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Amide formation mixed anhydride

In a similar manner resonance affects greatly the rate of racemization by reducing the energy required for ionization. This point is discussed with reference to a-phenylamino acids and particularly with regard to amide resonance in acylamino acids, peptides, diketopiperazines and hydantoins. The literature on the racemization of proteins by alkali is also reviewed. The racemization which is observed during acylation of amino acids is also discussed, and it is pointed out that apart from oxazolone formation, mixed anhydrides may also occur as intermediates and be partly responsible for the racemization observed. [Pg.362]

The phosphinic isocyanates (116) and isothiocyanates (117) react with oxygen, nitrogen, and phosphorus nucleophiles by attack at carbon rather than phosphorus. Phenyl phosphonodichloridate has been recommended as a useful reagent for the activation (presumably by mixed anhydride formation) of carboxylic acids for conversion to amides and hydrazides. ... [Pg.119]

Carboxylic acids can also be activated by the formation of mixed anhydrides with various phosphoric acid derivatives. Diphenyl phosphoryl azide, for example, is an effective reagent for conversion of amines to amides.140 The proposed mechanism involves formation of the acyl azide as a reactive intermediate. [Pg.254]

Another useful reagent for amide formation is compound 1, known as BOP-C1,141 which also proceeds by formation of a mixed carboxylic phosphoric anhydride. [Pg.255]

It is well documented that the isoimide is the kinetically favoured product and that isomerization yields the thermodynamically stable imide when sodium acetate is used as the catalyst. High catalyst concentrations provide maleimides with low isoimide impurity. The mechanism by which the chemical imidization is thought to occur is shown in Fig. 3. The first step in the dehydration reaction may be formation of the acetic acid-maleamic acid mixed anhydride. This species could lose acetic acid in one of the two ways. Path A involves participation by the neighboring amide carbonyl oxygen to eject acetate ion with simultaneous or subsequent loss of proton on nitrogen to form the isoimide. Path B involves loss of acetate ion assisted by the attack of nitrogen with simultaneous or subsequent loss of the proton on nitrogen to form the imide. If the cyclodehydration is run in acetic anhydride in the absence of the base catalyst, isoimide is the main reaction product. [Pg.172]

At high temperatures with low catalyst concentration the formation of acetanilides is favored. Maleic anhydride and acetanilides may be formed directly from the mixed anhydride by an initial attack of the nitrogen on the acetate carbonyl, but this process would involve a seven membered ring transition state. Another possible route to the formation of maleic anhydride and the acetanilides is participation by neighboring carbonyl in loosening the amide carbon-nitrogen bond to the extent that the amine can be captured by acetic anhydride as shown in path D. [Pg.172]

Preparation of acid chlorides is one of the easiest methods to activate an acid. Thionyl chloride (SOCh) [12, 13] is used widely to generate acid chlorides. The reaction of SOCb with water or other nucleophiles is extremely exothermic, and generates large quantities of sulfur dioxide and HCI. Nevertheless, acid chlorides (via SOCI2) and mixed anhydrides (via acid chlorides or chloroformates), are the most common reagents used for amide formation in the pharmaceutical industry, with N,N -carbonyldiiniidazole (CDl) growing in popularity[8]. [Pg.294]

Couplings with N-protected isoxazolidine-3-carboxylic acid can be performed without particular restrictions of the method, and the use of a mixed anhydride for acylation of amino acids or amide formation has been reported. 179 A similarly free choice of coupling methods is available for the acylation of isoxazolidine-3-carboxylic acid derivatives so far the use of carbodiimide and mixed anhydrides have been reported. 168179 Isoxazolidine-3-carboxylic acid derivatives are listed in Table 7. [Pg.74]

Less reactive than acyl halides, but still suitable for difficult couplings, are symmetric or mixed anhydrides (e.g. with pivalic or 2,6-dichlorobenzoic acid) and HOAt-derived active esters. HOBt esters smoothly acylate primary or secondary aliphatic amines, including amino acid esters or amides, without concomitant esterification of alcohols or phenols [34], HOBt esters are the most commonly used type of activated esters in automated solid-phase peptide synthesis. For reasons not yet fully understood, acylations with HOBt esters or halophenyl esters can be effectively catalyzed by HOBt and HOAt [3], and mixtures of BOP (in situ formation of HOBt esters) and HOBt are among the most efficient coupling agents for solid-phase peptide synthesis [2]. In acylations with activated amino acid derivatives, the addition of HOBt or HOAt also retards racemization [4,12,35]. [Pg.328]

The esterification of support-bound carboxylic acids has not been investigated as thoroughly as the esterification of support-bound alcohols. Resin-bound activated acid derivatives that are well suited to the preparation of esters include O-acylisoureas (formed from acids and carbodiimides), acyl halides [23,226-228], and mixed anhydrides (Table 13.15). A-Acylurea formation does not compete with esterifications as efficiently as it does with the formation of amides from support-bound acids. Esters can also be prepared from carboxylic acids on insoluble supports by acid-catalyzed esterification [152,229]. Alternatively, support-bound carboxylic acids can be esteri-fied by O-alkylation, either with primary or secondary aliphatic alcohols under Mitsu-nobu conditions or with reactive alkyl halides or sulfonates (Table 13.15). [Pg.353]

