Silyl ketones, formation

The construction of the naturally derived narbomycin and tylosin-aglycones by Masamune and coworkers employ identical methodology for seco-acid formation. In each case, Peterson alkenadon of a functionalized aldehyde (not shown) and the silyl ketones (96 R = SiMes Scheme 36) or (99 Scheme 37) efficiently introduced the required ( )-a,3-unsaturation. Silyl ketone formation is accomplished in each case through cuprate acylation by an activated carboxylic acid derivative. Formation of an acid chloride was not possible in the sensitive tylosin-aglycone intermediate however, selective acylation of the silylcuprate proceeded at the pyridyl thiol ester moiety of (98) and not with the r-butyl thiol ester. In a related investigation, (97), an advanced intermediate for 6-deoxyerythronolide B, was obtained from (95) via addition of lithium diethylcuprate to the acid chloride (84% yield). In all the above cases, no addition was observed at the f-butyl thiol ester. 

Diazaphospholes are known to undergo facile 1,3-dipolar cycloaddditions with a variety of dipoles [2, 4, 7, 98], During recent years, some interesting [2+3] cycloaddition reactions have been reported. 2-Acyl-[l,2,3]diazaphospholes 6 were reported to undergo [2+3] cycloaddition with diazocumulene 92, the minor equilibrium isomer of a-diazo-a-silyl ketones 91, to form a bicyclic cycloadduct 93 (Scheme 29). Thermolysis of the cycloadduct results in the formation of tricyclic phosphorus heterocycle 94, which can be explained due to the possibility of two parallel reactions of cycloadduct. On the one hand, extrusion of molecular nitrogen from 93... 

This silyl hydrazone formation-oxidation sequence was originally developed as a practical alternative to the synthesis and oxidation of unsubstituted hydrazones by Myers and Furrow [31]. The formation of hydrazones directly from hydrazine and ketones is invariably complicated by azine formation. In contrast, silyl hydrazones can be formed cleanly from /V,/V -bis(7< rt-butyldimethylsilyl)hydrazine and aldehydes and ketones with nearly complete exclusion of azine formation. The resulting silylhydrazones undergo many of the reactions of conventional hydrazones (Wolff-Kishner reduction, oxidation to diazo intermediate, formation of geminal and vinyl iodides) with equal or greater efficiency. It is also noteworthy that application of hydrazine in this setting may also have led to cleavage of the acetate substituents. 

Palladium-catalyzed bis-silylation of methyl vinyl ketone proceeds in a 1,4-fashion, leading to the formation of a silyl enol ether (Equation (47)).121 1,4-Bis-silylation of a wide variety of enones bearing /3-substituents has become possible by the use of unsymmetrical disilanes, such as 1,1-dichloro-l-phenyltrimethyldisilane and 1,1,1-trichloro-trimethyldisilane (Scheme 28).129 The trimethylsilyl enol ethers obtained by the 1,4-bis-silylation are treated with methyllithium, generating lithium enolates, which in turn are reacted with electrophiles. The a-substituted-/3-silyl ketones, thus obtained, are subjected to Tamao oxidation conditions, leading to the formation of /3-hydroxy ketones. This 1,4-bis-silylation reaction has been extended to the asymmetric synthesis of optically active /3-hydroxy ketones (Scheme 29).130 The key to the success of the asymmetric bis-silylation is to use BINAP as the chiral ligand on palladium. Enantiomeric excesses ranging from 74% to 92% have been attained in the 1,4-bis-silylation. 

The acid or base elimination of a diastereoisomerically pure p-hydroxysilane, 1, (the Peterson olefination reaction4) provides one of the very best methods for the stereoselective formation of alkenes. Either the E- or Z-isomer may be prepared with excellent geometric selectivity from a single precursor (Scheme 1). The widespread use of the Peterson olefination reaction in synthesis has been limited, however, by the fact that there are few experimentally simple methods available for the formation of diastereoisomerically pure p-hydroxysilanes.56 One reliable route is the Cram controlled addition of nucleophiles to a-silyl ketones,6 but such an approach is complicated by difficulties in the preparation of (a-silylalkyl)lithium species or the corresponding Grignard reagents. These difficulties have been resolved by the development of a simple method for the preparation and reductive acylation of (a-chloroalkyl)silanes.7... 

