Protective groups benzyl

Protecting group benzyl ether (OBn) Structure o Protects alcohols (OH in general) From almost everything Protection NaH, BnBr Deprotection H2. Pd/C, or HBr... 

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. 

The white crystalline diazoketone is dissolved in 10 ml of dry chloroform. Hydrogen chloride gas is bubbled slowly for 2 min into the solution that is cooled in ice. A spectrum of the product, 5-chloro-4-oxo-A -benzoxycarbonyl L-[5- C]norvaline-a-benzyl ester, should exhibit no diazo absorption. The chloroform is removed by flash evaporation and the residual material is suspended in 20 ml of 6 Af HCl and heated at 70° for 10 hr. The supernatant solution is decanted and replaced with 20 ml of 6 iV HCl, and the procedure is repeated until no insoluble material remains. The solutions are combined, and the products generated by removal of the protecting groups (benzyl alcohol, toluene) are removed by lyophilization the remaining colorless, moist powder may be dried under reduced pressure over PaO.-,. The net yield of L-2-amino-4-oxo-5-chloropentanoic acid hydrochloride is about 80% (49 mg, 0.24 mmole specific activity 1.16 Ci/mole). The chloroketone hydrochloride can be recrystallized from acetone-water to give the free base m.p. 151°-152° (dec.). 

Reductive acetylation/alkylation has also provided access to advanced bis-THP intermediates of the type 284 in several reported pursuits of leucascandrolide A (Scheme 74) [76, 117, 131]. These complex examples highlight the remarkable functional group tolerance of this reaction type. The elaborate a-acetoxy ethers 283 demonstrate that a number of protecting groups (benzyl, silyl derivatives, and esters) survive the reaction conditions. Unsaturated silyl enol ethers (i.e., 281 and 282) are effective nucleophiles and provide advanced intermediates like 284 in excellent yields and diastereoselectivities (80-90 %, dr > 25 1 for all cases). A similar strategy, coupled with ring-closing metathesis, was also used by Cossy and coworkers for this natural product (Scheme 60) [108]. 

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). 

Section 27 16 Carboxyl groups are normally protected as benzyl methyl or ethyl esters Hydrolysis m dilute base is normally used to deprotect methyl and ethyl esters Benzyl protecting groups are removed by hydrogenolysis... 

Catalytic hydrogenolysis of an O-benzyl protective group is a mild, selective method introduced by Bergmann and Zervas to cleave a benzyl carbamate (> NCO—OCH2C6H5 > NH) prepared to protect an amino group during pep-... 

Several methoxy-substituted benzyl ethers have been prepared and used as protective groups. Their utility lies in the fact that they are more readily cleaved oxidatively than the unsubStituted benzyl ethers. The table below gives the relative rates of cleavage with dichlorodicyanoquinone (DDQ). ... 

The cleavage proceeds by initial reduction of the nitro groups followed by acid-catalyzed cleavage. The DNB group can be cleaved in the presence of allyl, benzyl, tetrahydropyranyl, methoxy ethoxy methyl, methoxymethyl, silyl, trityl, and ketal protective groups. 

A benzylidene acetal is a commonly used protective group for 1,2- and 1,3-diols. In the case of a 1,2,3-triol the 1,3-acetal is the preferred product. It has the advantage that it can be removed under neutral conditions by hydrogenolysis or by acid hydrolysis. Benzyl groups and isolated olefins have been hydrogenated in the presence of 1,3-benzylidene acetals. Benzylidene acetals of 1,2-diols are more susceptible to hydrogenolysis than are those of 1,3-diols. In fact, the former can be removed in the presence of the latter. A polymer-bound benzylidene acetal has also been prepared." ... 

Historically, simple Vz-alkyl ethers formed from a phenol and a halide or sulfate were cleaved under rather drastic conditions (e.g., refluxing HBr). New ether protective groups have been developed that are removed under much milder conditions (e.g., via nucleophilic displacement, hydrogenolysis of benzyl ethers, and mild acid hydrolysis of acetal-type ethers) that seldom affect other functional groups in a molecule. 

An isopropyl ether was developed as a phenol protective group that would be more stable to Lewis acids than an aryl benzyl ether. The isopropyl group has also been... 

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. 

S-Benzyl and substituted S-benzyl derivatives, readily cleaved with sodium/ammonia, are the most frequently used thioethers. n-Alkyl thioethers are difficult to cleave and have not been used as protective groups. Alkoxymethyl or alkylthio-... 

Hg(OAc)2, H2O, 80% AcOH, HSCH2CH2SH, 25°, 5-20 min H2S, 2 h, high yield. The removal of an 5-benzylthiomethyl protective group from a dithioacetal with mercuiy(II) acetate avoids certain side reactions that occur when an 5-benzyl thioether is cleaved with sodium/ammonia. The dithioacetal is stable to hydrogen bromide/acetic acid used to cleave benzyl carbamates. 

The protective group is removed by mildly alkaline conditions that do not cleave methyl or benzyl esters. The group is stable to CF3COOH, HCl-AcOH, and HBr-AcOH. A polymer-bound version of this group has also been developed. ... 

Many carbamates have been used as protective groups. They are arranged in this chapter in order of increasing complexity of stmcture. The most useful compounds do not necessarily have the simplest stmctures, but are /-butyl (BOC), readily cleaved by acidic hydrolysis benzyl (Cbz or Z), cleaved by catalytic hy-drogenolysis 2,4-dichlorobenzyl, stable to the acid-catalyzed hydrolysis of benzyl and /-butyl carbamates 2-(biphenylyl)isopropyl, cleaved more easily than /-butyl carbamate by dilute acetic acid 9-fluorenylmethyl, cleaved by /3-elimination with base isonicotinyl, cleaved by reduction with zinc in acetic acid 1-adamantyl, readily cleaved by trifluoroacetic acid and ally], readily cleaved by Pd-catalyzed isomerisation. 

Some advantages of the Fmoc protective group are that it has excellent acid stability thus BOC and benzyl-based groups can be removed in its presence. It is readily cleaved, nonhydrolytically, by simple amines, and the protected amine is liberated as its free base. The Fmoc group is generally considered to be stable to hydrogenation conditions, but it has been shown that under some circumstances it can be cleaved with H2/Pd-C, AcOH, MeOH, (t /2 = 3-33 h). ... 

Phosphinamides are stable to catalytic hydrogenation, used to cleave benzyl-derived protective groups, and to hydrazine. The rate of hydrolysis of phosphin-... 

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