Column packings chiral

An hplc assay was developed suitable for the analysis of enantiomers of ketoprofen (KT), a 2-arylpropionic acid nonsteroidal antiinflammatory dmg (NSAID), in plasma and urine (59). Following the addition of racemic fenprofen as internal standard (IS), plasma containing the KT enantiomers and IS was extracted by Hquid-Hquid extraction at an acidic pH. After evaporation of the organic layer, the dmg and IS were reconstituted in the mobile phase and injected onto the hplc column. The enantiomers were separated at ambient temperature on a commercially available 250 x 4.6 mm amylose carbamate-packed chiral column (chiral AD) with hexane—isopropyl alcohol—trifluoroacetic acid (80 19.9 0.1) as the mobile phase pumped at 1.0 mL/min. The enantiomers of KT were quantified by uv detection with the wavelength set at 254 nm. The assay allows direct quantitation of KT enantiomers in clinical studies in human plasma and urine after adrninistration of therapeutic doses. 

A number of specialised stationary phases have been developed for the separation of chiral compounds. They are known as chiral stationary phases (CSPs) and consist of chiral molecules, usually bonded to microparticulate silica. The mechanism by which such CSPs discriminate between enantiomers (their chiral recognition, or enantioselectivity) is a matter of some debate, but it is known that a number of competing interactions can be involved. Columns packed with CSPs have recently become available commercially. They are some three to five times more expensive than conventional hplc columns, and some types can be used only with a restricted range of mobile phases. Some examples of CSPs are given below ... 

A chiral GC column is able to separate enantiomers of epoxy pheromones in the Type II class, but the applications are very limited as follows a custom-made column packed with a p-cyclodextrin derivative as a liquid phase for the stereochemical identification of natural 3,4- and 6,7-epoxydienes [73, 74] and a commercialized column of an a-cyclodextrin type (Chiraldex A-PH) for the 3,4-epoxydiene [71] (See Table 3). The resolution abilities of chiral HPLC columns have been examined in detail, as shown in Table 7 and Fig. 14 [75,76, 179]. The Chiralpak AD column operated under a normal-phase condition separates well two enantiomers of 9,10-epoxydienes, 6,7-epoxymonoenes and 9,10-epoxymonoenes. Another normal-phase column, the Chiralpak AS column, is suitable for the resolution of the 3,4-epoxydienes. The Chiralcel OJ-R column operated under a reversed-phase condition sufficiently accomplishes enantiomeric separation of the 6,7-epoxydienes and 6,7-epoxymonoenes. 

The chiral recognition ability of the insoluble (+)-l was estimated by HPLC using a column packed with small particles of l.25 However, this column showed a poor efficiency because of a low theoretical plate number. This defect was overcome by coating soluble poly(TrMA) with a DP of 50 on macroporous silica gel.26 The 1-coated silica gel had higher resistance against compression and longer lifetime than the CSP of insoluble 1. Moreover, the two 1-based CSPs show quite different chiral recognition for several race-mates, which may be attributed to the different orientation of 1 in bulk and on the surface of the silica gel.27... 

Thermodynamic behaviors and retention mechanisms for SFC are unique. Low temperatures and high pressures or high densities usually favor fast separation of enantiomers in SFC. In the case that the isoelution temperature is below the working temperature, the selectivity increases as temperature increases and higher temperatures are favorable for chiral separation. Future development in SFC will likely include new chiral column technologies and instrumentation refinement. A greater variety of chiral columns packed with smaller particles will open up more areas of application for fast chiral separations. In addition, improvement in signal-to-noise ratio of... 

In 1973, Stewart and Doherty [9] resolved enantiomers of tryptophan on a column packed with BSA-succinoylaminoethyl-agarose in a discontinuous elution procedure. The mobile phase used was 0.1 M borate buffer (pH 9.2). The chromatograms of this classical research are shown in Figure 2. Several years later, this technique was applied for the chiral resolution of warfarin enantiomers [10]. In 1981, the enantiomers of tryptophan and warfarin racemates were resolved on various serum albumin CSPs [11,21,22]. The same method was used for the resolution of other drugs [12-14]. Allenmark et al. [23] studied the resolution of a series of active racemic sulfoxides on a BSA column using 0.08 M phosphate buffer (pH 5.8) as the eluting solvent. 

Separation of enantiomers of etodolac using two different derivitization agents and three chiral stationary phases has been studied [24]. Etodolac was converted to its anilide derivative with either 1,3-dicyclohexyl-carbodiimide or l-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride. Etodolac, derivatizing agent, aniline, and dichloromethane were allowed to incubate for 30 minutes, which was followed by addition of 1 M HC1. The organic layer was removed, washed, dried, and then injected into normal phase or reverse phase HPLC. The HPLC system consisted of a 250 x 4.6 mm (5 pm particle size) column packed with chiral stationary phases, and detection was effected by the UV absorbances at 254 and 280 nm. Separation of etodolac enantiomers was achieved on only one of the stationary phases when using 20% 2-propanol in hexane as the mobile phase at a flow rate of 2.0 mL/min. 

