From silyl ethers

The reaction tolerates a wide variety of allylic substrates (Scheme 9.38). Allylic alcohols were obtained from silyl ethers by standard methods. 

Catalytic DBB29 avoids the need for such vigorous conditions, and allows benzyl48 and allyl lithiums to be formed from silyl ethers,49 mesylates50 triflates,51 carbamates and carbonates,9 and even directly from lithium alkoxides.49... 

The ability of fluoro-2 -phosphanes to transform silyl ethers into fluorides was first observed during a study of the reactions of phosphorus pentafluoride and its derivatives R PF5 (n = 1, 2, 3 R = hydrocarbon group) with trimethylsilyl ethers. Subsequently, this reaction was proposed as a new method for the preparation of C-F compounds from silyl ethers or silicic acid esters with fluoro-A -phosphanes. Pentafluorophenyl-substituted fluoro-A -phos-phanes were found to react similarily, Other workers found that tctrafluoro(phenyl)-A -phos-phane. which was chosen as the most convenient reagent with regard to reactivity and stability, gave considerable amounts of elimination products, especially with primary and cyclic alcohols. Good yields of fluorinated products are obtained when stable carbocations can be formed at the site of substitution, such as in tertiary alcohols, but 2-phcnylethanol. benzyl alcohol and diphcnylmethanol, on the other hand, give only poor yields of fluorinated products ethers and polymers are the main products. ... 

The mechanism of the formation of organic fluorides from silyl ethers and fluoro-/.5-phosphanes has been studied in some detail for lelrafluoro(phenyl )-25-phosphanc.9 The first step, which is usually quantitative at low temperatures, is the formation of an intermediate alkoxyfluoro-25-phosphane 1 and fluorotrimethylsilanc. 

The aryl triflate 13 is formed in one step from silyl ether 12. 

Hydrolysis. Alcohols and carbonyl compounds are recovered from silyl ethers and dioxolanes, respectively, on treatment of the latter with the Ce(III) salt and Nal in MeCN. 

Brook rearrangement. a-Trimethylsilylpropargyl alcohols undergo Brook rearrangement to afford allenyl silyl ethers, which can be used to condense with aldehydes. Silyl group transfer from the ether four bonds apart is preferred after the Sn/Li exchange from silyl ethers of l-tributylstannyl-l,3-alkanediols. °... 

Similarly, a variety of aryl ethers can be obtained via the [4-1-2] cross-benzannulation reaction of enynes with diynes (Scheme 14.24) [18]. Notably, using this strategy, alkoxy substituent can be introduced at positions 2, 4, and 6 of ary-lacethylene 65 with the use of appropriate coupling partners. Moreover, starting from silyl ethers, the corresponding p-alkynylphenols can be synthesized after deprotection in either a stepwise or a one-pot fashion [18b],... 

A useful catalyst for asymmetric aldol additions is prepared in situ from mono-0> 2,6-diisopropoxybenzoyl)tartaric acid and BH3 -THF complex in propionitrile solution at 0 C. Aldol reactions of ketone enol silyl ethers with aldehydes were promoted by 20 mol % of this catalyst solution. The relative stereochemistry of the major adducts was assigned as Fischer- /ir o, and predominant /i -face attack of enol ethers at the aldehyde carbonyl carbon atom was found with the (/ ,/ ) nantiomer of the tartaric acid catalyst (K. Furuta, 1991). 

Silyl ethers serve as preeursors of nucleophiles and liberate a nucleophilic alkoxide by desilylation with a chloride anion generated from CCI4 under the reaction conditions described before[124]. Rapid intramolecular stereoselective reaction of an alcohol with a vinyloxirane has been observed in dichloro-methane when an alkoxide is generated by desilylation of the silyl ether 340 with TBAF. The cis- and tru/u-pyranopyran systems 341 and 342 can be prepared selectively from the trans- and c/.y-epoxides 340, respectively. The reaction is applicable to the preparation of 1,2-diol systems[209]. The method is useful for the enantioselective synthesis of the AB ring fragment of gambier-toxin[210]. Similarly, tributyltin alkoxides as nucleophiles are used for the preparation of allyl alkyl ethers[211]. 

