

The mechanism is very similar the electrophilic sulfur atom attacks the a carbon atom of the silyl enol ether releasing a chloride ion that removes the Me3Si group from the intermediate. 

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 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]. 

Both these silyl enol ethers 50 and 52 could of course be hydrolysed to the saturated aldehydes, but that would be to sacrifice the useful reactivity of these intermediates in aldol and other reactions explored in chapters 2-6. A more productive development is to react the silyl enol ether with an electrophile and hence develop a synthesis from three components in two consecutive reactions.23 This approach has formed the basis of many modern syntheses as it develops the target molecule so quickly and is discussed in chapter 37 under tandem reactions . It is not necessary to trap the enolate with Me3SiCl when lithium cuprates are used with ketones as the lithium enolate is the product of 1,4-addition. You may choose the lithium enolate or the silyl enol ether, whichever is more appropriate for the next step. 

The double bond can be restored after a conjugate addition to an electrophilic alkene if the enolate intermediate 110 is trapped as a silyl enol ether 111 and then combined with a sulfur or selenium electrophile which is later eliminated. Organocuprates are ideal nucleophiles for this process as the intermediate enolate can be trapped as a silyl enol ether and reacted directly with PhSCl or PhSeCl. 

A TMSOTf-initiated cyclization of the dicarbonyl substrate was invoked to explain the reactivity pattern [79]. Selective complexation of the less hindered carbonyl group activates it toward intramolecular nucleophilic attack by the more hindered carbonyl which leads to an oxocarbenium species. Subsequent attack by the enol ether results in addition to the more hindered carbonyl group. The formation of this cyclic intermediate also explains the high stereochemical induction by existing asymmetric centers in the substrates, as demonstrated by Eq. 52, where the stereochemistry at four centers is controlled. A similar reactivity pattern was observed for the bis-silyl enol ethers of / -diketones. The method is also efficient for the synthesis of oxabicyclo[3.3.1] substrates via 1.5-dicarbonyl compounds, as shown in Eq. 53. Rapid entry into more complex polycyclic annulation products is possible starting from cyclic dicarbonyl electrophiles [80]. 

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