Esters, preparation from acids, diazomethane

Esters prepared from corresponding acids diazomethane. 

Poly(itaconic acid) has also been prepared in a 0.2M/liter aqueous solution using potassium persulfate at 50 C over a 5-hr period under reduced pressure. After the polymer is reprecipitated twice into methanol-ethyl acetate, a polymer is isolated with a molecular weight of 1.64 x 10, determined by vapor pressure osmometry of a methanolic solution of the methyl ester prepared from the polymer [49]. Unfortunately Tsuchida and coworkers did not report on the quantitative extent to which poly(methyl itaconate) had been formed from this polymer (presumably by reaction with diazomethane). Consequently, there is little in the literature to confirm or dispute the paper by Braun and Azis el Sayed [97], which offered evidence that during the free-radical polymerization of itaconic acid, carbon dioxide evolves to a considerable extent. During the process, it seems that hydroxyl and formyl radicals are generated and incorporated in the macromolecule. It is proposed by these authors that the homopolymer of itaconic acid contains virtually no itaconic acid repeat units but rather intramolecular lactone rings and acetal- or hemiacetal-like moieties. Since the polymer remains soluble in the reaction solvent (dioxane). 

The Arndt-Eistert reaction (Scheme 2.1) which involves the Wolff rearrangement of diazoketones 13 (prepared from the corresponding commercially available N-protected-a-amino acids 12 by reaction of their mixed anhydrides with diazomethane a cautionary note is warranted here the generation and handling of diazomethane require special precautions) has been used extensively by Seebach and coworkers for the preparation of N-protected /9 -amino acids 14 and /9 -amino acid esters 15 and 16. 

Pyrrole-2-carboxylic acid esters have been prepared from ethyl chloroformate and pyrrolylmagnesium bromide1 2 or pyrrolyllithium,3 by hydrolysis and decarboxylation of dimethyl pyrrole-1,2-dicarboxylate followed by re-esterification of the 2-acid4 and by oxidation of pyrrole-2-carboxaldehyde followed by esterification with diazomethane.4... 

Polystyrene-bound benzhydryl- or trityl halides react much more rapidly with carboxylates than chloromethyl polystyrene, and the base used to form the carboxylate no longer plays a decisive role in these reactions (see Experimental Procedure 13.7). Support-bound phenyldiazomethanes have been used to prepare esters directly from carboxylic acids under mild reaction conditions. Unfortunately, the diazomethanes required are not easy to prepare, and have not yet found widespread application. 

The parent of the diazo compounds, diazomethane, CH2=N=N, has been mentioned before in connection with ylide reactions for ring enlargement (Section 16-4A) and the preparation of methyl esters from acids (Table 18-7). It is one of the most versatile and useful reagents in organic chemistry, despite the fact that it is highly toxic, dangerously explosive, and cannot be stored without decomposition. 

In the event, iodolactonization of the carboxylate salt derived from the ester 458 afforded 459, and subsequent warming of the iodo lactone 459 with aqueous alkali generated an intermediate epoxy acid salt, which suffered sequential nucleophilic opening of the epoxide moiety followed by relactonization on treatment with methanol and boron trifluoride to deliver the methoxy lactone 460. Saponification of the lactone function in 460 followed by esterification of the resulting carboxylate salt with p-bromophenacylbromide in DMF and subsequent mesylation with methanesulfonyl chloride in pyridine provided 461. The diazoketone 462 was prepared from 461 by careful saponification of the ester moiety using powdered potassium hydroxide in THF followed by reaction with thionyl chloride and then excess diazomethane. Completion of the D ring by cyclization of 462 to the keto lactam 463 occurred spontaneously on treatment of 462 with dry hydrogen chloride. 

Sulphonic acids are usually esterified with diazomethane [121] by methods analogous to those used for the preparation of esters of carboxylic acids (see p. 54). If the reaction starts from the salts, it is necessary to convert them into acids either by direct acidification or with the aid of a cation-exchange resin in the H+ form. 

