Silylation kinetics

C-Silylation. Depending on the reaction conditions, secondary amides can be either C-silylated or A -silylated. Kinetic C-silylation of IV-methylacetamide can be quantitatively achieved by treatment with excess TMSOTf (3 equiv) and EtsN (3 equiv) at 0 °C for 2 min, followed by aqueous work-up (eq 44). ... 

The ketone is added to a large excess of a strong base at low temperature, usually LDA in THF at -78 °C. The more acidic and less sterically hindered proton is removed in a kineti-cally controlled reaction. The equilibrium with a thermodynamically more stable enolate (generally the one which is more stabilized by substituents) is only reached very slowly (H.O. House, 1977), and the kinetic enolates may be trapped and isolated as silyl enol ethers (J.K. Rasmussen, 1977 H.O. House, 1969). If, on the other hand, a weak acid is added to the solution, e.g. an excess of the non-ionized ketone or a non-nucleophilic alcohol such as cert-butanol, then the tautomeric enolate is preferentially formed (stabilized mostly by hyperconjugation effects). The rate of approach to equilibrium is particularly slow with lithium as the counterion and much faster with potassium or sodium. 

The 9 — 15 fragment was prepared by a similar route. Once again Sharpless kinetic resolution method was applied, but in the opposite sense, i.e., at 29% conversion a mixture of the racemic olefin educt with the virtually pure epoxide stereoisomer was obtained. On acid-catalysed epoxide opening and lactonization the stereocentre C-12 was inverted, and the pure dihydroxy lactone was isolated. This was methylated, protected as the acetonide, reduced to the lactol, protected by Wittig olefination and silylation, and finally ozonolysed to give the desired aldehyde. 

A more economical route to MQ resin uses low cost sodium sihcate and trimethylchlorosilane as inputs (eq. 35) (395). The sodium sihcate process is initiated by acidifying an aqueous sodium sihcate solution to a pH of 2. The resulting hydrosol quickly builds molecular weight. The rate of this increase is moderated by the addition of an alcohol such as 2-propanol. The hydrosol is subsequentiy silylated by the addition of trimethylchlorosilane. This process, which is kinetically sensitive and limited to synthesizing M/Q ratios of 1 or less, is preferred when MQ resins having high (>1%) OH content are required (395). 

Alkylation of pyrazinones and quinoxalinones may be carried out under a variety of conditions and it is usually observed that while O-alkylation may occur under conditions of kinetic control, to yield the corresponding alkoxypyrazines or alkoxyquinoxalines, under thermodynamic control the A-alkylated products are formed. Alkylation using trialkyl-oxonium fluoroborate results in exclusive O-alkylation, and silylation under a variety of conditions (75MI21400) yields specifically the O-silylated products. Alkylation with methyl iodide or dimethyl sulfate invariably leads to A-methylation. 

The Ireland-Claisen reaction of ( )-vinylsilanes has been applied to the stereoselective synthesis of syn- and c/nti-2-substituted 3-silyl alkcnoic acids. a R-2-Alkyl-3-silyl acids are prepared by rearrangement of ( )-silyl ketene acetals which are generated in situ from the kinetically formed (Z)-enolate of the corresponding propionate ester40. Chelation directs the stereochemistry of enolization of heteroelement-substituted acetates in such a way that the syn-diastereomers are invariably formed on rearrangement403. 

The diastereomeric ratio of the trimethylsilyl triflate catalyzed amidoalkylation of a number of silyl enol ethers at — 40 CC appears to be dependent on the substituents in the substrate87. At — 40 °C the diastereomeric ratio is shown to be kinetically controlled. On allowing the reaction mixture to warm to 20 "C slow epimerization, increasing the amount of the minor isomer, is observed. In the case of the naphthalene derivative, sodium methoxide catalyzed epimerization of the kinetic mixture [(antijsyn) 88 12] produces the thermodynamic mixture [(antijsyn) 9 91]. 

One-pot tandem sequences involving 1,4-addition and ISOC as the key steps have been developed for the construction of N and 0 heterocycles as well as of carbocycles [44]. In this sequence, the nitronate arising from 1,4-addition to an a, -unsaturated nitro alkene is trapped kinetically using trimethyl silyl chloride (TMSCl). The resulting silyl nitronate underwent a facile intramolecular 1,3-dipolar cycloaddition with the unsaturated tether (e.g.. Schemes 20-22). 

The penicillin-N,S-acetal 479 reacts with N,N-bis(trimethylsilyl)formamide 22c and Hg(OAc)2, apparently via the iminium salt 480, to give the penicillin-N,N-acetal 481 in 65% yield [64]. On treatment of racemic y-ketoesters such as 482 with chiral silylated 1,3-mercaptoalcohols such as 483, in the presence of TMSOTf 20, at room temperature a kinetically controlled 2 1 mixture of the 0,S-acetals... 

The major breakthrough in the development of such RsE species was achieved several years ago by Sekiguchi et al., who reported the isolation and full identification of a homologous series of (t-Bu2MeSi)3E (E = Si, Ge, Sn) radicals without Jt-bond conjugation. " All of these radicals, kinetically and thermodynamically stabilized by the bulky electropositive silyl substituents, were prepared by the same very simple and straightforward method, which clearly danonstrated the generality of this synthetic approach. 

Methyl 1-phenylthiovinyl ketones can also be used as enones in kinetically controlled Robinson annulation reactions, as illustrated by Entry 6. Entry 7 shows a annulation using silyl enol ether as the enolate equivalent. These reactions are called Mukaiyama-Michael reactions (see Section 2.6.3). 

The kinetic advantages of IMDA additions can be exploited by installing temporary links (tethers) between the diene and dienophile components.132 After the addition reaction, the tether can be broken. Siloxy derivatives have been used in this way, since silicon-oxygen bonds can be readily cleaved by solvolysis or by fluoride ion.133 The silyl group can also be used to introduce a hydroxy function by oxidation. 

The first of the few low-temperature methods for the formation of an o-QM was a method developed by Rokita.5 It is principally used for reversible DNA alkylation. However, it has recently begun to find its way into some synthetic applications. It utilizes a silylated phenol, which proves vastly more manageable as an o-QM precursor than the corresponding o-hydroxyl benzyl halide (Fig. 4.6). In this kinetically controlled process, expulsion of a benzylic leaving group is triggered at low temperature by treatment with a fluoride ion, which causes a (3-elimination. 

Y(03SCF3)3 to afford a monoaminoalkylation product in good yield in aqueous media.40 Zinc tetrafluoroborate is also highly effective for such couplings in aqueous THF.41 Kobayashi also reported a Mannich-type reaction of imines with silyl enolates catalyzed by neutral salts such as sodium triflate in water as a suspension medium. Unusual kinetic behavior indicates that the presence of the Mannich adduct facilitates the rate of its formation.42... 

After extensive experimentation, it was discovered that exposure of silyl ether (+)-97 to potassium trithiocarbonate and trifluoroacetic acid in dichloromethane affords a 25 7 1 mixture of endolendo endo/exo exo/exo bisdithiepanethione products, reflecting a ca. 5 1 preference for nucleophilic approach from the endo-face of each diketopiperazine moiety. Resubjection of the isolated bisdithiepanethione diastereomers to the original reaction conditions did not result in their equilibration, indicating that the products were a result of kinetic trapping. 

When furans were tethered to silyl enol ethers at the 2-position, spiroannulation also occurred at the 2-position under electrochemical conditions <06CC194>, as exemplified below. The formation of the kinetic products is the result of the higher nucleophilicity of the furan C2-position. 

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