Epimers, preparation

Convergent Synthesis of Racemic LTA4 and Double-Bond Isomers Convergent Synthesis of Chiral LTA4 and Its 5,6-Epoxy Epimers Preparation of LTA4 Synthons... 

Epimerization at C(5) has not been observed under the conditions discussed for the preparation of C(6) epimers (see Section 5.11.3.8.4). It is possible to prepare 5 -epipenicillins, however, as shown in Scheme 28. Note particularly the successful removal of the phthaloyl group (step iii) in this sequence, a procedure which leads to /3-lactam cleavage when C(5) is the R, or natural, configuration. Silylation of (35) followed by DBN treatment afforded (36), which corresponds to epimerization at C(3), and (37), which corresponds to epimerization at C(3) and C(6). No product corresponding to only C(6) epimerization was observed (76JOC2561). 

During the course of these mechanistic studies a wide range of possible applications of this reaction have been revealed. When the reduction is carried out with lithium aluminum deuteride and the anion complex decomposed with water, a monodeuterio compound (95) is obtained in which 70% of the deuterium is in the 3a-position. Reduction with lithium aluminum hydride followed by hydrolysis with deuterium oxide yields mainly (70 %) the 3j5-di-epimer (96), while for the preparation of dideuterio compounds (94) both steps have to be carried out with deuterated reagents. ... 

The treatment of ketoximes with lithium aluminum hydride is usually a facile method for the conversion of ketones into primary amines, although in certain cases secondary amine side products are also obtained. Application of this reaction to steroidal ketoximes, by using lithium aluminum deuteride and anhydrous ether as solvent, leads to epimeric mixtures of monodeuterated primary amines the ratio of the epimers depends on the position of the oxime function. An illustrative example is the preparation of the 3(x-dj- and 3j5-di-aminoandrostane epimers (113 and 114, R = H) in isotopic purities equal to that of the reagent. 

During the course of a mass spectrometric study of D-homo-14-hydroxy steroids, it was necessary to prepare the corresponding C-8 deuterium labeled analogs. The preparation of these uncommon steroid derivatives has been achieved by repeating the Torgov total synthesis [(257) (262)] with a deuterium-labeled bicyclic starting material (258). Both of the resulting 14-hydroxy epimers, (261) and (262), exhibited better than 90% isotopic purity. ... 

Oxidation of the sodium enolate of 15b, prepared by using NaHMDS, with ( )-2-phenylsulfonyl-3-phenyloxaziridine yielded the desired 7-hydroxy derivative 23 (R = H) and its C(7) epimer with a very low... 

Cholest-3-ene has been prepared previously by deamination of 5/3-cholestan-3 -yl amine,by reduction of a mixture of 4 -bromo-5 -cholestan-3a-ol and its epimer with zinc in acetic acid, and as component of a mixture of cholestenes by Wolff-Kishner reduction of cholest-4-en-3-one. ... 

Although these Boc derivatives underwent methylation with poor selectivity (compared to 3-amino-N-benzoyl butanoates [106] and Z-protected methyl 4-phen-yl-3-aminobutanoate [107]), epimers were succesfully separated by preparative HPLC or by flash chromatography. However, saponification of the methyl ester caused partial epimerization of the a-stereocenter and a two-step (epimerization free) procedure involving titanate-mediated transesterification to the corresponding benzyl esters and hydrogenation was used instead to recover the required Boc-y9 -amino acids in enantiomerically pure form [104, 105]. N-Boc-protected amino acids 19 and 20 for incorporation into water-soluble /9-peptides were pre-... 

Similarly, the oxazoHdine (it,S)-147, obtained as a mixture of epimers at C2 from N,N-dibenzyl (it)-phenylalaninal and hl-benzyl (S)-valinol, reacted with Grignard reagents to form in situ the iminium ion 148, from which the diamino alcohols 149 were produced as a single diastereomer [71 ] (Scheme 23). On the other hand, when the oxazoHdine derived from the (S)-aldehyde was used, the diamino alcohol was obtained as a 70 30 mixture of diastereomers. Alhough the preparation of the primary 1,2-diamines was not explored in that paper, compoimds 149 would be the precursors of the syn 1,2-diamine... 

On the other hand, following the same sequences from the differently protected serine-derived nitrone 168, through the formation of hydroxylamines 169, C2 epimers of carboxylic acid and aldehydes are obtained, i.e., (2S,3R)-170 and (2S,3R)-171. Moreover, the syn adducts 164 were exclusively obtained in the addition of Grignard reagents to the nitrone 163, whereas the same reactions on nitrone 168 occurred with a partial loss of diastereoselectivity [80]. Q, j6-Diamino acids (2R,3S)- and (2R,3R)-167 can also be prepared from the a-amino hydroxylamines 164 and 169 by reduction, deprotection and oxidation steps. The diastereoselective addition of acetylide anion to N,N-dibenzyl L-serine phenyhmine has been also described [81]. 