Me3SiCH2CH=CH2i TsOH, CH3CN, 70-80°, 1-2 h, 90-95% yield. This silylating reagent is stable to moisture. Allylsilanes can be used to protect alcohols, phenols, and carboxylic acids there is no reaction with thiophenol except when CF3S03H is used as a catalyst. The method is also applicable to the formation of r-butyldimethylsilyl derivatives the silyl ether of cyclohexanol was prepared in 95% yield from allyl-/-butyldi-methylsilane. Iodine, bromine, trimethylsilyl bromide, and trimethylsilyl iodide have also been used as catalysts. Nafion-H has been shown to be an effective catalyst. 

Benzyloxy-2-fluoro-2-methylpropionaIdehyde was prepared in optically active form from (5)-monoethyl 2-fluoro-2-methylmalonate, which had itself been prepared by enzymatic hydrolysis A number of enol silyl ethers or enolates were added to the aldehyde in processes that occur with fair to good diastereoselectivity [6] (equation 6) (Table 2)... 

Silyl ethers are among the most frequently used protective groups for the alcohol function. This stems largely from the fact that their reactivity (both formation and cleavage) can be modulated by a suitable choice of substituents on the silicon atom. Both steric and electronic effects are the basic controlling elements that regulate the ease of cleavage in multiply functionalized substrates. In plan-... 

EtMgBr, Et20, it, 1 h, 90-100% yield. These conditions were used to prevent a neighboring silyl ether from migrating. Ethylmagnesium chloride is much more reactive thus, the reaction can be run at —42°, giving a 90% yield of the alcohol. Acetates and pivaloates are also cleaved. 

With ring G in place, the construction of key intermediate 105 requires only a few functional group manipulations. To this end, benzylation of the free secondary hydroxyl group in 136, followed sequentially by hydroboration/oxidation and benzylation reactions, affords compound 137 in 75% overall yield. Acid-induced solvolysis of the benzylidene acetal in 137 in methanol furnishes a diol (138) the hydroxy groups of which can be easily differentiated. Although the action of 2.5 equivalents of tert-butyldimethylsilyl chloride on compound 138 produces a bis(silyl ether), it was found that the primary TBS ether can be cleaved selectively on treatment with a catalytic amount of CSA in MeOH at 0 °C. Finally, oxidation of the resulting primary alcohol using the Swem procedure furnishes key intermediate 105 (81 % yield from 138). 

Hydroxyboron subphthalocyanine was obtained in very low yield (2%) from chloroboron subphthalocyanine in the presence of sodium hydroxide and a crown ether in refluxing xylene, the major product (8%) being, u-oxo-bis(boron subphthalocyanine).68 Silyl ethers, however, are formed in reasonable yields.68... 

In a formal synthesis of fasicularin, the critical spirocyclic ketone intermediate 183 was obtained by use of the rearrangement reaction of the silyloxy epoxide 182, derived from the unsaturated alcohol 180. Alkene 180 was epoxidized with DMDO to produce epoxy alcohol 181 as a single diastereoisomer, which was transformed into the trimethyl silyl ether derivative 182. Treatment of 182 with HCU resulted in smooth ring-expansion to produce spiro compound 183, which was subsequently elaborated to the desired natural product (Scheme 8.46) [88]. 

A high degree of syn selectivity can be obtained from the addition of enamines to nitroalkenes. In this case, the syn selectivity is largely independent of the geometry of the acceptor, as well as the donor, double bond. Next in terms of selectivity, are the addition of enolates. However, whether one obtains syn or anti selectivity is dependent on both the geometry of the acceptor and the enolate double bond, whereas anti selectivity of a modest and unreliable level is obtained by reaction of enol silyl ethers with nitroalkenes under Lewis acid catalysis. 

Preparation from hcxamethyldisiloxane and 12/AI powder in detail, followed by cleavage of cyclohexyl methyl ether, to give cyclohexanol (via the intermediate silyl ether). 

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