Diastereomeric system

The most numerous group of asymmetric syntheses includes reactions of chiral sulfur compounds leading to diastereomeric systems as a result of the generation of a new chiral center and the preserva-... 

In this section, diastereomeric crystallization is presented as a driving force -or internal selection pressure - to resolve dynamic diastereomeric systems. The dynamic diastereomeric systems are generated from reversible covalent bond formation, leading to compounds carrying chiral carbon centers under thermodynamic control. The dynamic systems can represent more variety of the possible diastereomer adducts. The selective diastereomers, A —B, , are subsequently chosen from the dynamic system by self-transformation and/or self-preferential crystallization. When the selective product C , is formed, the ratio of its corresponding diastereomer adducts A -Bm in the dynamic system will be decreased. The equilibrium in the dynamic system will force the reproduction of the intermediate until the resolution has reached completion. In the end, only one diastereomeric product Cnm is selectively crystallized and easily purified from the solution. 

An achiral reagent cannot distinguish between these two faces. In a complex with a chiral reagent, however, the two (phantom ligand) electron pairs are in different (enantiotopic) environments. The two complexes are therefore diastereomeric and are formed and react at different rates. Two reaction systems that have been used successfully for enantioselective formation of sulfoxides are illustrated below. In the first example, the Ti(0-i-Pr)4-f-BuOOH-diethyl tartrate reagent is chiral by virtue of the presence of the chiral tartrate ester in the reactive complex. With simple aryl methyl sulfides, up to 90% enantiomeric purity of the product is obtained. 

Although there is usually a preference for anti elimination in acyclic systems, syn elimination is competitive in some cases. In acyclic systems, the extent of anti versus syn elimination can be determined by use of stereospecifically deuterated substrates or by use of diastereomeric reactants which will give different products by syn and anti elimination. The latter approach showed that elimination from 3-phenyl-2-butyl tosylate is a stereospecific anti process. ... 

The occurrence of syn elimination in 5-decyl systems has been demonstrated with the use of diastereomeric deuterium-labeled substrates. Stereospecifically labeled 5-substituted decane derivatives were prepared and subjected to appropriate elimination conditions. By comparison of the amount of deuterium in the E and Z isomers of the product, it was... 

The mixture of free amino acids is reacted with OPA (Fig. 7-8) and a thiol compound. When an achiral thiol compound is used, a racemic isoindole derivative results. These derivatives from different amino acids can be used to enhance the sensitivity of fluorescence detection. Figure 7-9 shows the separation of 15 amino acids after derivatization with OPA and mercaptothiol the racemic amino acids may be separated on a reversed-phase column. If the thiol compound is unichiral, the amino acid enantiomers may be separated as the resultant diastereomeric isoindole compound in the same system. Figure 7-10 shows the separation of the same set of amino acids after derivatization with the unichiral thiol compound Wisobutyryl-L-cysteine (IBLC). 

According to the modified Maquenne system (18,19,31) used in this chapter, the diastereomeric configuration of any cyclitol is expressed by a fraction, and position-numbering, if otherwise equivocal, is so assigned that the numerator will have the lowest possible numbers. For example, proto-quercitol (12 or 13) is designated (134/25,), not (14/ 235) or (25/134). 

An expedient and stereoselective synthesis of bicyclic ketone 30 exemplifies the utility and elegance of Corey s new catalytic system (see Scheme 8). Reaction of the (R)-tryptophan-derived oxazaboro-lidine 42 (5 mol %), 5-(benzyloxymethyl)-l,3-cyclopentadiene 26, and 2-bromoacrolein (43) at -78 °C in methylene chloride gives, after eight hours, diastereomeric adducts 44 in a yield of 83 % (95 5 exo.endo diastereoselectivity 96 4 enantioselectivity for the exo isomer). After reaction, the /V-tosyltryptophan can be recovered for reuse. The basic premise is that oxazaborolidine 42 induces the Diels-Alder reaction between intermediates 26 and 43 to proceed through a transition state geometry that maximizes attractive donor-acceptor interactions. Coordination of the dienophile at the face of boron that is cis to the 3-indolylmethyl substituent is thus favored.19d f Treatment of the 95 5 mixture of exo/endo diastereo-mers with 5 mol % aqueous AgNC>3 selectively converts the minor, but more reactive, endo aldehyde diastereomer into water-soluble... 

