Carboxyl groups, protection alkynes

Then we directly carried out click reaction between 40-fold excess of alkyne-PS and alkyne-(PlBA-N3)2 to result in PS-PfBA-PS triblock while 5-fold excess is not enough to suppress the self-polycondensation of alkyne-(PiBA-N3)2 chains (Fig. 4.16a). However, one problem to deal with is how to remove the excess of alkyne-PS chains from the mixtures of reaction products. Further TFA de-protection of tertiary butyl group into carboxyl group leads to the corresponding HB-(PAA) -g-(PS)n+i and PS-PAA-PS, which would facilitate the removal of excess alkyne-PS chains. In the precipitation-purification step, we repeated dissolution-precipitation cycle three times to remove excess alkyne-PS, where cyclohexane was used as precipitant, which is a good solvent for short PS, but a very poor solvent for HB-(PAA) -g-(PS) +i and PS-PAA-PS copolymers. Finally, purified white-powder of amphiphilic copolymer HB-(PAA)io-g-(PS)n = 6.30 x 10 g/mol), HB-(PAA)47- -(PS)48 (Afw = 2.60 X 10 g/mol) and their linear triblock analogues PS-PAA-PS (Afw = 7.50 X 10 g/mol) were obtained. 

Two new sections on the protection of phosphates and the alkyne-CH are included. All other sections of the book have been expanded, some more than others. The section on the protection of alcohols has increased substantially, reflecting the trend of the nineties to synthesize acetate- and propionate-derived natural products. An effort was made to include many more enzymatic methods of protection and deprotection. Most of these are associated with the protection of alcohols as esters and the protection of carboxylic acids. Here we have not attempted to be exhaustive, but hopefully, a sufficient number of cases are provided that illustrate the true power of this technology, so that the reader will examine some of the excellent monographs and review articles cited in the references. The Reactivity Charts in Chapter 10 are identical to those in the first edition. The chart number appears beside the name of each protective group when it is first introduced. No attempt was made to update these Charts, not only because of the sheer magnitude of the task, but because it is nearly impossible in... 

A synthetically useful virtue of enol triflates is that they are amenable to palladium-catalyzed carbon-carbon bond-forming reactions under mild conditions. When a solution of enol triflate 21 and tetrakis(triphenylphosphine)palladium(o) in benzene is treated with a mixture of terminal alkyne 17, n-propylamine, and cuprous iodide,17 intermediate 22 is formed in 76-84% yield. Although a partial hydrogenation of the alkyne in 22 could conceivably secure the formation of the cis C1-C2 olefin, a chemoselective hydrobora-tion/protonation sequence was found to be a much more reliable and suitable alternative. Thus, sequential hydroboration of the alkyne 22 with dicyclohexylborane, protonolysis, oxidative workup, and hydrolysis of the oxabicyclo[2.2.2]octyl ester protecting group gives dienic carboxylic acid 15 in a yield of 86% from 22. 

How to Use the Book to Locate Examples of the Preparation of Protection of Monofunctional Compounds. Examples of the preparation of one functional group from another are found in the monofunctional index on p. x, which lists the corresponding section and page. Sections that contain examples of the reactions of a functional group are found in the horizontal rows of this index. Section 1 gives examples of the reactions of alkynes that form new alkynes Section 16 gives reactions of alkynes that form carboxylic acids and Section 31 gives reactions of alkynes that form alcohols. 

Examples of the protection of alkynes, carboxylic acids, alcohols, phenols, aldehydes, amides, amines, esters, ketones, and alkenes are also indexed on p. xvii. Section (designated with an A 15A, 30A, etc.) with protecting group reactions are located at the end of pertinent chapters. 

Carboxylic acids can be protected as oxazolines [96, 105-107, 186, 191] or as ester functions. Alkynic esters such as silyl esters [153, 211], tert-butyl esters [216], and even benzyl esters [153, 211] have been successfully hydrozirconated when the reactive site was a terminal alkyne or vinyl group (Scheme 8-27). 

Activation by addition of a carboxylic acid to a triple bond occurs with ethyl ethynyl ether,which forms amides via reactive enol esters. The reaction is catalyzed by mercury(II) oxide under almost neutral conditions. Push-pull alkynes exert higher reactivityThe intermediate enol esters (Scheme 4) rearrange and react with the amino function of a second amino acid. Hydroxy, thiol and imidazole functional groups do not have to be protected. The degree of racemization is low, and yields are good in the case of small peptides. 

Dihydro-2-isopropyl-3.6-dimethoxypyrazine, a bis(lactim)ether, is converted into the 5-di-azo compound 1 by lithiation and diazo group transfer. The intermediate diazo compound reacts at room temperature with olefins such as cyclohexene to produce the cyclopropane derivatives with excellent diastereoselectivity . The derivative from cyclohexene is hydrolyzed by acid treatment to give methyl 7-cv(cfo-aminobicyclo[4.1.0]hcptane-7-carboxylate. The bis(lac-tim)ether diazo compound 1 is also involved in an exceptional asymmetric [2 + 1J cycloaddition producing cnantiomerically pure cyclopropenc derivatives4. Thus, reactions of the diazo compound with monosubstituted alkynes afford the spiro compounds as one diastereomer. Hydrolytic removal of the auxiliary and protection of the amino group provides enantiomerically pure methyl l-amino-2-arylcyclopropene-l-carboxylates in moderate overall yield. 

Hydrozirconation of alkenes as a route to rr-alkylzirconiums is limited by other reactive functional groups e.g., alkynes react more readily than alkenes with (/j -Cp)2ZrHCl, and other reactive functional groups with ( / -Cp)2ZrHCl include alcohols, aldehydes, ketones, carboxylic acids, carboxylic acid esters, nitriles and thiocarbonyls . Alcohols may be protected either as alkyl ethers or as trialkylsilyl ethers. 

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