Amides, enantiomeric

Adsorption surface, SFC, solvent Interactions, 1>>9 Air monitors. Industrial chromatography, 200 Alditol acetates, chromatogram, 32f Alkyl groups, bonded, HPLC development, 82,83 Amides, enantiomeric, separation, >l3,>l>lf Amine compounds, RPLC, 8>l Amino acids HPLC, 86,87f Ion exchange, 81 ligand exchange, >>... 

The kinetic resolution of racemic amino acid amides is performed with permeabilized whole cells of P. putida ATCC 12633 with a nearly 100% stereoselectivity for hydrolysis of the L-amide (enantiomeric ratio E > 200 [20]). Thus, both the L-acid and the D-amide can be obtained in nearly 100% e.e. at 50% conversion. The biocatalyst accepts a broad structural variety of amino acid amides, from alanine amide to, for example, p-naphthyl-glycine amide or lupinic acid amide (Scheme 4). So far more than 100 different amino acid amides have been successfully resolved. 

Macaudiere et al. first reported the enantiomeric separation of racemic phosphine oxides and amides on native cyclodextrin-based CSPs under subcritical conditions [53]. The separations obtained were indicative of inclusion complexation. When the CO,-methanol eluent used in SFC was replaced with hexane-ethanol in LC, reduced selectivity was observed. The authors proposed that the smaller size of the CO, molecule made it less likely than hexane to compete with the analyte for the cyclodextrin cavity. 

The best results were obtained with amides of (S)- or (/ )-3-methoxy-l-phenyl-2-propylamine, which gave, with linear aliphatic aldehydes, products with enantiomeric excesses greater than 75% using titanium(IV) chloride as the Lewis acid. A transition state involving coordination of the titanium by the carbonyl oxygens of both the amide and the aldehyde was proposed95. 

Asano et al. have developed an approach for the synthesis of D-amino acids through DKR using a two-enzyme system [55]. They had previously reported the discovery of new D-stereospecific hydrolases that can be applied to KR of racemic amino acid amides to yield D-amino acids. Combination of a D-stereospedfic hydrolase with an amino acid amide racemase allows performing DKR of i-amino acid amides yielding enantiomerically pure D-amino acids in excellent yields (Figure 4.29). 

The resolution of racemic ethyl 2-chloropropionate with aliphatic and aromatic amines using Candida cylindracea lipase (CCL) [28] was one of the first examples that showed the possibilities of this kind of processes for the resolution of racemic esters or the preparation of chiral amides in benign conditions. Normally, in these enzymatic aminolysis reactions the enzyme is selective toward the (S)-isomer of the ester. Recently, the resolution ofthis ester has been carried out through a dynamic kinetic resolution (DKR) via aminolysis catalyzed by encapsulated CCL in the presence of triphenylphosphonium chloride immobilized on Merrifield resin (Scheme 7.13). This process has allowed the preparation of (S)-amides with high isolated yields and good enantiomeric excesses [29]. 

The strategy described here explains the different possibilities of enzymatic ammonolysis and aminolysis reaction for resolution of esters or preparation of enantiomerically pure amides, which are important synthons in organic chemistry. This methodology has been also applied for the synthesis of pyrrolidinol derivatives that can be prepared via enzymatic ammonolysis of a polyfunctional ester, such as ethyl ( )-4-chloro-3-hydroxybutanoate [30]. In addition, it is possible in the resolution of chiral axe instead of a stereogenic carbon atom. An interesting enzymatic aminolysis of this class of reaction has been recently reported by Aoyagi et al. [31[. The side chain of binaphthyl moiety plays an important role in the enantiodis-crimination of the process (Scheme 7.14). 

For this reaction, CALB catalyzes the amidation between a racemic P-hydroxyester and racemic amines, leading to the corresponding amide with very high enantiomeric and diastereomeric excesses. Besides, the remaining ester and amine are recovered from the reaction media, also showing good enantiomeric excesses. By this method, three enantioenriched interesting compounds are obtained from an easy one-step reaction. 