At>-7-Oxabicyclo[2.2.l]hept-5-ene-2-carboxylic acid - (84) was isolated as a minor component from the mother liquor of 29. Compound 84 is an epimer of 29 at C-2, and three known carba-sugar pentaacetates have been prepared from 84 as follows. 

Deoxy-5-epi-5-fluorosisomicin (695) was prepared by mutasynthesis using 2,5-dideoxy-5-epi-5-fluorostreptamine (693). Compound 695 and 5-deoxy-5-fluorosisomicin (696) were respectively synthesized from protected derivatives 697 and its 5-epimer by treatment with DAST. These compounds (695 and 696) showed antibacterial activity similar to that of sisomi-... 

GTX3 can be ruled out because, due to the conditions of sample preparation, it would have been accompanied by its epimer, GTX2 (3). The blocking kinetics of GTX2 are sufficiently different from those observed that it would have been easily detected if present. 

High performance liquid chromatography (HPLC) has been by far the most important method for separating chlorophylls. Open column chromatography and thin layer chromatography are still used for clean-up procedures to isolate and separate carotenoids and other lipids from chlorophylls and for preparative applications, but both are losing importance for analytical purposes due to their low resolution and have been replaced by more effective techniques like solid phase, supercritical fluid extraction and counter current chromatography. The whole analysis should be as brief as possible, since each additional step is a potential source of epimers and allomers. 

Arenesulfinate esters are usually prepared from an arenesulfinyl chloride and an alcohol in ether and pyridine. The arenesulfinyl chloride is usually prepared from the sodium arenesulfinate which is made by reduction of the arenesulfonyl chloride, preferably by aqueous sodium sulfite. After the crystalline sulfinate epimer has been removed by filtration, the equilibrium between the epimers remaining in the mother liquor may be reestablished by the addition of hydrogen chloride as shown by Herbrandson and Cusano . In this way the yield of the least soluble diastereomer may be increased beyond that which exists in the original reaction mixture (Scheme 1). Solladie prepared sulfinate ester 19 in 90% yield using this technique and published the details of his procedure. Estep and Tavares also published a convenient recipe for this method, although their yields were somewhat lower than Solladie s. 

As an alternative, Harpp and coworkers reacted benzenesulfinyl chloride with the trimethylsilyl derivative of menthol to form the diastereomeric esters in 91% yield the epimer of configuration R could be isolated by crystallization in unspecified yield. Grossert and coworkers prepared ester 19 in 51% yield as a mixture of diastereomers by treating p-toluenesulfonyl chloride with sodium p-toluenesulfinate in DMF containing menthol. It was postulated that initial nucleophilic attack by the sulfinate oxygen on the sulfonyl sulfur atom gave the mixed sulfonate-sulfinate anhydride 21, which then reacted... 

Although menthyl esters, especially 19, are most often used to prepare sulfoxides, esters derived from optically active alcohols other than menthol have been prepared . Ridley and Smal prepared arenesulfmic esters of 1,2 5,6-di-O-cyclohexylidene-a-D-glucofuranose. Unfortunately, these diastereomers were oils, except for the mesityl derivative, with the major epimer having configuration R at sulfur and so they offered no advantage over the menthyl esters. Separation of the epimers by chromatography failed. 

A major problem with the sulfoxide synthesis using menthyl sulfmates is its failure to produce optically pure dialkyl sulfoxides. The prerequisite menthyl alkanesulfinates are oils which have resisted separation into the individual epimers. The menthyl phenyl methanesulfmates are an exception the R epimer is crystalline . One solution to this problem, at least for preparing methyl alkyl sulfoxides, was achieved using cholesteryl methanesulfmates (27) . Both epimers were crystalline and could be separated by fractional crystallization, although in poor yield. Treatment of the epimers with n-propyl, n-butyl, isobutyl, p-tolyl and benzyl magnesium halides yielded the respective methyl alkyl sulfoxides (28) in greater than 95% e.e. and in 32 to 53% yields. 

The A-D-ring analog 30a,b (mixture of epimers) has been prepared from the epoxide 3a,b by base catalyzed epoxide cleavage, hydroxymethylenation, and O-alkylation of the butenolide unit using standard conditions. Hydroxymethylenation of keto-ester 7 followed by butenolide addition provided the A-D-ring analog 31. 

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