Zwitterionic chiral stationary phases based on cinchona and chiral sulfonic acids for the direct stereoselective separation of amino acids and other amphoteric compounds

An extensive series of free amino acids and analogs were directly resolved into enantiomers (and stereoisomers where appropriate) by HPLC on zwitterionic chiral stationary phases (Chiralpak ZWIX(+) and Chiralpak ZWIX(?)). The interaction and chiral recognition mechanisms were based on the synergistic double ion‐paring process between the analyte and the chiral selectors. The chiral separation and elution order were found to be predictable for primary α‐amino acids with apolar aliphatic side chains. A systematic investigation was undertaken to gain an insight into the influence of the structural features on the enantiorecognition. The presence of polar and/or aromatic groups in the analyte structure is believed to tune the double ion‐paring equilibrium by the involvement of the secondary interaction forces such as hydrogen bonding, Van der Waals forces and π–π stacking in concert with steric parameters. The ZWIX chiral columns were able to separate enantiomers and stereoisomers of various amphoteric compounds with no need for precolumn derivatization. Column switching between ZWIX(+) and ZWIX(?) is believed to be an instrumental tool to reverse or control the enantiomers elution order, due to the complementarity of the applied chiral selectors.     

Distinguishing Enantiomers by Tip‐Enhanced Raman Scattering: Chemically Modified Silver Tip with an Asymmetric Atomic Arrangement

Discrimination between enantiomers is achieved by tip‐enhanced Raman scattering (TERS) using a silver tip that is chemically modified by an achiral para‐mercaptopyridine (pMPY) probe molecule. Differences in the relative intensities of the pMPY spectra were monitored for three pairs of enantiomers containing hydroxy (?OH) and/or amino (?NH₂) groups. The N: or N⁺?H functionality of the pMPY‐modified tip participates in hydrogen‐bond interactions with a particular molecular orientation of each chiral isomer. The asymmetric arrangement of silver atoms at the apex of the tip induces an asymmetric electric field, which causes the tip to become a chiral center. Differences in the charge‐transfer (CT) states of the metal‐achiral probe system in conjunction with the asymmetric electric field produce different enhancements in the Raman signals of the two enantiomers. The near‐field effect of the asymmetric electric field, which depends on the number of analyte functional groups capable of hydrogen‐bond formation, improves the degree of discrimination.     

The factors that influence the elution order for the resolution of amino acids on vancomycin phase using the polar-organic mobile phases after their pre-column derivatization with electrophilic reagents

A variety of amino acids were enantioresolved on a vancomycin bonded chiral phase using the polar-organic mobile phases after their pre-column derivatization with electrophilic reagents in alkaline medium. The resolution was highly dependent on the analyte's structure and was enhanced as the aromatic side-chain group on the skeleton of analyte for pi-pi interaction with the chiral selector became available. The steric hindrance resulting from the bulky side-chain group on the analyte also affected the resolution. Elution reversal, not found on the teicoplanin phase under the same chromatographic conditions, was possible through altering the type of reagent used in the derivatizing reaction (e.g. 2,4-difluorophenylisothiocyanate to 2,4-difluorophenylisocyanate). It is believed that the steric hindrance, as a result of the bulky sulfur atom in reagents such as methylisothiocyanate and others examined in this study, was responsible for the reversed elution order. The bulkiness of the substituent on the aromatic ring of derivatizing reagents (i.e. 2,3- and 3,5-dichlorophenylisothiocyanate) was observed to affect the resolution and alter the elution order as well.     

Chiral Separation of Organic Phosphonate Compounds on Polysaccharide-Based Chiral Stationary Phases

Four polysaccharide-based chiral stationary phases have been used to separate the enantiomers of fourteen O,O-dialkyl-1-benzyloxycarbonyl-aminoarylmethyl phosphonates. These polysaccharide-based chiral stationary phases are Chiralpak AD, Chiralpak AS, Chiralcel OG and Chiralcel OJ. The data obtained indicate that the chiral separation ability for these organophosphonate compounds are in the order Chiralpak AD > Chiralcel OG > Chiralcel OJ > Chiralpak AS. With Chiralpak AD, all of the studied compounds could be easily baseline separated. Those two polysaccharides possess different chiral discrimination mechanism due to of the difference of the conformational structures of amylose and cellulose. The chiral discrimination of derivatized amylose chiral stationary phases were based on the stereogenic fit of the analytes in the helical structures of amylose and the transient diastereomeric complex formation between the analyte and the amylose CSP through π–π interaction H-bond interactions and induced dipole interactions exerted by the substituents on the analyte molecules. The chiral discrimination, in case of derivatized cellulose chiral stationary phase is based on the stereogenic fit of the analytes in the grooves of cellulose followed by interactions mentioned above between the analytes and the cellulose CSP.     

