Anhydrides, alcoholysis reaction

Dibenzylamine substitution and alcoholysis compete in reactions of PhP(X)Cl2, where X = O or S, in stabilized chloroform as a solvent.344 The oxy-compound gives both PhPO[N(CH2Ph)2]2OEt and PhPO(OEt)2, but when the stabilizer is removed the products are PhPOCl[N(CH2Ph)2] and the anhydride (44). Reactions of the thio-derivative are similar, but two... 

Some references cover direct preparation of the different crystal modifications of phthalocyanines in pigment form from both the nitrile—urea and phthahc anhydride—urea process (79—85). Metal-free phthalocyanine can be manufactured by reaction of o-phthalodinitrile with sodium amylate and alcoholysis of the resulting disodium phthalocyanine (1). The phthahc anhydride—urea process can also be used (86,87). Other sodium compounds or an electrochemical process have been described (88). Production of the different crystal modifications has also been discussed (88—93). 

Acidic contaminants are poisonous to the alcoholysis catalysts and must be avoided. If the oil has a high acid number, or there are high acidity residues left in the reactor from the previous batch, such as sublimed phthaUc anhydride condensed under the dome of the reactor, the reaction can be severely retarded. A longer batch time or additional amount of catalyst is then required. Both are undesirable. 

The acid chlorides are generally more reactive than the corresponding acid anhydrides. In fact, the alcoholysis of acid chlorides is probably the best laboratory method for preparing esters. Frequentiy, basic materials are added during the course of the reaction to neutralize by-product hydrochloric acid. When the basic material is aqueous caustic, the procedure is referred to as the Schotten-Baumann procedure (73). Esterification of tertiary alcohols by acid chlorides is described in Reference 74. Esters of tertiary alcohols can also be formed through an intermediate /-butyl thioate group (75) ... 

Polyesters have been obtained in organic medium by polyesterification of hydroxy acids,328,329 hydroxy esters,330 stoichiometric mixtures of diols and diacids,331-333 diols and diesters,334-339 and diols and cyclic anhydrides.340 Lipases have also been reported to catalyze ester-ester interchanges in solution or in die bulk at moderate temperature.341 Since lipases obviously catalyze the reverse reaction (i.e., hydrolysis or alcoholysis of polyester), lipase-catalyzed polyesterifications can be regarded as equilibrium polycondensations taking place in mild conditions (Scheme 2.35). 

Chemoenzymatic synthesis of alkyds (oil-based polyester resins) was demonstrated. PPL-catalyzed transesterification of triglycerides with an excess of 1,4-cyclohexanedimethanol mainly produced 2-monoglycerides, followed by thermal polymerization with phthalic anhydride to give the alkyd resins with molecular weight of several thousands. The reaction of the enzymatically obtained alcoholysis product with toluene diisocyanate produced the alkyd-urethane. 

The compounds referred to as azolides are heterocyclic amides in which the amide nitrogen is part of an azole ring, such as imidazole, pyrazole, triazole, tetrazole, benzimidazole, benzotriazole, and their substituted derivatives. In contrast to normal amides, most of which show particularly low reactivities in such nucleophilic reactions as hydrolysis, alcoholysis, aminolysis, etc., the azolides are characterized by high reactivities in reactions with nucleophiles within the carbonyl group placing these compounds at about the same reactivity level as the corresponding acid chlorides or anhydrides. 11... 

Hydrolases catalyze the hydrolytic cleavage of C-0, C-N, C-C, and some other bonds including phosphoric anhydride bonds. They possess several attractive features, such as broad substrate selectivity and high stereospecificity. This has made them a popular choice for the conduction of many biotransformafions as well as a powerful addition to the organic chemistry toolbox. Hydrolases also often catalyze several related reactions, such as condensations and alcoholysis. 

Alcoholysis of meso-cycYic anhydrides offers a versatile route to succinate and glu-tarate half-esters. Although a number of stoichiometric approaches to this problem have been investigated, a successful catalytic version of this reaction appeared as recently as 2003. ° Bolm and coworkers have developed a protocol for the metha-nolysis of a variety of succinic anhydrides using cinchona alkaloids [Eq. (10.50)]. The reaction may be made catalytic in alkaloid when pentamethylpiperidine is used as a stoichiometric additive. A moderate decrease in enantioselectivity is observed in a number of cases, although excellent selectivities are still attainable. More problematic is the reaction time (6 days under catalytic conditions) ... 

Deng also showed that (DHQD)2AQN could catalyze the parallel KR (PKR) of a variety of monosubstituted succinic anhydrides via asymmetric alcoholysis [215]. The nature of the solvent was found to have a significant influence on the selectivity. Hence, increasing the size of the alcohol from methanol to ethanol resulted in increased levels of enantioselectivity, albeit with reduced reaction rates. In this context, 2,2,2-trifluoroethanol appeared to be the alcohol of choice as it allowed the ASD of 2-methyl succinic anhydride (58a) with a remarkable level of selectivity. Indeed, the use of (DHQD)2AQN (15 mol%) provided a mixture of two regioiso-meric hemiesters 59a and 60a in a 1 1 ratio with 93 and 80% ee respectively. 

