Alcohols, hindered esterification

Esterification. The esterification of rosin provides important commercial products for the adhesive industry. Rosin esters are formed by the reaction of rosins with alcohols at elevated temperatures. Because the carboxyl group of the resin acids is hindered by attachment to a tertiary carbon, esterification with an alcohol can only be accomplished at elevated temperatures. This hindrance is in turn responsible for the high resistance of the resin acid ester linkage to cleavage by water, acid and alkali. 

AC2O or AcCl, Pyr, DMAP, 24-80°, 1-40 h, 72-95% yield. The use of DMAP increases the rate of acylation by a factor of lO. These conditions acylate most alcohols, including tertiary alcohols. The use of DMAP (4-A,A-dimethylaminopyridine) as a catalyst to improve the rate of esterification is quite general and works for other esters as well, but it is not effective with hindered anhydrides such as pivaloic anhydride. The phosphine i (48-99% yield) and Bu3P have been developed as active acylation catalysts for acetates and benzoates. 

Esterification of tertiary alcohols poses several problems and expensive catalysts, like dimethylamino pyridine, are recommended. While esterification/transesterification/hydrolysis involving primary and secondary alcohols has been reported both with chemocatalysts and biocatalysts, terf-alcohol based esters have not found success. Recent work of Yeo et al. (1998) reports successful results for /er/-butyl octonoate using a new strain of lipase. This is a significant finding as the production of esters based on fert-alcohols (and reciprocally with hindered acids) may well be possible with biocatalysts, avoiding expensive catalysts and allowing easier separation. 

As has been mentioned, preparation of esters of the C-17 hydroxyl group of selected progestins affords compounds with prolonged action. Similar chemical treatment of a corticoid would almost certainly lead to an ester of the sterically more accessible primary alcohol at C-21. In an interesting method for achieving esterification of the more hindered and less reactive tertiary 17-hydroxyl, prednisolone... 

Exactly the same considerations apply to the esterification of hindered acids (182) in the reverse direction. It will be noticed that this mechanism requires protonation on the less favoured (cf. p. 240) hydroxyl oxygen atom (185) to allow the formation of the acyl carbocationic intermediate (184). Apart from a number of R3C types, a very well known example is 2,4,6-trimethylbenzoic (mesitoic) acid (186), which will not esterify under ordinary acid-catalysis conditions—and nor will its esters (187) hydrolyse. Dissolving acid or ester in cone. H2S04 and pouring this solution into told alcohol or water, respectively, is. found to effect essentially quantitative esterification or hydrolysis as required the reaction proceeds via the acyl cation (188) ... 

Another important use of solubility parameters is in interpreting the effects of different solvents on the rates of reactions. In a chemical reaction, it is the concentration of the transition state that determines the rate of the reaction. Depending on the characteristics of the transition state, the solvent used can either facilitate or hinder its formation. For example, a transition state that is large and has little charge separation is hindered in its formation by using a solvent that has a high value of S. The volume of activation is usually positive for forming such a transition state which requires expansion of the solvent. A reaction of this type is the esterification of acetic anhydride with ethyl alcohol ... 

ESTERIFICATION OF HINDERED ALCOHOLS tert-BUTYL p-TOLUATE, 51, 96 Esters, from diazoketones and organoboranes, 53, 82 Esters, a-deuterio-, 53, 82 Esters, y [Pg.59]

Electrolytic reduction, apparatus, 52, 23 Enol acetates, acylation of, 52,1 Enol esters, preparation, 52, 39 Epichlorohydrin, with boron trifluoride diethyl therate and dimethyl ether to give trimethyloxonium tetra-fluoroborate, 51,142 ESTERIFICATION OF HINDERED ALCOHOLS f-BUTYL p-TOLUATE,... 

The present procedure4 is an especially effective method for the synthesis of esters of aromatic acids and hindered tertiary alcohols or of acid-labile alcohols such as 2,2-diphenylethanol. The yields are excellent, and the reaction procedure is simple. The method is illustrated by the preparation of /-butyl p-toluate, a compound that could not be prepared by a conventional method0 of esterification involving the acid chloride and /-butanol in the presence of dimothylaniline. Examples of esters prepared by this method are illustrated in Table I. 

Notes A basic catalyst for amine and alcohol acylations, (particularly useful for hindered alcohols), macrocyclization, and for Steslich esterification. DMAPIPCC provides a useful oxidation protocol.1 Examples l.2... 

Esterification of acids with bulky substituents, such as 2,4,6-trimethyl-benzoic acid, can be achieved through formation of acyl cations. This is done by simply dissolving the carboxylic acid in strong sulfuric acid, whereby the acyl cation 11 is formed, and then pouring the solution into an excess of cold alcohol (see also Equations 18-5 and 18-6). This procedure works because it avoids the formation of a hindered tetrahedral intermediate similar to 10 and instead forms the conjugate acid directly ... 