The most systematically investigated acyl anion equivalents have been the IMS ethers of aromatic and heteroaromatic aldehyde cyanohydrins, TBDMS-protected cyanohydrins, - benzoyl-protected cyanohydrins, alkoxycaibonyl-protected cyanohydrins, THP-protected cyanohydrins, ethoxyethyl-protect cyanohydrins, a-(dialkylamino)nitriles, cyanophosphates, diethyl l-(trimethylsiloxy)-phenyimethyl phosphonate and dithioacetals. Deprotonation di these masked acyl anions under the action of strong basie, usually LDA, followed by treatment with a wide varies of electrophiles is of great synthetic value. If the electrophUe is another aldehyde, a-hydroxy ketones or benzoins are formed. More recently, the acyl caibanion equivalents formed by electroreduction of oxazolium salts were found to be useful for the formation of ketones, aldehydes or a-hydroxy ketones (Scheme 4). a-Methoxyvinyl-lithium also can act as an acyl anion equivalent and can be used for the formation of a-hydroxy ketones, a-diketones, ketones, y-diketones and silyl ketones. - - ... 

Clearly the course of these cyclization reactions is dependent upon the silicon group. In this regard, cyclization of (82) affords the steroid nucleus (83 Scheme 40). The formation of (83) was attributed, in part, to a transition state preference for the formation of the linear vinyl carbocation (84b) rather than the bent vinyl cation (84a), which would be produced in an endocyclic cyclization. The formation of (81) was controlled by the generation of the -silyl carbocation (85a), which may be a precursor to an a-silyl ketone, which undergoes protodesilylation. It is not known whether the formation of (81) as the major cyclization product occurs through a kinetic pathway or by Wagner-Meerwein rearrangement of the kinetically prefened linear carbocation (85b). 

Owing to the interest of optically active C-centered organosilanes, Paquette and co-workers (refs. 116-118) have applied the Haller-Bauer reaction to optically active non-enolizable a-silyl phenyl ketones. An optically active silane (Fig. 23) was obtained with retention of configuration (96 to 98 %). These results are interpreted on the basis of an initial a-silyl carbanion formation within a solvent shell that also encases benzamide. 

Formation of Alkyl Eno Ethers and Enol Esters 2322 Formation Enol Silyl Ethers and Silyl Ketone Acetals... 

Hydrolysis with mild acid leads to selective reversal of the silyl cyanohydrin formation, thus revealing the ketone at C17. Condensation of that function with lithium acetylide proceeds as in all cases noted earlier to give the 17a-ethynyl-17/3-hydroxy intermediate 31-2 (Scheme 4.31). Treatment of that intermediate with acid then leads to hydrolysis of the ketal at position 3. The transient intermediate hydroxy ketone quickly loses water so as to form an olefin at C4 and thus mifepristone (31-3). 

As for the diols, the symmetric compounds have found most uses for nonsymmetric diols, a versatile synthesis via silyl ketones using the SAMP/RAMP methodology has been developedl5. Both enantiomers of the simplest symmetric diol, 2,3-butanediol (11), are often used in asymmetric synthesis, mostly for the formation of acetals and ketals with carbonyl compounds and subsequent reactions with acidic catalysts (Section D. 1.1.2.2.), Grignard reagents (Section D. 1.3.1.4.) and other carbanions (Sections D. 1.5.1., D. 1.5.2.4.), and diastereoselective reductions (Section D.2.3.3.). Precursors of chiral alkenes for cycloprotonations (Section D.1.6.1.5.) and for chiral allenes (Section B.I.), and chiral haloboronic acids (Section D. 1.1.2.1.) are other applications. The free diol has been employed as a chiral ligand in molybdenum peroxo complexes used for enantioselective epoxidation of alkenes (Section D.4.5.2.2.). 

Norrish Type II hydrogen abstraction is the predominant reaction on irradiation of the silylated ketones (27). This affords the dealkylated product (28). There is some Norrish Type I reactivity that results in the formation of the isomerized product (29) and the two ring-opened products (30) and (31). The ratio of the two reactions varies with the silyl group, with a 32 1 ratio of (28) (29) obtained from (27, R = Me) and a 13 1 ratio from (27, R = Ph or R3 = MePh2). ... 

As discussed earlier (see also Chapter 6), oxime derivatives are often prepared for polyfunctional compounds containing ketone groups in order to prevent the formation of mixed enol-silyl ethers. An alternative approach is to use a catalyst to enhance the yield of enol-silyl ethers (see also above. Section 4.2.3, for TMS ethers). The use of potassium acetate in toluene as catalyst is reported to produce a quantitative yield of TBDMS ethers and >96% yield of TBDMS-enol ethers of a, -unsaturated keto steroids [326]. An alternative to this approach, set out below, uses sodium formate to catalyse enol-silyl ether formation with fewer by-products being produced [12, 13]. 

Silylation of ketones by use of BSMTFA occurs in triethylamine and DMF at 40-60 °C to give the corresponding silyl enol ethers in good to excellent yields (eq 1). In addition, silyl ether formation takes place in A-hydroxysuccinimide (88% yield) and N-hydrox)q))Trole (99% yield) by use of BSMTFA in THF. ... 

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