Silyl enol ethers methyl ketone-derived

Alkenes react in a similar fashion giving methoxymethyl derivatives, but in this case the intermediate carbenium ion is trapped with methoxide or another nucleophile such as a nitrile to afford the methyl ether or amide in a Ritter-like reaction (eq 11). In similar fashion, silyl enol ethers give ketones (eq 12), allyl-silanes afford homologated alkenes (eq 13), and stannylalkynes are converted to propargyl ethers. ... 

Silyl enol ethers of alkenyl methyl ketones can be efficiently cyclized to cyclopentenones and cyclohexenones by treating them with stoichiometric amounts of palladium acetate244 an example indicating the elaboration of this approach to the synthesis of a reduced benzoxepinone derivative, and the suggested244 mechanism of the reaction, are depicted in Scheme 174. 

The Simmons-Smith reaction has been used as the basis of a method for the indirect a methylation of a ketone.1065 The ketone (illustrated for cyclohexanone) is first converted to an enol ether, e.g., by 6-6, or to an enamine (6-14) or silyl enol ether (2-23). Application of the Simmons-Smith reaction gives the norcarane derivative 106, which is then cleaved... 

Use of the preformed Z-silyl enol ether 18 results in quite substantial anti/syn selectivity (19 20 up to 20 1), with enantiomeric purity of the anti adducts reaching 99%. The chiral PT-catalyst 12 (Schemes 4.6 and 4.7) proved just as efficient in the conjugate addition of the N-benzhydrylidene glycine tert-butyl ester (22, Scheme 4.8) to acrylonitrile, affording the Michael adduct 23 in 85% yield and 91% ee [10]. This primary product was converted in three steps to L-ornithine [10]. The O-allylated cinchonidine derivative 21 was used in the conjugate addition of 22 to methyl acrylate, ethyl vinyl ketone, and cydohexenone (Scheme 4.8) [12]. The Michael-adducts 24-26 were obtained with high enantiomeric excess and, for cydohexenone as acceptor, with a remarkable (25 1) ratio of diastereomers (26, Scheme 4.8). In the last examples solid (base)-liquid (reactants) phase-transfer was applied. 

The silicon-carbon double-bonded intermediates generated photo-chemically from a-alkenyldisilane derivatives react with both enolizable and nonenolizable ketones to give olefins (98). For instance, the photolysis of a-styrylpentamethyldisilane (49) in the presence of one molar equivalent of acetone gives l-trimethylsilyl-2-phenyl-3-methyl-2-butene in 13% yield as a single product. No silyl enol ether to be expected from the reaction of the intermediate with the enol form of acetone is observed. Similar irradiation of 49 with acetophenone affords (E)- and (Z)-l-trimeth-... 

This is a mild, simple and practical procedure for 1,4-addition of an aldehyde to methyl vinyl ketone, without converting the aldehyde into an enamine or a silyl enol ether. The products, substituted 5-ketoaldehydes, are important compounds, especially for the preparation of substituted 2-cyclohexen-1-one derivatives, which have been versatile starting materials for syntheses of natural products such as terpenoids. These 5-ketoaldehydes have been prepared previously by the 1,4-addition of modified aldehydes, i.e., morpholinoenamines of aldehydes,trimethylsilyl enol ethers of aldehydes in the presence of a Lewis acid, or diethylallylamine in the presence of a catalytic amount of a Ru complex, to methyl vinyl ketones. 

Mukaiyama aldol reactions of various silyl enol ethers or ketene silyl acetals with aldehydes or other electrophiles proceed smoothly in the presence of 2 mol % B(CgF5)3 [151a,c]. The following characteristic features should be noted (i) the products can be isolated as j8-trimethylsilyloxy ketones when crude adducts are worked-up without exposure to acid (ii) this reaction can be conducted in aqueous media, so that the reaction of the silyl enol ether derived from propiophenone with a commercial aqueous solution of formaldehyde does not present any problems (iii) the rate of an aldol reaction is markedly increased by use of an anhydrous solution of B(C6Fs)3 in toluene under an argon atmosphere and (iv) silyl enol ethers can be reacted with chloromethyl methyl ether or trimethylorthoformate hydroxymethyl, methoxy-methyl, or dimethoxymethyl Cl groups can be introduced at the position a to the carbonyl group. These aldol-type reactions do not proceed when triphenylborane is used (Eq. 92). 

This sequence transforms acyclic ketones and aldehydes into a-methylene ketones and a-methyl-a,)5-unsaturated ketones and aldehydes It has been illustrated by the synthesis of eucarvone, ( )-nuciferal and ( )-manicone This ring-opening of chlorosiloxycyc-lopropanes with ClSiMea elimination appears to be a practical route to Z or a,)5-ethylenic aldehydes and ketones depending on the stereochemistry of the reactants. For example, conversion in MeOH-NEta at 20°C of the 2-chloro-2-methyl-3-pentyl-l-trimethylsiloxycyclopropanes (derived from the addition of the chloromethylcarbene to the E and Z silyl enol ethers of n-heptanal) leads either to or Z 2-methyl-oct-2-enal (equation 65). ... 

