Enantioseparation cyclodextrins

Enantiomeric resolution of solutes that fit within the molecular cavity, which is chiral, results in the formation of an inclusion complex (Ref. 169 and Fig. 4). In general, the enantiomers are separated on the basis of formation constants of the host-guest complexes. The enantiomer that forms the more stable complex has a greater migration time because of this effect. The chiral recognition mechanism for cyclodextrin enantioseparation has been discussed in several works (163-168). 

Inspired by the separation ability of cyclic selectors such as cyclodextrins and crown ethers, Malouk s group studied the synthesis of chiral cyclophanes and their intercalation by cation exchange into a lamellar solid acid, a-zirconium phosphate aiming at the preparation of separation media based on solid inorganic-organic conjugates for simple single-plate batch enantioseparations [77-80]. 

In a different approach, Stalcup and co-workers [25] used sulfated (3-cyclodextrin for the enantioseparation of piperoxan in work directly derived from earlier CE and classical gel results. Their results were obtained using a continuous free flow apparatus developed by R S Technologies, Inc. Processing rates on the order of 4.5 mg h were reported. 

Barretta and coworkers63 reported a direct determination of the enantiomeric purity of chiral trisubstituted allenes by using permethylated cyclodextrin as a chiral solvating agent. They found that the heptakis ft-cyclodextrin TRIMEB discussed above can be successfully used as a chiral solvating agent (CSA) for the NMR determination of the enantiomeric purity of trisubstituted allenes llOa-f. An accurate analysis of the experimental conditions (molar ratio aliene/TRIMEB, temperature and solvent) required to optimize the enantioseparation has been carried out. The XH NMR spectra of TRIMEB, allenes llOa-f, and the mixtures TRIMEB/allene have been recorded at 300 MHz in CD3OD as solvent. 

Enantioseparation of nine amphetamine derivatives, methorphan, and propoxyphene was studied by comparing two different CSP typologies, a macrocyclic antibiotic CSP (vancomycin) and a native P-cyclodextrin CSP [123]. The suitability of the eluent systems to ESI interfacing was discussed, and a tandem mass spectrometric (MS/MS) detection method was developed. 

Berkecz, R. et al., LC enantioseparation of -lactam and P-amino acid stereoisomers and a comparison of macrocyclic glycopeptide and P-cyclodextrin-based columns, Chromatographia, 63, S37, 2006. 

Tesafova, E. and Bosikova, Z., Comparison of enantioseparation of selected benzodiazepine and phenothiazine derivatives on chiral stationary phases based on P-cyclodextrin and macrocyclic antibiotics, J. Sep. ScL, 26, 661, 2003. 

Wamke, M.M. et al.. Use of native and derivatized cyclodextrin based and macrocychc glycopeptide based chiral stationary phases for the enantioseparation of pterocarpans by HPLC, J. Liq. Chrom. Rel. TechnoL, 28, 823, 2005. 

Cherkaoui, S., and Veuthey, J. L. (2001). Use of negatively charged cyclodextrins for the simultaneous enantioseparation of selected anesthetic drugs by capillary electrophoresis-mass spectrometry. /. Pharm. Biomed. Anal. TJ, 615 — 626. 

L Ma, J Han, H Wang, J Gu, R Fu. Capillary electrophoresis enantioseparation of drugs using (3-cyclodextrin polymer Intramolecular synergistic effect. Electrophoresis 20 1900-1903, 1999. 

AM Rizzi, L Kremser. pKa shift-associated effects in enantioseparations by cyclodextrin-mediated capillary zone electrophoresis. Electrophoresis 20 2715-2722, 1999. 

Cyclodextrins have significantly contributed to the development of enantioseparations in CE, where they represent the most widely used chiral selectors. On the other hand, due to its inherently high separation efficiency and diverse technical advantages, CE has contributed enormously to the better understanding of affinity interactions between CDs and chiral analytes. The following text summarizes the recent developments in this field (3-60). 

Capillary electrophoresis has been applied for the enantioselective determination of the binding constants of chiral drugs with cyclodextrins for basically the following two reasons (1) optimization of chiral selector concentration and (2) understanding the fine mechanisms of enantioseparations in CE. The first group of studies have been published mainly on the early stage of chiral CE development, whereas the second goal is followed in the most recent studies, mainly by Rizzi and Kremser (10,13) and Scriba et al. 

B Chankvetadze, M Fillet, N Burjanadze, D Bergenthal, C Bergander, H Luft-mann, J Crommen, G Blaschke. Enantioseparation of aminoglutethimide with cyclodextrins in capillary electrophoresis and studies of selector-selectand interactions using NMR spectroscopy and electrospray ionization mass spectrometry. Enantiomer 5 313-322, 2000. 

A Amini, U Paulsen-Sorman. Enantioseparation of local anaesthetic drugs by capillary zone electrophoresis with cyclodextrins as chiral selectors using a partial-filling technique. Electrophoresis 18 1019-1025, 1997. 

Motoyama et al. [182] applied on-line SPE for the enantioseparation of pindolol in urine and sernm. The samples were injected into the system after filtration through a membrane filter. A cation exchanger with a mobile phase of 100 mM NH4AC (pH 5.0) AcN (90 10) was connected to a phenylcarbamate-P-cyclodextrin colnmn. A mobile phase of AcN H20 (50 50) with lOmM NH4AC... 

