Transesterification with halides

Without additional reagents Mixed phosphorus esters by transesterification with halides... 

The diphenylphosphoryl group has been used as an alternative to arylidene groups for the protection of glucosaminyl halides during the synthesis of nucleosides [231] and disaccharides [232]. On completion of the reaction sequence the group is converted into the dibenzylphosphoryl group by transesterification with benzyl alcohol containing ammonia, then removed as described above. 

In our previous works[8,9] on the synthesis of various 5-membered cyclic carbonate, quaternary ammonium salts such as tetrabutylammonium halides showed excellent catalytic activities in relatively mild reaction conditions, under atmospheric pressure and below 140 U. hi this work, several kinds of quaternary ammonium salts have been used for the transesterification reactions of the ethylaie carbonate with methanol to DMC and ethylene glycol. 

The various tri-, di- and monoorganotin hydroxides and oxides that can be obtained by partial or complete hydrolysis of the corresponding halides or carboxylates often behave as catalysts for reactions such as esterification or transesterification, and it is partly with the aim of obtaining better and more selective catalysts that a lot of work has been carried out on these compounds in the past decade.347... 

The esters of salicylic acid account for an increasing fraction of the salicylic acid produced, about 15% in the 1990s. Typically, the esters are commercially produced by esterification of salicylic acid with the appropriate alcohol using a strong mineral acid such as sulfuric as a catalyst. To complete the esterification, the excess alcohol and water are distilled away and recovered. The cmde product is further purified, generally by distillation. For the manufacture of higher esters of salicylic acid, transesterification of methyl salicylate with the appropriate alcohol is the usual route of choice. However, another reaction method uses sodium salicylate and the corresponding alkyl halide to form the desired ester. 

Alcoholysis of trihalides 0-6 Hydrolysis of ortho esters 0-20 Alcoholysis of acyl halides 0-21 Alcoholysis of anhydrides 0-22 Esterification of carboxylic acids 0-23 Transesterification 0-24 Alkylation of carboxylic acid salts 0-25 Cleavage of ethers with anhydrides 0-26 Alkylation of carboxylic acids with diazo compounds... 

Enol Ethers and Esters 0-15 O-Alkylation of carbonyl compounds with diazo alkanes 0-17 Transetherification 0-20 Reaction between acyl halides and active hydrogen compounds 0-23 Transesterification 0-24 Acylation of vinylic halides 0-94 Alkylation with ortho esters 0-107 O-Acylation of 1,3-dicarbonyl compounds... 

Isosorbide 2-acetate may also be prepared by transesterification of equimolar amounts of isosorbide 2,5-diacetate and isosorbide in the presence of acidic or basic catalysts (KOH or p-toluenesulfonic acid, for 1 hat 140°, and distillation104,107 of the 2-acetate at 100° at 27 kPa 89%). Subsequent esterification of the resulting isosorbide mononitrates with acyl and aroyl halides... 

Important examples of this type of compounds include pinacolborane, catecholborane, etc. These compounds are readily available by the reaction of pinacol 331 or catechol with either borane or boron halides. Transesterification also provides an attractive alternative for the synthesis of these compounds (Scheme 55). 

Tin(iv) enolates are normally generated by transmetallation from lithium enolates with trialkyltin halides or transesterification between enol acetates with trialkyltin alkoxides.220 Other types of generation systems are described below. 

The 4-methoxybenzyl esters are prepared by transesterification of N-protected amino acid nitrophenyl esters with 4-methoxybenzyl alcohol in the presence of several equivalents of imidazole, followed by subsequent acidolytic cleavage of the N-protecting group.Alternatively, reaction of N-protected amino acids silver(I) salts with 4-methoxybenzyl halides (TEA/CHCI3, rt, 24 h, 60% yield) or treatment of N-protected amino acids with 4-meth-... 

Transesterification has been carried out with phase-transfer catalysts, without an added solvent. Nonionic superbases (see p. 365) of the type P(RNCH2CH2)3N catalyze the transesterification of carboxylic acid esters at 25°C. ° Silyl esters (R C02SiR3) have been converted to alkyl esters (R C02R) via reaction with alkyl halides and tetrabutylammonium fluoride. Thioesters are converted to phenolic esters by treatment with triphosgene-pyridine and then phenol. 

The preparation of esters can be classified into two main categories (1) carboxylate activation with a good leaving group and (2) nucleophilic displacement of a carboxylate on an alkyl halide or sulfonate. For simple esters, acid-catalyzed esterification with azeotropic removal of water is also very effective, but limited to simple systems for the most part. The nucleophilic approach is generally not suitable for the preparation of esters if the halide or tosylate is sterically hindered, but there has been some success with simple secondary halides and tosylates (ROTs, DMF, K2CO3, 69-93% yield). The section on transesterification should also be consulted, since this technology can be quite useful for the preparation of esters from other esters. 

In 1982, Evans reported that the alkylation of oxazolidinone imides appeared to be superior to either oxazolines or prolinol amides from a practical standpoint, since they are significantly easier to cleave [83]. As shown in Scheme 3.17, enolate formation is at least 99% stereoselective for the Z(0)-enolate, which is chelated to the oxazolidinone carbonyl oxygen as shown. From this intermediate, approach of the electrophile is favored from the Si face to give the monoalkylated acyl oxazolidinone as shown. Table 3.6 lists several examples of this process. As can be seen from the last entry in the table, alkylation with unactivated alkyl halides is less efficient, and this low nucleophilicity is the primary weakness of this method. Following alkylation, the chiral auxiliary may be removed by lithium hydroxide or hydroperoxide hydrolysis [84], lithium benzyloxide transesterification, or LAH reduction [85]. Evans has used this methology in several total syntheses. One of the earliest was the Prelog-Djerassi lactone [86] and one of the more recent is ionomycin [87] (Figure 3.8). 

The reactions proceed with a high yield. In the case of halide derivatives evolved HCl is bound by Py and/or NH3. The transesterification methods are applicable to those cases when the substitution is conducted using an alcohol with a boiling point that is higher than that of the alcohol to be substituted. By this method mixed titanates have also been prepared (Fig. 4-2). The released alcohol can be removed from the reaction mixture either directly during the synthesis or as an azeotropic solution with solvent (most often with benzene). 

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