For the synthesis of the porphyrin the formate ester of 3j3-hydroxy-5-cholenic acid 179 was coupled via amide bonds to the a,/ ,a,j -atropisomer of meso-tetrakis(o-aminophenyl)-porphyrin 170, using the mixed anhydride... [Pg.81]

The reaction of metal N-alkylcarbamates M(C)2CN 11 R) (M = Na, Mn(II), Co(II) R = Ph, Pr, Cy) with R C(0)C1 (R = Me, Ph) takes place, at ambient temperature, in a more complex way with the formation of isocyanates (RNCO), carboxylic anhydrides (R C(0)0C(0)CR ), amides (RNHC(O)R ) and C02. Amide formation and the evolution of C02 can be due to (i) the decomposition of mixed anhydride RNHC(0)0C(0)R obtained by addition of the acyl chloride to the oxygen atom of the carbamate group or (ii) the direct reaction of acyl chloride at the carbamic nitrogen atom of M(02CNHR) . The mixed anhydride RNHC(O) 0C(0)R might also decompose via another route so as to afford isocyanate and carboxylic acid. However, a different pathway (Scheme 6.6) has been also envisaged for the formation of RNCO and R C(0)0C(0)CR, which excludes any intermediacy of the mixed anhydride [61a], Two acetic acid molecules, bound to the same metal or to different metal centers, would then be dehydrated and acetic... [Pg.131]

Amides. Amides can be prepared in one step from a carboxylic acid and an amine by reaction with 1 (1 equiv.) and triethylamine (2 equiv.) in CH2C12 at 25°. Presumably a mixed anhydride is first formed, which reacts subsequently with the amine. A variation involves conversion of the carboxylic acid into the carboxylic anhydride by reaction with 1 (0.5 equiv.) and triethylamine subsequent addition of the amine results in the formation of the amide. Yields are generally greater than... [Pg.213]

Reactions between a representative range of alkyl- and aryl-amines and of aliphatic and aromatic acids showed that the direct formation of amides from primary amines and carboxylic acids without catalyst occurs under relatively low-temperature conditions (Scheme 1). The best result obtained was a 60% yield of N-bcnzyl-4-phenylbutan-amide from benzylamine and 4-phenylbutanoic acid. For all these reactions, an anhydride intermediate was proposed. Boric and boronic acid-based catalysts improved the reaction, especially for the less reactive aromatic acids, and initial results indicated that bifunctional catalysts showed even greater potential. Again, anhydride intermediates were proposed, in these cases mixed anhydrides of carboxylic acids and arylboronic acids, e.g. (I).1... [Pg.54]

With these considerations in mind it was decided to investigate phosphinic-carboxylic mixed anhydrides in peptide methodology. .Mechanistic consideration of the reactants (2) and (3) and products shown above would suggest regiospecific nucleophilic attack by the amine component due to the formation of an amide bond with concomitant generation of a new P-0 bond.As in the study of phosophinamidates discussed above,a series of phosphinic acids were selected for preparation of the mixed anhydrides (2) because of the intimate steric and electronic... [Pg.200]

The reaction of phthalic anhydride with 1,3,4,6-tetra-0-acetyl-2-amino-2-deoxy-D-glucose leads to the formation of the expected A-phthaloyl amide or phthalamic acid. Furthermore, intramolecular condensation occurs, presumably by way of a mixed anhydride intermediate, on treating this with ethyl chloroformate, thereby forming an A,A-phthaloyl imide, 1,3,4,6-tetra-0-acetyl-2-deoxy-2-phthalimido-D-glucose.105 106 The 2-amino-2-deoxy-D-glucose derivative can be regenerated by the action of hydrazine.69 107... [Pg.235]

Fig. 6.21. In situ activation of a carboxylic acid—i.e., the side chain carboxyl group of protected L-aspartic acid—as the mixed anhydride (B) and its aminolysis to a Weinreb amide. How this Weinreb amide acylates an organolithium compound is shown in Figure 6.44. The acylation of an H nucleophile by a second Weinreb amide is presented in Figure 6.42 and the acylation of a di(ketone enolate) by a third Weinreb amide in Figure 13.64. Figure 6.50 also shows how Weinreb amides of carboxylic acids can be obtained by C,C bond formation. Fig. 6.21. In situ activation of a carboxylic acid—i.e., the side chain carboxyl group of protected L-aspartic acid—as the mixed anhydride (B) and its aminolysis to a Weinreb amide. How this Weinreb amide acylates an organolithium compound is shown in Figure 6.44. The acylation of an H nucleophile by a second Weinreb amide is presented in Figure 6.42 and the acylation of a di(ketone enolate) by a third Weinreb amide in Figure 13.64. Figure 6.50 also shows how Weinreb amides of carboxylic acids can be obtained by C,C bond formation.
Figure 7.4 illustrates the dehydration of primary amides A to nitriles B using trifluo-romethanesulfonic acid anhydride. All intermediates correspond to the ones discussed above. When the mixed anhydrides F finally release trifhioromethanesulfonic acid in two steps hy the already familiar El mechanism, the formation of the nitrile B is completed. [Pg.325]

Figure 6 Different types of mixed anhydrides used for amid bond formation. Figure 6 Different types of mixed anhydrides used for amid bond formation.
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See also in sourсe #XX -- [ Pg.600 ]



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Amides Anhydrides

Amides mixed

Anhydrides formation

Mixed anhydrides

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