A simple, isocratic chromatographic method for the separation, identification, and measurement of etodolac enantiomers without derivitization using chiral stationary phase columns has been reported [25]. A chiral stationary phase column packed with Chiracel OD (cellulose tris-3,5-dimethylphenylcarbamate coated on 10 pm silica gel) was used as the stationary phase. The mobile phase (85 15 v/v, n-hexane/2-propanol (containing 0.1% trifluoroacetic acid)) was pumped at 0.7 mL/min and the UV detection was set at 230 nm. The (-)-(/ )-etodolac enantiomer eluted first, indicating its stronger interaction between the stationary phase relative to the (+)-(S)-etodolac enantiomer. 

Silica-base stationary phases have also been employed for enantiomeric separations in CEC [6,72-81]. In the initial work on chiral CEC, commercially available HPLC materials were utilized, including cyclodextrins [6,74,81] and protein-type selectors [73,75,80] such as human serum albumin [75] and ai-acid glycoprotein [73]. Fig. 4.9, for example, depicts the structure of a cyclodextrin-base stationary phase used in CEC and the separation of mephobarbital enantiomers by capillary LC and CEC in a capillary column packed with such a phase. The column operated in the CEC mode affords higher separation efficiency than in the capillary LC mode. Other enantiomeric selectors are also use in CEC, including the silica-linked or silica-coated macrocyclic antibiotics vancomycin [82,83] and teicoplanin [84], cyclodextrin-base polymer coated silicas [72,78], and weak anion-exchage type chiral phases [85]. Relatively high separation efficiency and excellent resolution for a variety of compounds have also been achieved using columns packed with naproxen-derived and Whelk-0 chiral stationary phases linked to 3 pm silica particles [79]. Fig. 4.10 shows the... 

Fig. 4.10. (A) The chiral stationary phases (S)-naproxen-derived and (3R,4S)-Whelk 0 1. (B) CEC enantiomeric separation of an antidepressant (N-[l-(4-bromo-phenyl)-ethyl]-2,2-dimethyl-propionamide) on a column packed with (3R,4S)-Whelk-0 1 chiral phase immobilized on 3 pm silica. Adapted from ref. [79] with permission. Copyright Elsevier 1997.

Enantiomers can be separated in an analogous manner after reaction with 2-phenyl-propionyl chloride [40], Brooks et al. [41] used drimanoyl and chrysanthemoyl chlorides as chiral reagents for series of enantiomeric alcohols. The alcohol (1 mg) in dry toluene (20 pi) was treated with 10 pi of a solution of freshly prepared drimanoyl chloride (3 molar excess) in dry toluene and the mixture was heated at 60°C for 1 —2 h. The injection was performed without using any other purification. Good separation of enantiomers of chrysanthemoyl esters, which are prepared in an analogous manner, was achieved on a 5-m column packed with 1% of SE-30 on Gas-Chrom Q (100-120 mesh) at 143°C. 

Chromatographic resolution of enantiomers. The enantiomers of the racemic compound form diastereomeric complexes with the chiral material on the column packing. One of the enantiomers binds more tightly than the other, so it moves more slowly through the column. 

Packed capillary columns with chirally selective stationary phases (e.g., flr acid glycoprotein), as well as wall-immobilized, CD-based stationary phases, have been successfully used in CE chromatographic separations. Also, macro-cylic crown ethers, forming sterically selective complexes with the guest molecule, have been used for the resolution of optically active amines. 

The synthetic ( )-calanolide A was resolved into its enantiomers, (+)-calanolide A (1) and ( )-calanolide A, by using a semipreparative chiral HPLC column packed with amylose carbamate eluting with hexane/ethnol (95 5). The ultraviolet detection was set at a wavelength of 254 nm. (+)-calanolide A and its enantiomer (—)-calanohde A were collected, and their chemical structures were identified based on their optical rotations and spectroscopic data, as compared with the corresponding natural and synthesis compounds. 

Another approach is electrochromatography with capillary columns packed with an achiral stationary phase, preferentially a reversed-phase type material. The chiral SO is added to the background electrolyte, and may be adsorbed onto the stationary phase by a secondary equilibration process. Enantioseparations in this additive mode have been reported with cyclodextrin type SOs )504-507) and with a chiral ion-pair agent derived from quinine 1508) as mobile phase additives. 

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