Amides reductive silylation

Reductive Silylation of Amides Using Trichlorosilane/Tertiary Amine Mixture... 

A trichlorosilane/tertiary amine mixture has been shown to reduce the carbonyl moiety of aromatic amides to give ASMAs. This constitutes an alternative to the reductive silylation described in Section III.B.2.f.194 This work has been reviewed195 and extended to aliphatic amides to give RSMA. 

This hydrosilylation method can also be applied to the reduction of esters. The silyl acetal products can be hydrolyzed, resulting in net reduction of esters to aldehydes. For example, ethylbenzoate can be fully reduced in the presence of 0.1 mol % [Ir(coe)2Cl]2 and 1.5 equiv of diethylsUane at room temperature for 1 h to give benzaldehyde after hydrolysis (eq 3). The functional group compatibility is analogous to that of the amide reduction. 

In this series of amides, hydrolysis or aminolysis of a simple ester, cleavage of a silyl groups a cis/trans isomerization, or reduction of a quinone to a hydro-quinone exposes an alcohol that then induces deprotection by intramolecular addition to the amide carbonyl. 

The JV-silyl phosphinous amides present some particularities in their reactivity that make these compounds worth commenting on separately. They are stable and can be easily prepared in the usual way by reaction of AT-silyl substituted primary amines or hexamethyldisilazane with halophosphanes [48,49,128,129] or byJV-silylation of the appropriate phosphinous amides [72, 107]. The reductive Ph-P bond cleavage in AT-silyl phosphazenes Ph3P=NSiMe3 by the action of sodium is a peculiar example of preparing Ph2PNHSiMe3 [130]. 

Combined use of Co(acac)2 and DiBAlH also gives selective reduction for a,(3-unsaturated ketones, esters, and amides.112 Another reagent combination that selectively reduces the carbon-carbon double bond is Wilkinson s catalyst and triethylsilane. The initial product is the enol silyl ether.113... 

METHOXYCARBONYL-1,1,6-TRIMETHYL-1,4,4a,5,6,7,8,8a-OCTAHYDRO-2,3-BENZOPYRONE, an intramolecular Diels-Alder reaction is responsible for the diastereoselectivity. The stereoselective 1,4-functionalization of 1,3-dienes is exemplified by a two-step process leading to cis- and trans-1-ACETOXY-4-(DICARBOMETHOXYMETHYL)-2-CYCLOHEXENE. The effectiveness of a silyl hydride in providing a means for erythro-directed reduction of a p-keto amide is applied in a route to ERYTHRO-1 -(3-HYDROXY-2-METHYL-3-PHENYL-PROPANOYLJPIPERIDINE. This is followed by an asymmetric synthesis based on a chiral bicyclic lactam leading to (R)-4-ETHYL-4-ALLYL-2-CYCLOHEXEN-1-ONE. The stereoselectivity with which acetoxy migration can operate to an adjacent radical center is reflected in the one-step reaction that gives rise to 1,3,4,6-TETRA-O-ACETYL-2-DEOXY-a-D-GLUCOPYRANOSE. 

Perhaps the most useful type of alkene substrates for these reactions are enol ethers, enol esters and vinyl sulfides. Silyl enol ethers have excellent electron-donor properties, with an ionization potential of about 8 eV and an oxidation potential in various solvents of approximately 1.0-1.5 V vs SCE161. These compounds are easily synthesized by reaction of an enolate with a chlorosilane. (A very recent report synthesized a variety of silyl enol ethers with extremely high stereochemical yield, using the electrogenerated amidate of 2-pyrolidinone as the base.)162 An interesting point is that the use of oxidative or reductive cyclization reactions allows carbonyl functionalities to be ambivalent, either oxidizable or reducible (Scheme 65)163. 

In the total synthesis of (+)-trienomycins A and F, Smith et al. used an Evans aldol reaction technology to construct a 1,3-diol functional group8 (Scheme 2.1i). Asymmetric aldol reaction of the boron enolate of 14 with methacrolein afforded exclusively the desired xyn-diastereomer (17) in high yield. Silylation, hydrolysis using the lithium hydroperoxide protocol, preparation of Weinreb amide mediated by carbonyldiimidazole (CDI), and DIBAL-H reduction cleanly gave the aldehyde 18. Allylboration via the Brown protocol9 (see Chapter 3) then yielded a 12.5 1 mixture of diastereomers, which was purified to provide the alcohol desired (19) in 88% yield. Desilylation and acetonide formation furnished the diene 20, which contained a C9-C14 subunit of the TBS ether of (+)-trienomycinol. 

Functionally substituted benzylic, allylic, and vinylic compounds containing alkoxides, esters, ethers, nitriles, or amides can be reacted with halosilanes under Barbier conditions using HMPT to yield C- and O-silylated products, 1,2- or 1,4-addition products, as well as reductive dimers. Radical and anionic intermediates are postulated, based on SET reactions from the metal, and multiple silated species can be obtained. The use of the TMSCl-Mg-HMPT system has been extensively investigated by Galas group [85] at the University of Bordeaux, and their work has greatly advanced the science of the Barbier reaction with silanes. 

Phenylalanine-derived oxazolidinone has heen used in O Scheme 52 as a chiral auxiliary for as)rmmetric cross-aldolization (Evans-aldol reactions [277,278,279,280,281,282,283,284, 285]). The 6-deoxy-L-glucose derivative 155 has heen prepared by Crimmins and Long [286] starting with the condensation of acetaldehyde with the chlorotitanium enolate of O-methyl glycolyloxazohdinethione 150. A 5 1 mixture is obtained from which pure 151 is isolated by a single crystallization. After alcohol silylation and subsequent reductive removal of the amide, alcohol 152 is obtained. Swem oxidation of 152 and subsequent Homer-Wadsworth-Emmons olefination provides ene-ester 153. Sharpless asymmetric dihydroxylation provides diol 154 which was then converted into 155 (O Scheme 60) (see also [287]). 

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