Silyl enol ethers chlorotrimethylsilane

Yields in the acyloin condensation can be improved by running the reaction in the presence of chlorotrimethylsilane MesSiCl, in which case the dianion 36 is converted to the bis silyl enol ether 38, which can be isolated and subsequent )... 

In a separate, dry, 1-L, two-necked, round-bottomed flask fitted to a nitrogen bubbler and equipped with a magnetic stirring bar and a septum inlet is added a solution of 12.6 g (60.0 mmol) of 2-(hydroxymethylene)cyclododecanone (Note 4) in 500 mL of anhydrous ether. The stirred ethereal solution of the hydroxymethylene ketone is treated at 22°C with 33 mL of a freshly prepared mixture (1/1, v/v) of chlorotrimethylsilane and triethylamine (Note 5). An immediate reaction takes place with deposition of a white precipitate. The mixture is stirred thoroughly at 22°C for 15 min to insure complete conversion to the silyl enol ether. 

Conjugate reduction.1 This stable copper(I) hydride cluster can effect conjugate hydride addition to a,p-unsaturated carbonyl compounds, with apparent utilization of all six hydride equivalents per cluster. No 1,2-reduction of carbonyl groups or reduction of isolated double bonds is observed. Undesirable side reactions such as aldol condensation can be suppressed by addition of water. Reactions in the presence of chlorotrimethylsilane result in silyl enol ethers. The reduction is stereoselective, resulting in hydride delivery to the less-hindered face of the substrate. 

A different approach towards titanium-mediated allene synthesis was used by Hayashi et al. [55], who recently reported rhodium-catalyzed enantioselective 1,6-addition reactions of aryltitanate reagents to 3-alkynyl-2-cycloalkenones 180 (Scheme 2.57). In the presence of chlorotrimethylsilane and (R)-segphos as chiral ligand, alle-nic silyl enol ethers 181 were obtained with good to excellent enantioselectivities and these can be converted further into allenic enol esters or triflates. In contrast to the corresponding copper-mediated 1,6-addition reactions (Section 2.2.2), these transformations probably proceed via alkenylrhodium species (formed by insertion of the C-C triple bond into a rhodium-aryl bond) and subsequent isomerization towards the thermodynamically more stable oxa-jt-allylrhodium intermediates [55],... 

A route involving trapping the enolate as a silyl enol ether, subsequent transme-tallation to the corresponding lithium enolate and alkylation turned out to be more efficient (Scheme 18.41) [123]. Thus, treatment of 120 with the cuprate 124 and chlorotrimethylsilane furnished the silyl enol ether 125, which was then converted into the desired enprostil derivative 127 with 68% yield over both steps by reaction with methyllithium and the allenic triflate 126. 

Methyllithium (4.0 mmol, 1.0 M in diethyl ether, 4.0 mL) was added to a suspension of CuCN (2.0 mmol, 0.18 g) in THF (10 mL) at -75°C. The reaction mixture was then stirred until a clear solution was obtained and allowed to warm to room temperature. The appropriate (Z)-vinylic telluride A (2.0 mmol) or B (1.0 mmol) was added and stirred for 45 min. The solution was cooled back to -75°C and the corresponding enone (2.2 mmol) was added. After 20 min, chlorotrimethylsilane (2.6 mmol, 0.60 g) diluted in THF (5 mL) was added. The reaction mixture was stirred for 1 h, allowed to warm to room temperature and then treated with 1 1 solution of saturated aqueous NH4CI and NH4OH (20 mL), extracted with ethyl acetate (3x20 mL), dried, evaporated and the residue was purified by Kiigelrohr distillation affording the silyl enol ethers. 

MeOC6H4, respectively. The titanium enolates were converted into silyl enol ethers 54 by treatment with chlorotrimethylsilane and lithium isopropoxide. Additionally, cyclic enones lb and Ic, and linear enones Id and le, are also good substrates for the asymmetric conjugate addition of phenyltitanium triisopropoxide, giving the corresponding arylation products with over 97% enantioselectivity. 

The feasibility of a deprotonation of cyclohexanone derivatives bearing a chiral heterocyclic substituent in the 4-position with the C2-symmetric base lithium bis[(/f)-l-phenylethyl]amide with internal quenching of the lithium enolate formed with chlorotrimethylsilane is shown in entries 32 and 33 of Table 229,25a. The silyl enol ethers are obtained in a diastereomeric ratio of 79.5 20.5. By using lithium bis[(1S)-l-phenylethyl]amide the two diastereomers are formed in a ratio of 20 80 indicating that the influence of the chirality of the substituent is negligible. 

Enantioselective deprotonation can also be successfully extended to 4,4-disubstituted cyclohexanones. 4-Methyl-4-phenylcyclohexanone (3) gives, upon reaction with various chiral lithium amides in THF under internal quenching with chlorotrimethylsilane, the silyl enol ether 4 having a quaternary stereogenic carbon atom. Not surprisingly, enantioselectivities are lower than in the case of 4-tm-butylcyclohexanone. Oxidation of 4 with palladium acetate furnishes the a./i-unsaturated ketone 5 whose ee value can be determined by HPLC using the chiral column Chiralcel OJ (Diacel Chemical Industries, Ltd.)59c... 

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. 

The first reference to 2-trimethylsilyloxy-l,3-butadiene (1) was a report2 of its reaction with tetracyanoethylene by Cazeau and Frainnet without mention of any experimental details. Later, Conia3 reported its synthesis in 50% yield with only a reference made to the usual House procedure4 for silyl enol ethers. The diene 1 has also been prepared using lithium diisopropylamide as base and chlorotrimethylsilane in tetrahydrofuran-ether (1 1) in yields up to 65%, but on a smaller scale.s... 

