Chiral columns chromatography

The success of chiral column chromatography depends on diastereoisomeric interactions between the chiral stationary phase and the enantiomers this leads to differential adsorption of enantiomers,... 

Method 1 represents the oldest technique for producing selectively one enantiomer, and readers should already be familiar with it.3 A chromatography column normally is an achiral environment elution of a racemate through the column should result in no separation into enantiomers. In Method 2, however, columns are modified by attaching chiral, enantioenriched groups to the solid support. Now a chiral environment does exist such that the two enantiomers exhibit diastereomerically different interactions with the column this is the basis for separation. Chiral column chromatography can sometimes resolve... 

The triethylsilyl ether 147 thus formed regiospecifically from the diol 150 [Rl=(BnO)2 (0), R2=Bn], which was optically resolved by a chiral column chromatography, was transformed to Ins(2,4,5)P3 and Ins(l,4,5)P3 (Schema 3-23). At this stage, temporary protection of OH-1 with the silyl group is not necessary, i.e. 150 can be directly phosphorylated by the phosphite-phosphonium approach as described in the section on phosphorylation (Scheme 2-6). H The diol 150 was used furthermore as a versatile synthetic intermediate for the synthesis of myo-inositol 1,2-cyclic-4,5-trisphosphate 152 (Scheme 3-23), 8 2-acyl analogues of Ins(1,4,5)P3, and inositol phospholipid. 

The tungstate method is successfully apphed to both 39a and 40a resulting in the generation of the same product, Nb-acetyl-1-hydroxy-L-tryptophan methyl ester ((S)-41), in 69 and 67% yields, respectively [21]. The application to the mixtiue of diastereomers (39a and 40a) without separation gives (S)-41 (69%) as reported previously [22]. Subsequent treatment of (S)-41 with excess ethereal CH2N2 yields Nb-acetyl-l-methoxy-L-tryptophan methyl ester ((S)-42,94%) [22]. Optical purity of (S)-42 is established to be more than 99% ee by its analysis using chiral column chromatography. 

Resolution (separation) of enantiomers can be accomplished in a number of ways, including the use of chiral resolving agents and chiral column chromatography. 

Optical resolution of the key intermediates, trans 41 and cis 4 2, was achieved, with base-line resolution, by chiral column chromatography on a chindpak AS column, to afford (-)-trans 41, (+)-inns 41, (-)-cis 42, and (+)-c 42 on a semi-preparative scale. The first total syntheses of (-)-6,7-secoagroclavine 47] and its (+>enantionier [(+)-/ranr 4 7] were completed in a one-pot operation by the reaction of (-)- and (+)-trans 41 with an excess of methylmagnesium iodide, respectively, followed by reduction of the resulting methylhydroxykunines [(-)- and (+)-tnms 49], with zinc in metiianolk hydrochloric acid. 

GC using chiral columns coated with derivatized cyclodextrin is the analytical technique most frequently employed for the determination of the enantiomeric ratio of volatile compounds. Food products, as well as flavours and fragrances, are usually very complex matrices, so direct GC analysis of the enantiomeric ratio of certain components is usually difficult. Often, the components of interest are present in trace amounts and problems of peak overlap may occur. The literature reports many examples of the use of multidimensional gas chromatography with a combination of a non-chiral pre-column and a chiral analytical column for this type of analysis. 

The enantioselective determination of 2,2, 3,3, 4,6 -hexachlorobiphenyl in milk was performed by Glausch et al. (21). These authors used an achiral column for an initial separation, followed by separation of the eluent fraction on a chiral column. Fat was separated from the milk by centrifugation, mixed with sodium sulfate, washed with petroleum ether and filtered. The solvent was evaporated and the sample was purified by gel permeation chromatography (GPC) and silica gel adsorption chromatography. Achiral GC was performed on DB-5 and OV-1701 columns, while the chiral GC was performed on immobilized Chirasil-Dex. 

A mixture of 1.4 g (10 mmol) of 4-chlorobenzaldehyde and 0.71 g (5 mol %) of the chiral polymer E is stirred in 10 mL of dry toluene for 15 h, under a dry nitrogen atmosphere, to form the Schiff base. After cooling to 0lC, 15 mL (15 mmol) of 1 M diethyl/inc in hexane is added and the mixture is stirred for a further 24 h at O C. 1 N HC1 is then added dropwise at O C, and the chiral polymer is removed by filtration. The polymer is washed several times with 11,0 and Et,0. The aqueous layer is separated and extracted with Et20. The combined organic layer is dried over MgS04 and concentrated under reduced pressure. The crude product is purified by column chromatography (silica gel, CHC1,) yield 1.61 g (95 %) 99 % ee [a]2,0 —23.9 (r = 4.93, benzene). 

Alkaline hydrolysis of the crude adduct formed with benzaldehyde, followed by treatment with diazomethane and column chromatography, affords methyl (2R,3S)-3-hydroxy-2-methyl-3-phenylpropanoate in 96% ee. Reduction of the crude products formed in the reactions with 2-inethylpropanal and 2,2-dimethylpropanal leads to the corresponding 1,3-diols with >96% ee. In both the hydrolysis and the reduction procedures, the chiral auxiliary reagent, 1,1,2-triphenyl-1,2-ethanediol, can be recovered and reused72. 

Based oil 11PLC analysis using a chiral column (Waters OptiPak TC). h Yield after purification by column chromatography. c Oxidative removal of the 2-isopropyl-4-methoxyphenyl moiety from 3 is unsuccessful. 

Racemic mixtures of sulfoxides have often been separated completely or partially into the enantiomers. Various resolution techniques have been used, but the most important method has been via diastereomeric salt formation. Recently, resolution via complex formation between sulfoxides and homochiral compounds has been demonstrated and will likely prove of increasing importance as a method of separating enantiomers. Preparative liquid chromatography on chiral columns may also prove increasingly important it already is very useful on an analytical scale for the determination of enantiomeric purity. 

All the y-sultines were obtained as diastereomeric mixtures (ca 1 1, by NMR), and each one of y-sultines ( + )-49 and ( + )-51 (R = t-Bu) was separated into two diastereomers A and B by column chromatography. The oxidation of y-sultines (— )-49A and (+ )-49B to the corresponding optically active sultones (+ )-52A,B, which lack a chiral sulfur, may be taken as proof that the observed optical activity in the sultines is also due to the y-carbon. This result seems to exclude the intermediacy of vinylsulfene in the reaction mechanism, since its disrotatory closure would lead to racemic y-carbon in the product. 

When the desired hydrogen uptake had been achieved, the vessel was opened, catalyst separated by filtration, and the reaction solution analysed by chiral gas chromatography (column Cydex B, 50 m, SGE Ltd). Analysis gave conversion and enantiomeric excess Enantiomeric excess is defined as IR - SI /(R+S). 

In order to achieve a true comparison between both catalytic systems, colloidal and molecular, which display very different reaction rates, a series of experiments were carried out with the homogeneous molecular system, decreasing the catalyst concentration in the studied allylic alkylation reaction. The reaction evolution is monitored taking samples at different reaction times and analysing each of them by NMR spectroscopy (to determine the conversion) and HPLC chromatography with chiral column (to determine the enantioselectivity of I and II). For molecular catalyst systems, the Pd/substrate ratio was varied between 1/100 and 1/10,000. For the latter ratio, the initial reaction rate was found comparable to that of the colloidal system (Figure 2a), but interestingly the conversion of the substrate is quasi complete after ca. 100 h in... 

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