Tert-butyldimethylsilyl chloride, reaction with alcohols

Intermediate 10 must now be molded into a form suitable for coupling with the anion derived from dithiane 9. To this end, a che-moselective reduction of the benzyl ester grouping in 10 with excess sodium borohydride in methanol takes place smoothly and provides primary alcohol 14. Treatment of 14 with methanesulfonyl chloride and triethylamine affords a primary mesylate which is subsequently converted into iodide 15 with sodium iodide in acetone. Exposure of 15 to tert-butyldimethylsilyl chloride and triethylamine accomplishes protection of the /Mactam nitrogen and leads to the formation of 8. Starting from L-aspartic acid (12), the overall yield of 8 is approximately 50%, and it is noteworthy that this reaction sequence can be performed on a molar scale. 

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). 

Conversion of ketone 80 to the enol silane followed by addition of lithium aluminum hydride to the reaction mixture directly provides the allylic alcohol 81 [70]. Treatment of crude allylic alcohol 81 with tert-butyldimethylsilyl chloride followed by N-b ro m o s u cc i n i m i de furnishes the a-bromoketone 82 in 84 % yield over the two-step sequence from a.p-unsaturated ester 80. Finally, a one-pot Komblum oxidation [71] of a-bromoketone 82 is achieved by way of the nitrate ester to deliver the glyoxal 71. It is worth noting that the sequence to glyoxal 71 requires only a single chromatographic purification at the second to last step (Scheme 5.10). 

The classical Henry reaction conditions (base catalyzed addition) have some drawbacks sometimes the nitro alcohols are obtained in low yields and diastereoselectivities are not always high. To improve these results, a number of modifications were introduced. One of them is the Seebach s silyl nitronate method,25 that involves a reaction between an aldehyde with a silyl nitronate prepared by metalation of the corresponding nitro alkane with LDA, followed by reaction of the resulting nitronate with tert-butyldimethylsilyl chloride.26... 

CAL and AK lipase were used in these reactions and the results are listed in Table 6.19. In one case, the acetylated product 151 was converted (after protection of the alcohol with tert-butyldimethylsilyl chloride) to a phosphine oxide with vinylmagnesium bromide, with clean inversion at the phosphorus atom. 

Saxena et al. (2003) have carried out the reactions of alcohols or phenols with tert-butyldimethylsilyl chloride (TBDMSCl) or trimethylsilyl chloride (TMSCl) in presence of catalytic amount (20 mol%) of iodine in a microwave oven for 2 min, which resulted into corresponding silyl ethers in excellent yield. It was also observed that under similar reaction conditions, iodine in methanol deprotects the silyl ether into its parent alcohol or phenol. 

The 0-silylation reaction of alcohols is important as a protection method of hydroxyl groups. 0-Silylations of liquid or crystalline alcohols with liquid or crystalline silyl chlorides were found to be possible in the solid state. For example, when a mixture of powdered L-menthol (26), ferf-butyldimethylsilyl chloride (27), and imidazole (28) was kept at 60 °C for 5 h, 0-tert-butyldi-methylsilyl L-menthol (29) was obtained in 97% yield [8] (Scheme 4). Similar treatments of 26 with the liquid silyl chlorides, trimethyl- (30a) and triethylsilyl chloride (30b), gave the corresponding 0-silylation products 31a (89%) and 31b (89%), respectively, in the yields indicated [8] (Scheme 4). However, 0-silylation of triisopropyl- (30c) and triphenylsilyl chloride (30d) proceeded with difficultly even at 120 °C and gave 31c (57%) and 31d (70%), respectively, in relatively low yields. Nevertheless, when the solvent-free silylation reactions at 120 °C were carried out using two equivalents of 30c and 30d, 31c (77%) and 31d (99%) were obtained, respectively, in relatively high yields. 

The Introduction of the side chain containing carbon atoms 16 to 11 was accomplished as shown In Scheme 2. Selective tosylatlon of 9A followed by displacement with cyanide ion and protection of the 19 alcohol with tert-butyldimethylsilyl (TBS) chloride gave 11. Subsequent reduction with diisobutylaluminum hydride (DIBAL) and hydrolysis gave the aldehyde 12. Wittig reaction of 12 with (carbethoxyethyl i dene) tri phenl ypfiosphorane provided the o,b... 

A slight modification of Corey synthesis (see Scheme 3.16) affords an estrane that bears a hydroxyl at C14. The 14-dehydroestrone intermediate from that synthesis is first reduced to give the corresponding 17[3-hydroxy analogue. This, in turn, is converted to its tert-butyldimethylsilyl ether (TBDMS) (32-1) by reaction with the silyl chloride (Scheme 3.32). Oxidation by means of w-chloroperbenzoic acid (mCPBA) affords the 14—15 epoxide 32-2 as a 3 1 mixture of a- and p-epimers. Treatment of the former with lithium aluminum hydride leads to the alcohol... 

Theil et al. developed a method for chemoenzymatic synthesis of both enantiomers of cispentacin [89]. frans-2-Hydroxymethylcyclopentanol, obtained by the sodium borohydride reduction of ethyl 2-oxocyclopentanecarboxylate, was monosilylated with tert-butyldimethylsilyl (TBDMS) chloride to afford 55. Lipase PS-catalysed transesterification with vinyl acetate in /erf-butyl methyl ether furnished the ester 56 and the alcohol 57. The deacetylated 58 was obtained by the Mitsunobu reaction with phthalimide, triphenylphosphine and diethyl azodicarboxylate (DEAD) to furnish the cis oriented 59 with inversion of configuration (not retention as mentioned in the original article) (Scheme 9). Desilylation, Jones oxidation and subsequent deprotection with aqueous methylamine gave the ( R,2S) enantiomer 5 [89]. The (15, 2/f) enantiomer was prepared by the same route from the silyl alcohol 57. 

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