The combinations of chlorotrimethylsilane-hexamethylphosphoramide (HMPA) or chlorotrimethylsi-lane-4-(dimethylamino)pyridine (DMAP) are also powerful accelerants for copper(I)-catalyzed Grignard conjugate additions,33 and stoichiometric organocopper and homocuprate additions (Scheme 21 ).36 However, these reactions must be performed in tetrahydrofuran instead of ether.37 These procedures are noted for their high yields with stoichiometric quantities of Grignard reagents, excellent chemoselectivity and efficiency with a,3-unsaturated amides and esters and enals.58 Typically, additions to enals proceed via the S-trans conformers to afford stereo-defined silyl enol ethers for example, enals (122) and (124) give the ( )-silyl enol ether (123) and (Z)-silyl enol ether (125), respectively. 

A much more general synthesis of these silyl enol ethers, however, is based on the reductive cleavage of the carbon-sulphur bond of the silyl enol ether of a thiolester using sodium metal and chlorotrimethylsilane, once again in a silyl acyloin reaction (Scheme 22)97,98. 

A number of a,/J-unsaUiraled acyl silanes have been prepared from silyl enol ethers of acyl silanes (Scheme 41)129. Addition of phenyl sulphenyl chloride to the silyl enol ether with subsequent elimination of chlorotrimethylsilane gives the a-(phenylthio)acyl silane. Oxidation to the sulphoxide followed by in situ elimination of benzenesulphenic... 

At this point, consideration was next accorded to proper introduction of the pair of substituents as in 34. As expected, the regiocontrolled introduction of a methyl group proved not to be problematic, and lithium diisopropylamide came to be favored as the base. The p isomer 29 predominted by a factor of 5 1 over the a isomer for the usual steric reasons (Scheme 5). To reach silyl enol ether 31, it was most efficient and practical to react the 29/30 mixture with chlorotrimethylsilane under thermodynamic conditions. This step proved to be critical, as it allowed for implementation of the Lewis acid-catalyzed acetylation of 31 under conditions where the benzyloxy substituent was inert. Equally convenient was the option to transform the modest levels of enol acetate produced competitively back to starting ketone by saponification with methanolic potassium hydroxide. 

Mukaiyama found that Lewis acids can induce silyl enol ethers to attack carbonyl compounds, producing aldol-like products.22 The reaction proceeds usually at -78 °C without selfcondensation and other Lewis acids such as TiCl4 or SnCI4 are commonly used. The requisite silyl enol ether 27 was prepared by treatment of ketone 13 with lithium hexamethyl disilazide (LiHMDS) and trapping the kinetic enolate with chlorotrimethylsilane. When the silyl enol ether 27 was mixed with aldehyde 14 in the presence of BF3-OEt2 a condensation occurred via transition state 28 to produce the product 29 with loss of chlorotrimethylsilane. The induced stereochemistry in Mukaiyama reactions using methylketones and a, -chiral aldehydes as substrates... 

For example, condensation of silyl enol ether (3.21) of 3-pentanone with 2-methylbutanal in the presence of TiC gives the Ti-complex 3.22, which on hydrolysis yields an aldol product, manicone (4,6-dimethyl-4-octen-3-one) (3.23), an alarm pheromone. Treatment of 3-pentanone with LDA results in the formation of an enolate, which is trapped with chlorotrimethylsilane to give 3.21. Other Lewis acids such as tin tetrachloride (SnCU) and boron trifluoride etherate (BF3-OEt2) can also be used. 

The stable, well-characterized copper(I) hydride cluster [(PPh3)CuH]6 is a useful reagent for conjugate reduction of a,p-unsaturated carbonyl compounds. o This hydride donor is chemically compatible with chlorotrimethylsilane, allowing formation of silyl enol ethers via a reductive silation process (Scheme 53). 

The main deficiencies with the preceding approaches are that only arylene-amines give good yields (and there are other routes to 5-arylimidazolcs), and since unsubstituted vinylamines (R = H Scheme 4.3.3) are not available this means that 4- and 5-unsubstituted imidazoles are not accessible. An alternative route involving silyl enol ethers (6) has been reported to overcome these deficiencies (Scheme 4.3.4). Silyl enol ethers can be made either by treating a ketone with chlorotrimethylsilane and triethylamine in DMF solution, or by sequential reactions of the ketone with LDA and chlorotrimethylsilane in 1,2-dimethoxyethane. This normally gives a mixture in which the less highly substituted enol ether is the major product (enolate formation is kinetically controlled) [25], When (6) is heated with an At-chloroamidine for 12-24h in chloroform solution in the presence of an equimolar amount of dry pyridine 1,2-disubstituted (5) (R = H) or 1,2,5-trisubstituted (5) imidazoles are... 

Trapping. The enolate generated from the enone shown below reacts at oxygen with chlorotrimethylsilane in the presence of triethylamine to produce the trimethylsilyl enol ether. Silyl enol ethers are valuable intermediates for the preparation of regiode-fmed enolates (see Chapter 6). 

Cycloaddition of methyl chloromethylene carbene to silyl enol ethers is the first step in a short sequence to ring-expand cyclic ketones to a-methylcyclo-alkenones [equation (20)]. Thermal elimination of chlorotrimethylsilane com-... 

The reaction of a-bromoketones with first lithium diisopropyl amide and then with chlorotrimethylsilane yields trimethylsilyl enol ethers quantitatively, and within a few minutes [295]. Pyrolysis of trimethylsilyl p keto esters affords high yields of silyl enol ethers [296], e.g. Eq. 3.130 ... 

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