Amino acylations.1 This salt is far more reactive, particularly for O-acylation, than N,N -carbonyldiimidazole. Thus it effects esterification of N-Cbz protected amino acids with even hindered alcohols such as /-menthol in 98% yield without need of a base and, consequently, free from racemization. It also can effect coupling of amino acids in high yields and without racemization. 

In general, the acid catalyzed esterification of organic acids can be accomplished easily with primary or secondary alkyl or aryl alcohols, but tertiary alcohols usually give carbonium ions which lead to dehydration. The structure of the acid is also of importance. As a rule, the more hindered the acid is alpha to the carbonyl carbon the more difficult esterification becomes (20A). 

In this process, epoxidation of the double bonds was followed by reduction to obtain the tert-alcohol which was esterified with methacryloyl chloride in the subsequent step. While epoxidation was found to be close to quantitative based on double bond content, reduction was incomplete and the residual epoxy functional PIB (24-47%) had to be separated by column chromatography before esterification. It should be noted that this macromonomer was a tert-ester which might be quite unstable in acidic conditions, and is also more hindered than the... 

Steric factors can also play a part in the reactivity of acid derivatives. For example, a bulky group attached to the carbonyl group can hinder the approach nucleophiles and hence lower reactivity. The steric bulk of the nucleophile can also have an influence in slowing down the reaction. For example, acid chloride react faster with primary alcohols than they do with secondary or tertiary alcohols. This allows selective esterification if a molecule has more than one alcohol group present ... 

Esterification.1 This reagent in combination with a catalytic amount of 4-dimethylaminopyridine (DMAP) is very effective for esterification of carboxylic acids with alcohols or thiols at room temperatures. However, reaction of aromatic and hindered acids requires several days at room temperature. French chemists report that only this method is useful for esterification of the protected baccatin III derivative (2) with (2R,3S)-N-benzoyl-0-(l-ethoxyethyl)-3-phenylisoserine (3) to provide the protected taxol derivative (4). A reaction conducted at 73° for 100 hours with 6 equiv. of 1 and 2 equiv. of DMAP produced 4 in 80% yield. Natural taxol, a cancer chemotherapeutic agent, is obtained by removal of the protective groups at C2 and C7 of 4. 

Pentafluoropropionyl and heptafluorobutyryl derivatives have also been used for the GC analysis of amino acids in combination with esterification with various alcohols. In comparison with TFA derivatives, they are much more stable and resitant to hydrolysis, their retention times are shorter and all twenty protein amino acids can be separated on common phases (OV, SE, etc.). The price and restricted availability of the acylation reagents obviously hinder their wider application. 

A wide variety of organic solvents has been used to conduct bioconversions including nonpolar solvents such as isooctane, n-hexane, and toluene, in addition to methanol, acetone, and other water-miscible solvents. Dipolar aprotic solvents dimethylformamide (DMF) and dimethylsulfoxide (DMSO) are also compatible with many enzymes and are often used to enhance the solubility of substrates in combination with a nonpolar solvent. Tertiary alcohols such as f-butanol and t-amyl alcohol have been used for many lipase-mediated esterifications as the hindered tertiary alcohol is not typically a good substrate for most enzymes. It should be noted that the presence of small amounts of water is essential for the effective use of most biocatalysts in organic solvents. In some cases an enzyme may only require a monolayer of water molecules on its surface in order to operate. In other cases there may need to be enough water to form reverse micelles where the biocatalyst is contained within a predominantly aqueous... 

Anderson, Goodman, and Baker employed an O-(methoxycarbonyl) protecting group in an analogous manner for their synthesis of methyl 2,3-anhydro-D-ribofuranoside (XLV). Treatment of 1,2-0-isopropylidene-D-xylofuranose (XLI) with methyl chloroformate in pyridine gave, by preferential esterification of the least-hindered alcohol group (at C5), predominantly 1,2-0-isopropylidene-5-0-(methoxycarbonyl)-D-xylofuranose (XLII) a small proportion of the 3,5-di-0-(methoxycarbonyl) derivative was separated by fractional recrystallization. Subsequently, the C3-hydroxyl was esterified with tosyl chloride, and the resulting 3-0-tosyl ester XLIII... 

Esterification. The related salt dimethylchloroforminium chloride has been used for esterification (8, 186), but has the disadvantage that alkyl chlorides are also formed as by-products. The salt 1 does not activate an alcohol group and, in the presence of pyridine as base, it effects esterification of acids (even hindered ones) with primary and secondary alcohols in high yield. Esterification with hindered tertiary alcohols is possible, but slow. 

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