Mannitol hexanitrate is obtained by nitration of mannitol with mixed nitric and sulfuric acids. Similarly, nitration of sorbitol using mixed acid produces the hexanitrate when the reaction is conducted at 0—3°C and at —10 to —75°C, the main product is sorbitol pentanitrate (117). Xylitol, ribitol, and L-arabinitol are converted to the pentanitrates by fuming nitric acid and acetic anhydride (118). Phosphate esters of sugar alcohols are obtained by the action of phosphorus oxychloride (119) and by alcoholysis of organic phosphates (120). The 1,6-dibenzene sulfonate of D-mannitol is obtained by the action of benzene sulfonyl chloride in pyridine at 0°C (121). To obtain 1,6-dimethanesulfonyl-D-mannitol free from anhydrides and other by-products, after similar sulfonation with methane sulfonyl chloride and pyridine the remaining hydroxyl groups are acetylated with acetic anhydride and the insoluble acetyl derivative is separated, followed by deacetylation with hydrogen chloride in methanol (122). Alkyl sulfate esters of polyhydric alcohols result from the action of sulfur trioxide—trialkyl phosphates as in the reaction of sorbitol at 34—40°C with sulfur trioxide—triethyl phosphate to form sorbitol hexa(ethylsulfate) (123). 

The reaction proceeds through an intermediate mixed anhydride, or the symmetrical anhydride derived from it, and subsequent alcoholysis in the presence of the hydroxy com-ponent.123-251... 

Kinetic resolution of chiral, racemic anhydrides In this process the racemic mixture of a chiral anhydride is exposed to the alcohol nucleophile in the presence of a chiral catalyst such as A (Scheme 13.2, middle). Under these conditions, one substrate enantiomer is converted to a mono-ester whereas the other remains unchanged. Application of catalyst B (usually the enantiomer or a pseudo-enantiomer of A) results in transformation/non-transformation of the enantiomeric starting anhydride ). As usual for kinetic resolution, substrate conversion/product yield(s) are intrinsically limited to a maximum of 50%. For normal anhydrides (X = CR2), both carbonyl groups can engage in ester formation, and the product formulas in Scheme 13.1 are drawn arbitrarily. This section also covers the catalytic asymmetric alcoholysis of a-hydroxy acid O-carboxy anhydrides (X = O) and of a-amino acid N-carboxy anhydrides (X = NR). In these reactions the electrophilicity of the carbonyl groups flanking X is reduced and regioselective attack of the alcohol nucleophile on the other carbonyl function results. 

Quite remarkable progress has also been achieved in enantioselective transformation of cyclic anhydrides derived from a-hydroxy and a-amino carboxylic acids. By careful choice of the reaction conditions, dynamic kinetic resolution by alcoholysis has become reality for a broad range of substrates. Again, the above mentioned dimeric cinchona alkaloids were the catalysts of choice. In other words, organoca-talytic methods are now available for high-yielding conversion of racemic a-hydroxy and a-amino acids to their enantiomerically pure esters. If desired, the latter esters can be converted back to the parent - but enantiomerically pure - acids by subsequent ester cleavage. 

The alcoholysis of anhydrides (Reaction XVI) is similar in scope to the reaction of alcohols with acyl halides. The reaction is catalyzed by general esterification catalysts, but usually they are not needed unless the anhydride is unreactive or the di-ester (such as a phthalate) is the product sought. 

It might be anticipated that, if a racemic unsymmetrically substituted cyclic anhydride were to be used as a substrate for asymmetric alcoholysis, a KR would ensue. In fact, Deng has shown that for monosubstituted succinic anhydrides, because both carbonyl groups have comparable reactivity, what actually occurs on subjection to his (DHQD)2AQN-catalyzed asymmetric alcoholysis conditions, is a PKR [188]. Thus, the reaction of 2-methyl succinic anhydride (39a) with 2,2,2-trifluoroethanol (10 equiv.) in ether at —24 °C in the presence of (DHQD)2AQN (15 mol%) provided a mixture of two regioisomeric hemiesters... 

Each structural assignment of signals 1-7 in the spectrum of Figure 4 is based on the addition of the authentic compound to the crude ozonolysis mixture, and—aside from peak 1—is also based on additional analytical evidence 2,2,3,3-tetrabromobutane (peak 2), 3,3-dibromobu-tanone (peak 4), and acetic acid were actually isolated while acetyl bromide (peak 3) as well as acetic anhydride (peak 5) were further identified by their sensitivity to solvolysis reactions, particularly hydrolysis and alcoholysis to form the corresponding esters. Diacetylperoxide (peak 6) was identified by the disappearance of peak 6 from the NMR spectrum as well as the disappearance of the typical infrared bands at 1810 and 1835 cm"1 when the reaction mixture was treated with sodium iodide. 

The arsonons esters are easily synthesized by the reaction of the dihaloarsines with alcohols or alkoxides. With alcohols, CaCl2 mnst be present because the esters are very sensitive toward hydrolysis, which leads to the reformation of the anhydride (equation 129). The reaction of an alcohol with a bisaminoarsine leads to an arsonous ester (equation 130), as does the alcoholysis of the anhydride. Reaction of diols with bis(drmethylamino)alkylarsines leads to esters of macrocycUc arsinous acid. ... 

Polymers with pendant groups that are derivatives of carboxylic acid can he hydrolyzed to yield poly(acrylic acid). This includes polymers like polyacrylamide, polyacrylonitrile, and polyacrylates. When heated, poly(acrylic acid) form polymeric anhydrides, which undergo typical reactions of anhydrides, such as hydrolysis, alcoholysis, and amidation. 

Nucleophilic attack by a primary alcohol on the gamma phosphate of ATP (alcoholysis of an acid anhydride). This is a very favourable reaction. 

There has been considerable interest in the stereoselective ring opening of meso-cyclic anhydrides. The stereoselective alcoholysis of these anhydrides is particularly attractive as the resulting hemiesters are used as versatile intermediates in the construction of many bioactive compounds [1], Much effort has, therefore, been devoted to the development of efficient enzymatic and nonenzymatic catalytic systems for this reaction [2], Among the stereoselective catalysts developed to date,... 

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