Chiral derivatizing agent

Nuclear magnetic resonance ( H and C) chiral shift reagent chiral derivatizing agent chiral solvating agent. 

Siret L, Bargrmann N, Tambute A, Caude M (1992) Direct enantiomeric separation of P-blockers on ChyRoSine-A by supercritical fluid chromatography supercritical carbon dioxide as transient in situ derivatizing agent. Chirality 4 252-262... 

Most of the reactions applied to amines can also be transferred to alcohols (Eig. 7-5). One large group of chiral alcohols are the (i-adrenoreceptor blockers, for which a variety of derivatization agents was developed. One highly versatile reagent for the separation of (i-blockers is A-[(2-isothiocyanato)cyclohexyl]3,5-dinitrobenzoyl-amide (DDITC) [11]. Alternatively, unichiral drugs such as (3-blockers or (S)-naproxen [12] may be used in a reciprocal approach to derivatize racemic amine compounds. 

Derivatization of the optically active aldehydes to imines has been used for determination of their enantiomeric excess. Chi et al.3 have examined a series of chiral primary amines as a derivatizing agent in determination of the enantiomeric purity of the a-substituted 8-keto-aldehydes obtained from catalysed Michael additions. The imine proton signals were well resolved even if the reaction was not completed. The best results were obtained when chiral amines with —OMe or —COOMe groups were used [2], The differences in chemical shifts of diastereo-meric imine proton were ca. 0.02-0.08 ppm depending on amine. This method has been also used for identification of isomers of self-aldol condensation of hydrocinnamaldehyde. 

In determination of the absolute configuration of a-chiral primary amines, BINOL derivatives were used as chiral derivatizing agent.10 In this procedure, the chiral substrate was derivatized with R and S enantiomers of the 2,-methoxy-l,l -binaphthalene-8-carbaldehyde and the XH spectra of both diastereomers were compared. Comparison of the chemical shift differences of the diastereomers has allowed determination of the absolute configuration of the chiral substrate [5]. 

A variety of methods are also available when the compound under investigation can be converted with a chiral reagent to diastereomeric products, which have readily detectable differences in physical properties. If a derivatizing agent is employed, it must be ensured that the reaction with the subject molecule is quantitative and that the derivatization reaction is carried out to completion. This will ensure that unintentional kinetic resolution does not occur before the analysis. The derivatizing agent itself must be enantiomerically pure, and epi-merization should not occur during the entire process of analysis. 

Various chiral derivatizing agents have been reported for the determination of enantiomer compositions. One example is determining the enantiomeric purity of alcohols using 31P NMR.28 As shown in Scheme 1-8, reagent 20 can be readily prepared and conveniently stored in tetrahydrofuran (THF) for long periods. This compound shows excellent activity toward primary, secondary, and tertiary alcohols. To evaluate the utility of compound 20 for determining enantiomer composition, some racemic alcohols were chosen and allowed to react with 20. The diastereomeric pairs of derivative 21 exhibit clear differences in their 31P NMR spectra, and the enantiomer composition of a compound can then be easily measured (Scheme 1-8). 

Scheme 1-9. Chiral derivatizing agents used in 31P NMR analysis.

The use of diazaphospholidines as chiral derivatizing agents for the determination of the enantiomeric composition of choro- or bromohydrins has been reported. Thus, 31P NMR spectra of a range of diastereomeric derivatives have been described to show a systematic deshielding from 0.2 to 12.9 ppm of isomers 48 compared to isomers 49 <2000TA1273>. 

Heptafluorobutyryl chloride, chiral derivatizing agent, 6 96t Heptafluoroisobutenyl methyl ether,... 

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