Selenolate 1 [1,2], prepared from diphenyl diselenide by reduction with NaBH4 in ethanol, is not reactive enough towards esters and lactones. However, application of more rigorous conditions, i. e. at 110-120 °C in dry DMF for lactones 15, affords the corresponding ring-opened products, cu-phenylselenyl carboxylic acids 16, in good yields [44]. Compounds 16 can be easily converted to co-ole-finic methyl esters 17 by treatment with diazomethane followed by oxidative elimination of the phenylseleno group (Scheme 25). By contrast, the uncomplex-... 

Esters of a-hydroxymethyl ketones are formed by heating diazoketones with organic acids. The crude diazoketones prepared from acyl halides and diazomethane may be used. The over-all yields of acetoxy ketones, ArCOCHjO,CCHj, from benzoyl and /3-naphthoyl chlorides are 55% and 72%, respectively. ... 

Although known for almost forty years, and in spite of a total synthesis of its racemate, the stereochemistry of doisynolic acid has remained in doubt. This problem has now been settled by a stepwise chemical conversion (Scheme 23) of 14)5-oestrone methyl ether (339), prepared from natural oestrone (114a), into c/s-doisynolic acid methyl ether (342). Osmium tetroxide oxidation of the enol acetate corresponding to (339) provided 16a-hydroxy-14)S-oestrone methyl ether. Subsequent periodic acid oxidation afforded the lactol (340), which upon treatment with diazomethane gave the aldehydo-ester (341). Electrochemical reduction of the aldehyde (341) afforded a methyl ester which by alkaline hydrolysis provided (-f )-ds-doisynolic acid 3-methyl ether (342), thus defining its complete stereochemistry. ... 

By the employment of other bromides O-desmethylmycophenolic acid was obtained. Thus, the C7 bromoester methyl 6-bromo-4-methylhex-4-enoate, BrCH2CH=C(Me)CH2CH2C02Me, was prepared from tritylgeraniol which was first converted in several steps to the terminal diol, Malaprade oxidation of which furnished 4-methy-6-trityloxylhex-4-enal. Mild oxidation to, the corresponding acid with silver oxide, formation of the methyl ester with diazomethane and derivation of the required allylic bromide by treatment of the alcohol, liberated from the trityl derivative, with carbon tetrabromide containing triphenylphosphine completed the synthesis. 

Various ways of functionalization of the lactol 205 leading to C-nucleoside analogs were described.Compound 205 readily reacted with carboethoxymethylenetriphenylphosphorane with formation of trans ester 212, whereas the Wittig reagent prepared from pyruvate ester gave a product of an intramolecular Michael reaction (221). Acrylate ester 212 was converted on addition of diazomethane into pyrazoline 213, and further, by successive brom-ination-dehydrobromination followed by acid hydrolysis, was transformed into DL-3-(carboxamido)-4-P-ribofuranosylpyrazole 214. Another precursor of heterocyclic C-ribofuranosides (215) was obtained in the reaction of lactol 205 with... 

Bromonicotinic acid [20826-04-4] M 202.0, m 178-182°, 189-190°, pKEst 4.4, pK 4.02 (50% aqueous EtOH). The acid is recrystallised from H2O and then from EtOH using charcoal. The amide has m 219-219.5° (from aqueous EtOH), and the methyl ester, prepared by addition of ethereal diazomethane, can be pnrified by sublimation in a vacuum and has m 98-99°. The acid chloride also can be sublimed in vacuo and has m 74-75° and gives the methyl ester in MeOH. [Graf J Prakt Chem 138 244 1933, Bachman Micucci JA/n Chem Soc 70 2381 1948, Garcia et al. J Am Chem Soc 82 4430 1960, Misic-Vokovic et al. J Chem Soc 34 1978, Beilstein 22/2 V 181.]... 

Esters can be prepared by acid-catalyzed esterification or by reaction of the acid chloride with the alcohol. In small-scale syntheses, it is often more convenient to prepare the ester by reaction of the carboxylic acid with the appropriate diazo compound. Diazomethane is routinely used for making methyl esters, but more highly substituted esters can be prepared if the corresponding diazo compound is available. Benzhydryl esters, for example, are readily prepared from carboxylic acids by reaction with diphenyldiazomethane ... 

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