The addition of the anions of racemic 1-(diphenyl)- and l-(diethoxyphosphinyl)-2-butenes to 2-cyclopentenone or 2-cyclohexenone gives y-l,4-add ucls. () A1 ly 1 systems give exclusively. vy/t-adducts while (Z)-allyl systems give exclusively //-adducts. 2-Cycloheptenone gives diastereomeric mixtures of 1,4-adducts and 1,2-addition products1. 

Consecutive Michael additions and alkylations can also be used for the diastereoselective synthesis of 5- and 6-membered ring systems. For instance when 6-iodo-2-hexenoates or 7-iodo-2-heptenoates are employed the enolate of the Michael adduct is stereoselectively quenched in situ to provide the cyclic compound with trans stereochemistry (>94 6 diastereomeric ratio). As the enolate geometry of the Michael donor can be controlled, high stereoselectivity can also be reached towards either the syn or anti configuration at the exocyclic... 

To examine if the higher catalytic activity and selectivity of 47a as compared to the COP-X system 46 is mainly caused by the pentaphenyl ferrocenium or by the imidazoline moiety, oxazoline 53-Cl was prepared in diastereomerically pure form starting from carboxylic acid 51 and (5)-valinol via oxazoline 52 (Fig. 27) [73]. 

If HMPA is included in the solvent, the Z-enolate predominates.236,238 DMPU also favors the Z-enolate. The switch to the Z-enolate with HMPA or DMPU is attributed to a looser, perhaps acyclic TS being favored as the result of strong solvation of the lithium ion. The steric factors favoring the -TS are therefore diminished.239 These general principles of solvent control of enolate stereochemistry are applicable to other systems.240 For example, by changing the conditions for silyl ketene acetal formation, the diastereomeric compounds 17a and 17b can be converted to the same product with high diastereoselectivity.241... 

Torsional effects are important in cyclic systems. A PM3 study of the high stereoselectivity of compounds 4a-d found torsional effects to be the major difference between the diastereomeric TSs.81 The computed TSs for 4a are shown in Figure 12.10. The structures all show similar stereoselectivity, regardless of the presence and nature of a 3-substituent. 

Our approach for chiral resolution is quite systematic. Instead of randomly screening different chiral acids with racemic 7, optically pure N-pMB 19 was prepared from 2, provided to us from Medicinal Chemistry. With 19, several salts with both enantiomers of chiral acids were prepared for evaluation of their crystallinity and solubility in various solvent systems. This is a more systematic way to discover an efficient classical resolution. First, a (+)-camphorsulfonic acid salt of 19 crystallized from EtOAc. One month later, a diastereomeric (-)-camphorsulfonic acid salt of 19 also crystallized. After several investigations on the two diastereomeric crystalline salts, it was determined that racemic 7 could be resolved nicely with (+)-camphorsulfonic acid from n-BuOAc kinetically. In practice, by heating racemic 7 with 1.3equiv (+)-camphorsulfonic acid in n-BuOAc under reflux for 30 min then slowly cooling to room temperature, a cmde diastereomeric mixture of the salt (59% ee) was obtained as a first crop. The first crop was recrystallized from n-BuOAc providing 95% ee salt 20 in 43% isolated yield. (The optical purity was further improved to -100% ee by additional recrystallization from n-BuOAc and the overall crystallization yield was 41%). This chiral resolution method was more efficient and economical than the original bis-camphanyl amide method. 

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