Yashima, E., Yamada, M., Yamamoto, C., Nakashima, M., and Okamoto, Y. (1997) Chromatographic enantioseparation and chiral discrimination in NMR by trisphenylcarbamate derivatives of cellulose, amylose, oligosaccharides, and cyclodextrins, Enantiomer 2, 225-240. 

Enantioseparation of dihydropyridine derivatives could be accomplished using capillary electrophoresis by means of neutral and negatively charged (3-cyclodextrin derivatives [40]. The method used a fused silica capillary (47 cm x 75 pm 40 cm to detector), operated at 25°C. The running phase was 50 mM phosphate buffer (pH 3) containing cyclodextrins and organic modifiers, and an applied voltage of 6-20 kV was applied. Detection was effected at 190-300 nm. 

The first electrically driven enantioseparations involved the addition of a chiral selector to the mobile phase in CE. This selector is usually a complexing agent and acts as a pseudo-stationary phase. The separation is accomplished by the difference in the distibution equilibria between the pseudo-stationary phase and the enantiomers [134], The most common additives incorporated into these CE experiments were cyclodextrins and cyclodextrin derivatives [135-138], However, these experiments required the replacement of the chiral selector after each electrophoretic run. 

Synergistic effects in terms of efficiency of CE enantioseparation have been observed when a second (not necessarily chiral) selector is added in the same buffer system. It has been demonstrated that a combination of 18-crown-6 and )-cyclodextrin can achieve or enhance enantioselective separations of nonpolar amines, which are rarely observed with cyclodextrins alone <1997JCH(781)129, 1997JCH(695)157>. The formation of a ternary sandwich complex (dual complex) is postulated to be responsible for such a beneficial effect. 

Chromatographic enantioseparation of chiral xenobiotics and their metabolites is a versatile tool for process studies in marine and terrestrial ecosystems [235]. In 1994, three papers focused on the enantioselective determination of toxaphene components [120,236,237]. Buser and Muller found that technical toxaphene mixtures are not necessarily racemic [237]. This observation was supported after isolation of non-racemic B7-1453 from the product Melipax which had an excess of ca. 25% of the dextrorotary enantiomer [27, 238]. The enantioselective separation of toxaphene components is almost restricted to chiral stationary phases (CSPs) based on randomly derivatized ferf-butyldimethyl-silylated /1-cyclodextrin (commercially available from BGB Analytik, Adliswil, Switzerland). So far, only a few toxaphene components were enantioseparated on other CSPs [239, 240]. Some of these CSPs are not well defined as well, and for this reason a test mixture called CHIROTEST X was suggested for initial column testing [241],... 

The efficiency of chiral stationary phase (CSP) is crucial in chromatographic technique. Recently, a new p-cyclodextrin phenyl isocyanate bonded chiral stationary phase (CSP) was developed. This CSP is quite stable and can be used in most of HPLC solvents. Many drug enantiomers that do not have enantioseparation effect on native P-cyclodextrin column in reversed phase were separated very well on this new CSP. 

Zukowski J., Pawlowska M., Nagatkina M. Armstrong D. W., High-performance Liquid Chromatographic Enantioseparation of Glycyl dipeptides and tripeptides on Native Cyclodextrin Phases, Mechanistic Considerations, Journal of Chromatograpf. 629(1993), 169-179. 

ENANTIOSEPARATION OF PHARMACEUTICALLY RELEVANT CHIRAL COMPOUNDS USING CYCLODEXTRIN, MACROCYCLIC ANTIBIOTIC. AND CROWN-ETHER TYPE CSPs... 

Enantioseparations in SEC have been reported for several CSPs. including native and derivatized cyclodextrin-based CSPs [427-432. Pirkle-concept CSPs [77,336-338,347,348,363,365,433,434], polysaccharide type CSPs [137.435-438], macrocyclic antibiotic type CSPs [436], and others. 

Conceptually. CE enantioseparations are mainly applied to charged SAs. Micellar electrokinetic chromatography (MEKC) (introduced by Terabe et al. in 1984 488 ), in contrast, permits the separation of electrically neutral compounds. In enantiomer separation by MEKC. ionic pseudo-stationary phases, such as chiral micelles composed of chiral SO moieties, which migrate according to their electrophoretic mobility, may interact stereoselectively with the solutes to be separated. MEKC with synthetic (e.g. A-dodecoxycarbonylvalines, commercialized as SDVal by Waters) 1489.490) or naturally occurring chiral surfactants (e.g. bile salts) 1491-494). and cyclodextrin-moditied MEKC (most often SDS/CD combinations) 1495-498) are the mo.st widely used selector systems in MEKC. The topic of MEKC enantioseparation has been reviewed by Nishi )499). 

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. 

The pH, temperature, and ionic strength of the mobile phase also affect the cyclodextrin-solute complexation and retention properties. Many enantioseparations using cyclodextrin-modified systems involve solutes with an aromatic ring substituent or similar cyclic structure at the chiral center. A variety of chiral barbiturates, hydantoins, and related compounds have been resolved by using (3-cyclodextrin and alkylated B-cyclodextrin-modified systems. 

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