Protections alcohols

For other methods of cleavage the chapter on alcohol protection should be consulted. 

Bu4N F, THF, 0°, 1 h, 52-95% yield.A primary alcohol protected as the r-butyldimethylsilyl ether is cleaved under these conditions, but a similarly protected secondary alcohol is stable. 

Some of the more common reagents for the conversion of carboxylic acids to trimethylsilyl esters are listed below. For additional methods that can be used to silylate acids, the section on alcohol protection should be consulted since many of the methods presented there are also applicable to carboxylic acids. Trimethylsilyl esters are cleaved in aqueous solutions. 

Silyl-derived protective groups are also used to mask the thiol function. A complete compilation is not given here since silyl derivatives are described in the section on alcohol protection. The formation and cleavage of silyl thioethers proceed analogously to simple alcohols. The Si—S bond is weaker than the Si—O bond, and therefore sulfur derivatives are more susceptible to hydrolysis. For the most part silyl ethers are rarely used to protect the thiol function because of their instability. Silyl ethers have been used for in situ protection of the — SH group during amide formation. ... 

Butyl ethers can be prepared from a variety of alcohols, including allylic alcohols. The ethers are stable to most reagents except strong acids. The /-butyl ether is probably one of the more underused alcohol protective groups, considering its stability, ease and efficiency of introduction, and ease of cleavage. 

Bu2BOTf, BH3-THF, CH2CI2, 0°, 70-91% yield. In a variety of pyrano-sides, cleavage occurs primarily to give the primary alcohol, with the secondary alcohol protected as the benzyl ether." ... 

The section on alcohol protection should be examined, since many of the methods for the formation and cleavage of TBDMS ethers are similar. 

Protection of the OH with an alcohol-protective group gives this approach considerable versatility... 

One of the more common methods of alcohol protection is by reaction with a chlorotrialkylsilane, CI-S1R3, to yield a trialkylsilyl ether, R -O-SilTj. Chlorotrimethylsilane is often used, and the reaction is carried out in the presence of a base, such as tciethylamine, to help form the alkoxide anion from the alcohol and to remove the HC1 by-product from the reaction. 

The synthesis of key intermediate 12, in optically active form, commences with the resolution of racemic trans-2,3-epoxybutyric acid (27), a substance readily obtained by epoxidation of crotonic acid (26) (see Scheme 5). Treatment of racemic 27 with enantio-merically pure (S)-(-)-1 -a-napthylethylamine affords a 1 1 mixture of diastereomeric ammonium salts which can be resolved by recrystallization from absolute ethanol. Acidification of the resolved diastereomeric ammonium salts with methanesulfonic acid and extraction furnishes both epoxy acid enantiomers in eantiomerically pure form. Because the optical rotation and absolute configuration of one of the antipodes was known, the identity of enantiomerically pure epoxy acid, (+)-27, with the absolute configuration required for a synthesis of erythronolide B, could be confirmed. Sequential treatment of (+)-27 with ethyl chloroformate, excess sodium boro-hydride, and 2-methoxypropene with a trace of phosphorous oxychloride affords protected intermediate 28 in an overall yield of 76%. The action of ethyl chloroformate on carboxylic acid (+)-27 affords a mixed carbonic anhydride which is subsequently reduced by sodium borohydride to a primary alcohol. Protection of the primary hydroxyl group in the form of a mixed ketal is achieved easily with 2-methoxypropene and a catalytic amount of phosphorous oxychloride. 

Secondary amines do not give the expected /V-TBDMS derivatives under the conditions normally used for similar alcohol protection (Chapter 14). Instead, /V-formamides are produced (3) in good yield through a DMF-derived Vilsmeier intermediate. 

Chemo- and stereoselective reduction of (56) to (55) is achieved In highest yield by sodium borohydride in ethanol. The isolated ketone is reduced more rapidly than the enone and (55) is the equatorial alcohol. Protection moves the double bond out of conjugation and even the distant OH group in (54) successfully controls the stereochemistry of the Simmons-Smith reaction. No cyclopropanation occurred unless the OH group was there. Synthesis ... 

The methylthiomethyl (MTM) group is a related alcohol-protecting group. There are several methods for introducing the MTM group. Alkylation of an alcoholate by... 

C tert-Butyl Ethers by Alktlation of alcohols. Protecting Groups... 

Like Still s reagent, tributyl[(methoxymethoxy)methyl)etannane incorporates an alcohol protective group that can be conveniently unmasked under mild acidic conditions. However, an advantageous feature of this MOM ether derivative is that, in contrast to Still s reagent, it is achiral. In many applications the introduction of an additional chiral center into synthetic intermediates is undesirable because of the complications associated with the manipulation, analysis, and purification of diastereomeric mixtures. 

A variety of alcohols, protected as t-butyldimethylsilyl (TBDMS) ether derivatives, can be rapidly regenerated to the corresponding hydroxy compounds on alumina surface using MW irradiation (Scheme 6.8) [42], This approach prevents the use of corrosive fluoride ions that are normally employed for cleaving the silyl protecting groups. 

During the past 2 years several research groups have published research that either uses or expands upon Crowe s acyclic cross-metathesis chemistry. The first reported application of this chemistry was in the synthesis of frans-disubstitut-ed homoallylic alcohols [30]. Cross-metathesis of styrenes with homoallylic silyl ethers 15, prepared via asymmetric allylboration and subsequent alcohol protection, gave the desired trans cross-metathesis products in moderate to good yields (Eq. 15). 

With the alcohol protected, preparation of the Grignard reagent can proceed, and this can then react with the ketone carbonyl in a nucleophilic addition. The protecting group can then be removed by treatment with acid, to restore the hydroxyl function. This also involves a tertiary carbocation that is subsequently quenched with water. 

The methylthiomethyl (MTM) group is a related alcohol-protecting group. There are several methods for introducing the MTM group. Alkylation of an alcoholate by methylthiomethyl chloride is efficient if catalyzed by iodide ion.9 Alcohols are also converted to MTM ethers by reaction with dimethyl sulfoxide in the presence of acetic acid and acetic anhydride10 or with benzoyl peroxide and dimethyl sulfide.11 The latter two methods involve the generation of the methylthiomethylium ion by ionization of an acyloxysulfonium ion (Pummerer reaction). 

Breit reported a substrate-directed diastereoselective hydroformylation of acyclic methallylic and homomethallylic alcohols protected by 2-(diphenylphosphanyl)benzoyl group (63 and 64) using a P(OPh)3/Rh(acac)(GO)2 system and isolated the corresponding < ///-aldehydes in good diastereoselectivity (Table 11, up to 9614 = They... 

Notes This alcohol protecting is easily attached and readily removed by Lewis acids such as zinc bromide and titanium tetrachloride. Phenols can be protected (reaction of the sodium salt with MEMC1) and deprotected with TFA. More easily removed than the MOM group. 

Notes A weak acid, useful for substrates with acid-sensitive functional groups. Has been used to place and remove alcohol protecting groups ... 

F.Guibf and Y. Saint M Leux, The allyloxycarbonyl group for alcohol protection Quantitative removal or transformation into allyl protecting group via w-allyl complexes of palladium, Tetrahedron Lett. 22 3391 (1981). 

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