Preparation of optically active P-aminoesters, P-aminonitriles, and P-aminocarbox-amides are of special relevance for the synthesis of enantiomerically pure P-aminoacids compounds of special relevance in several areas of medicinal chemistry. The resolution of P-aminoesters can be carried out by acylation of the amino groups or by other biocatalytic reactions of the ester groups, such as hydrolysis, transesterification, or aminolysis. The resolution of ethyl ( )-3-aminobutyrate... 

In the special case of the prochiral carboxylic acids (36), dehydrohalogenation with an optically active lithium amide gave an optically active product with enantiomeric excesses as high as 82%. 

Chiral phosphinous amides have been found to act as catalysts in enantio-selective allylic alkylation. Horoi has reported that the palladium-catalyzed reaction of ( )-l,3-diphenyl-2-propenyl acetate with the sodium enolate of dimethyl malonate in the presence of [PdCl(7i-allyl)]2 and the chiral ligands 45 gave 46 in 51-94% yields and up to 97% ee (Scheme 38). It is notorious that when the reaction is carried out with the chiral phosphinous amide (S)-45a, the product is also of (S) configuration, whereas by using (R)-45b the enantiomeric (R) product is obtained [165]. 

The highly ordered cyclic TS of the D-A reaction permits design of diastereo-or enantioselective reactions. (See Section 2.4 of Part A to review the principles of diastereoselectivity and enantioselectivity.) One way to achieve this is to install a chiral auxiliary.80 The cycloaddition proceeds to give two diastereomeric products that can be separated and purified. Because of the lower temperature required and the greater stereoselectivity observed in Lewis acid-catalyzed reactions, the best diastereoselectivity is observed in catalyzed reactions. Several chiral auxiliaries that are capable of high levels of diastereoselectivity have been developed. Chiral esters and amides of acrylic acid are particularly useful because the auxiliary can be recovered by hydrolysis of the purified adduct to give the enantiomerically pure carboxylic acid. Early examples involved acryloyl esters of chiral alcohols, including lactates and mandelates. Esters of the lactone of 2,4-dihydroxy-3,3-dimethylbutanoic acid (pantolactone) have also proven useful. 

The synthesis in Scheme 13.37 also used a me,ro-3,4-dimethylglutaric acid as the starting material. Both the resolved aldehyde employed in Scheme 13.36 and a resolved half-amide were successfully used as intermediates. The configuration at C(2) and C(3) was controlled by addition of a butenylborane to an aldehyde (see Section 9.1.5). The boronate was used in enantiomerically pure form so that stereoselectivity was enhanced by double stereodifferentiation. The allylic additions carried out by the butenylboronates do not appear to have been quite as highly stereoselective as the aldol condensations used in Scheme 13.37, since a minor diastereoisomer was formed in the boronate addition reactions. 

Based on gasliquidchromatography (GLPC) amides, formed from various enantiomeric amines and the chiral-derivatizing reagent ( S)-(—)-JV-pentafluorobenzoylprolyl-l-imidazole, could be detected at nanogram levels [43],[44]... 

The chlorides 73a and 73b on reacting with dimethylamine in benzene afforded the amidates 92 and 93 respectively with complete diastereoselectivity. [58] The diastero-meric amides 94-96 were prepared in a similar manner by reacting 73a with chiral primary amines (optically active or racemic) and the isolated amides were applied for quantification of enantiomeric excesses of the amines of interest (Scheme 27) [55], A similar reaction with 1,2-diaminoethane gave bisphosphoramide 98 [59],... 

Mori later developed a shorter synthesis of these pheromones by employing a Weinreb amide A (Scheme 31) as the common intermediate [54]. The products 18-20, however, were less enantiomerically pure than those previously synthesized from the epoxy alcohol A of Schemes 29 and 30. 

A related enantiomerically pure zinc amide initiator, (340), has also been described.966 This complex catalyzes the alternating copolymerization of CHO and C02 to yield isotactic material (RR SS = 86 14). Similar enantiomeric excesses have been achieved using a mixture of Et2Zn and the chiral amino alcohol (341).967 Molecular weight distributions are much broader than using catalyst (340), but this protocol is still a convenient way to prepare optically pure diols (Scheme 23). 

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