Given this problem, the attachment of the butanone synthon to aldehyde 74 prior to the methyl ketone aldol reaction was then addressed. To ovenide the unexpected. vTface preference of aldehyde 74, a chiral reagent was required and an asymmetric. syn crotylboration followed by Wacker oxidation proved effective for generating methyl ketone 87. Based on the previous results, it was considered unlikely that a boron enolate would now add selectively to aldehyde 73. However, a Mukaiyama aldol reaction should favour the desired isomer based on induction from the aldehyde partner. In practice, reaction of the silyl enol ether derived from 87 with aldehyde 73, in the presence of BF3-OEt2, afforded the required Felkin adduct 88 with >97%ds (Scheme 9-29). This provides an excellent example of a stereoselective Mukaiyama aldol reaction uniting a complex ketone and aldehyde, and this key step then enabled the successful first synthesis of swinholide A. 

With ketones we come to the problem of regioselectivity, and the situation from chapter 3 is that methyl ketones 98 and ketones with one primary and one secondary alkyl group, particularly cyclic ketones such as 103 give the less substituted lithium enolate 97 or 102 by kinetically controlled deprotonation with LDA, and the more substituted silyl enol ether 99 or 104 on silylation under equilibrium conditions. Either derivative (lithium enolate or silyl enol ether) may be used to make the other, e.g. 96 and 100. 

Synthesis of 7 -amino acid-oxazole fragment 68 of calyculins A and B from D-erythronol-actone 58 has been reported by conversion to 59," which was subjected to oxidation reaction to afford the hemiaminal 60 (Scheme 9) Acetylation of 60 furnished 61, which was converted to ketone 62 in 88% yield. Conversion of 62 to a silyl enol ether, ozonolysis with reductive workup and O-methylation of the resultant alcohol 63 furnished 7 -lactam 64. Treatment of 64 with CAN led to 65 (60%), which was reacted with (CHj)2 A1 derivative of 66 to provide 67 (62%), which upon removal of the silyl group provided 68. 

Miscellaneous Reactions. Trimethylsilyldiazomethane converts acid- and base-sensitive maleic anhydride derivatives into the corresponding bis(methyl esters) (eq 70). Terminal silyl enol ethers are conveniently prepared from aldehydes by first treating the carbonyl compound with TMSC(Li)N2, followed sequentially by methanol and Rh2(OAc)4 (eq 71). The method works well with base-sensitive substrates and is superior to the attempted regioselective deprotonation/O-silylation of the corresponding methyl ketone. ... 

Aldol reaction between a silyl enol ether and an aromatic or aliphatic aldehyde can be catalysed by tetrabutylammonium fluoride ketones and epoxides are not attacked by the enolates derived in this manner. Directed cross-aldol reactions have now been carried out by conversion of a methyl ketone into the intermediate (15) using 9-trifluoromethylsulphonyl-9-borabicyclo[3,3,l]nonane and t-amine prior to reaction with the second carbonyl compound. ... 

Silyl enol ethers of P-amido substituted cyclohexanone give [2+2] cyclisadons to form N-heterocycles, fluoroalkyl amides convert cyclohexanones to the enol ether, C N02)4 witii benzocyclohexanone gives a-nitroketones, and with diazoesters give optically active siloxycyclopropanes. Pb(OAc)4 gives acetoxy derivatives, deracemisation by enantioselective protonation demonstrated, methyl vinyl ketones added to give a,e-diones, and... 

Scheme 8 Aldolization with methyl ketone-derived silyl enol ether...

The highly electrophilic cationic bis(8-quinolinolato)aluminum complex 407 enabled Yamamoto and coworkers to perform Mukaiyama-Michael additions of silyl enol ethers to crotonylphosphonates 406. The procedure was not only applicable to enol silanes derived from aryl methyl and alkyl methyl ketones (a-unsubstituted silicon enolates) but also to several cycfic a-disubstituted silyl enol ethers, as illustrated for the derivatives of a-methyl tetralone and indanone 405 in Scheme 5.105. Despite the steric demand of that substitution pattern, the reaction occurred in relatively high chemical yield with varying diastereoselectivity and excellent enantiomeric excess of the major diastereomer. The phosphonate residue was replaced in the course of the workup procedure to give the methyl esters 408. The protocol was extended inter alia to the silyl enol ether of 2,6,6-tetramethylcyclohexanone. The relative and absolute configuration of the products 408 was not elucidated [200]. 

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