Protecting group methyl ether

Alcohols protected as methyl ethers can be retrieved by reaction with tribromo-borane. Activation of the methyl ether by co-ordination of the Lewis acidic tri-bromoborane followed by nucleophilic cleavage of the O—Me bond (with concomitant formation of bromomethane) is typical behaviour. However, the cleavage took a different course with 39.1 [Scheme L39] instead of the O—Me bond being cleaved, the alternative C—O bond cleaved owing to participation of the remote acetoxy group.72 The formation of bromide 39.4 with retention of configuration is circumstantial evidence implicating dioxonium ion intermediate 393. 

Maiti and Roy reported a selective method for deprotection of primary allylic, benzylic, homoallylic and aryl TBS ethers using aqueous DMSO at 90° C. All other TBS-protected groups, benzyl ethers, THP ethers as well as methyl ethers remain unaffected. 

Before the TPS ether is cleaved with TBAF, secondary alcohol 7 has to be protected as methyl ether. TBAF is a reagent to cleave every silyl ether. Most other functional groups are not affected (see Chapter 2). In the next two steps the conversion of alcohol 33 into mesylate 34, which is a good leaving group, and then into iodide 35 in a Finkelstein type reaction occurs. Acetone is the solvent of choice, because Nal is better soluble in it than NaOMs and consequently reaction equilibrium is forced to the product side. Direct transformation from an alcohol to an iodide is possible with PPha and I2 in an Appel-like reaction, but in some cases this reaction fails. Final procedure is the generation of phosphonium salt 8. 

Septanose forms can also be obtained if the hydroxyl groups are protected by methyl ether formation. The isopropylidene groups in... 

The synthesis, characterization, and properties of a series of PEAs obtained from L-malic acid, 6-aminohexanol, and 1,6-hexanediamine, in which the hydroxy side group of malic acid was protected as methyl ether, have been studied [63]. Aregic and isoregic polymers were obtained and, furthermore, the ester-amide ratio was varied (i.e., from 1 50 to 1 1). AU studied PEAs were semicrystalline with T decreasing with the... 

Six protective groups for alcohols, which may be removed successively and selectively, have been listed by E.J. Corey (1972B). A hypothetical hexahydroxy compound with hydroxy groups 1 to 6 protected as (1) acetate, (2) 2,2,2-trichloroethyl carbonate, (3) benzyl ether, (4) dimethyl-t-butylsilyl ether, (5) 2-tetrahydropyranyl ether, and (6) methyl ether may be unmasked in that order by the reagents (1) KjCO, or NH, in CHjOH, (2) Zn in CHjOH or AcOH, (3) over Pd, (4) F", (5) wet acetic acid, and (6) BBrj. The groups may also be exposed to the same reagents in the order A 5, 2, 1, 3, 6. The (4-methoxyphenyl)methyl group (=MPM = p-methoxybenzyl, PMB) can be oxidized to a benzaldehyde derivative and thereby be removed at room temperature under neutral conditions (Y- Oikawa, 1982 R. Johansson, 1984 T. Fukuyama, 1985). 

Ethers are among the most used protective groups in organic synthesis. They vary from the simplest, most robust, methyl ether to the more elaborate, substituted, trityl ethers developed for use in nucleotide synthesis. They are formed and removed under a wide variety of conditions. Some of the ethers that have been used to protect alcohols are included in Reactivity Chart 1. ... 

Me3SiI, CH3CN, 25-50°, 100% yield. Selective removal of protective groups is possible with this reagent since a carbamate, =NCOOCMe3, is cleaved in 6 min at 25° an aryl benzyl ether is cleaved in 100% yield, with no formation of 3-benzyltyrosine, in 1 h at 50°, at which time a methyl ester begins to be cleaved. 

A carbonyl group cannot be protected as its ethylene ketal during the Birch reduction of an aromatic phenolic ether if one desires to regenerate the ketone and to retain the 1,4-dihydroaromatic system, since an enol ether is hydrolyzed by acid more rapidly than is an ethylene ketal. 1,4-Dihydro-estrone 3-methyl ether is usually prepared by the Birch reduction of estradiol 3-methyl ether followed by Oppenauer oxidation to reform the C-17 carbonyl function. However, the C-17 carbonyl group may be protected as its diethyl ketal and, following a Birch reduction of the A-ring, this ketal function may be hydrolyzed in preference to the 3-enol ether, provided carefully controlled conditions are employed. Conditions for such a selective hydrolysis are illustrated in Procedure 4. 

Enol ethers of saturated 3-ketones are not usually obtained directly from the ketone and therefore are of little importance as protective groups. However, enol ether (52) has been used instead of the bulkier 3-dimethyl ketal to protect the 3-ketone during angular methylation to (53). ... 

It is possible to change the stereochemical result of the alkylation by replacing the 3-ketal protecting group with a A -enol ether. This structural change eliminates a severe 1,3-diaxial interaction to a-face methylation and results in the formation of the 5a-methyl steroid (15) in about 35% yield, ... 

Birch s procedure for tropone synthesis appears to be widely applicable to 2,3- or 2,5-dihydroanisole derivatives which are readily obtained by reduction of appropriate aromatic methyl ethers by alcoholic metal-ammonia solutions. " Additional functional groups reactive to dibromocarbene or sensitive to base such as double bonds, ketones and esters would need to be protected or introduced subsequent to the expansion steps. 

A study of the reductive cleavage of a series of alkoxymethyl ethers using the glucose backbone shows that, depending on the reagent, excellent selectivity can be obtained for deprotection vs. methyl ether formation for most of the common protective groups. ... 

Alkylation of the tetrahydropyridine, 52 (obtained by reaction of a suitable protected derivative of 4-piperidone followed by dehydration and deprotection), with chloroacetonitrile affords 53, Reduction of the cyano group gives the diamine (54). Reaction of this intermediate with the S-methyl ether of thiourea affords guancycline (55). 

Alkylation of the protected azetidinyl bromide 61 with the anion from m-trifluormethyl-phenol gives ether 62. Removal of the N-(alpha-methylbenzyl)- protecting group by catalytic hydrogenation gives the secondary amine 63. Reaction of that compound with methyl isocyanate gives the anticonvulsant urea fluzinamide (64) [14]. 

You will note that the oxygen atoms attached to carbons 5 and 12 in 43 reside in proximity to the C-9 ketone carbonyl. Under sufficiently acidic conditions, it is conceivable that removal of the triethylsilyl protecting groups would be attended by a thermodynamically controlled spiroketalization reaction.30 Indeed, after hydro-genolysis of the C-26 benzyl ether in 43, subjection of the organic residue to the action of para-toluenesulfonic acid in a mixture of methylene chloride, ether, and water accomplishes the desired processes outlined above and provides monensin methyl ester. Finally, saponification of the methyl ester with aqueous sodium hydroxide in methanol furnishes the sodium salt of (+)-monensin [(+)-1], Still s elegant synthesis of monensin is now complete.13... 

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