Fluorescence quenching study of humic‐fraction‐modified silica gel in a solid state after association with a variety of pesticidal analytes in hexane and acetonitrile

In this paper, we investigate the fluorescence quenching of acidic humic‐fraction‐modified silica gel in the solid state after association with a variety of pesticidal analytes in hexane and acetonitrile. The percentage of fluorescence quenching is found to be dependent on the contact time and linearly on the number of moles of analyte involved in the association process. However, any π–π complexation interaction arising from the acidic aromatic ring on the analyte due to the derivatization of a bulky electron‐withdrawing group is not observed. Also, any mechanism leading to adsorption or any quenching process occurring as a result of the steric hindrance obtained by a theoretical interaction simulation is not observed. The Fourier transform infrared (FTIR) data and simulation results, instead, suggest that electron‐rich atoms on the analyte, such as oxygen, sulfur, nitrogen, and phosphorus, are responsible for fluorescence quenching, following dipole–dipole interaction with the humic‐fraction‐modified adsorbent.     

Distinguishing Enantiomers by Tip-Enhanced Raman Scattering: Chemically Modified Silver Tip with an Asymmetric Atomic Arrangement

Discrimination between enantiomers is achieved by tip-enhanced Raman scattering (TERS) using a silver tip that is chemically modified by an achiral para-mercaptopyridine (pMPY) probe molecule. Differences in the relative intensities of the pMPY spectra were monitored for three pairs of enantiomers containing hydroxy (−OH) and/or amino (−NH₂) groups. The N: or N⁺−H functionality of the pMPY-modified tip participates in hydrogen-bond interactions with a particular molecular orientation of each chiral isomer. The asymmetric arrangement of silver atoms at the apex of the tip induces an asymmetric electric field, which causes the tip to become a chiral center. Differences in the charge-transfer (CT) states of the metal-achiral probe system in conjunction with the asymmetric electric field produce different enhancements in the Raman signals of the two enantiomers. The near-field effect of the asymmetric electric field, which depends on the number of analyte functional groups capable of hydrogen-bond formation, improves the degree of discrimination.     

Stereoselective analysis of D and L dansyl amino acids as the mixed chelate copper(II) complexes by HPLC

This paper reviews the mixed chelation approach to resolution of the optical isomers of D and L dansyl amino acids by high performance liquid chromatography. The use of eluants containing Cu(II) complexes of L-proline, L-arginine, L-histidine, and L-histidine methyl ester effected the separation of many D and L amino acids, including those with aliphatic, polar, and aromatic substituents. The mechanism of separation, which is based on the preferential ternary complex formation of the analyte amino acid and the chiral chelate with Cu(II) in the mobile phase, is discussed. The stereoselectivity depends mainly on the different steric interactions between the alkyl side chains of the amino acid analytes and the chiral ligands coordinating around Cu(II), although such parameters as pH, temperature, organic modifier, and concentration of the chiral additive also affect the chromatographic separation. Among the chiral ligands studied, L-histidine methyl ester is unique in that it possesses both achiral selectivity for the dansyl amino acids and chiral selectivity for the respective D and L enantiomers. With a mobile phase gradient of acetonitrile in a buffer containing Cu(II) L-histidine methyl ester complex, a stereoselective procedure was devised for the analysis of D and L amino acid enantiomers, achieving the separation that the current amino acid analyzer could not perform. Finally, the use of the mixed chelation approach in two biomedical studies is described. In the first application, the histidine methyl ester gradient was adapted for analyzing amino acids in cerebrospinal fluid; in the second, an L-aspartame Cu(II) complex eluant was developed for measuring the urine concentration of D and L pipecolic acid (piperidine-2-carboxylic acid), a metabolite of lysine.     

Application of sulfobutylether-beta-cyclodextrin with specific degrees of substitution for the enantioseparation of pharmaceutical mixtures by capillary electrophoresis.

In this research the separation of the enantiomers of the basic drug bidisomide (SC-40230) from five closely related known process impurities was investigated using several neutral and anionic sulfobutylether beta-cyclodextrins (SBE-beta-CDs) as isomer selectors. Several novel sulfobutylether derivative mixtures and purified charge types having a specific degree of substitution were used to study the effect of selector charge on the efficiency and selectivity of both chiral and achiral separations. The effects of run buffer pH, selector type, and selector concentration on the chiral separation of bidisomide and the achiral separation of the related process impurities was also investigated. The related process impurity, SC-47500, displayed significant peak tailing with SBE-beta-CD mixtures which contained mono- to deca-substituted cyclodextrins. This problem was explored using isolated SBE-beta-CD charge types having degrees of substitution from one to seven. Peak tailing increased as the charge on the selector increased, suggesting that the distortion was due to electrodispersion and the large countercurrent mobility of the negatively charged complexes. Pure charge types having a lower degree of substitution provided adequate chiral and achiral selectivity, while eliminating the severe peak distortion caused by electrodispersion. The complete analysis of the bidisomide enantiomers and the related impurities was achieved with a pH 2.5 running buffer containing 5-10 mM of the isolated sulfobutylether charge types SBE[2]ds(1)sr-beta-CD or SBE[3]ds(1)sr-beta-CD. These conditions gave baseline resolution of bidisomide enantiomers and all five impurities, thus allowing both chiral and achiral purity to be determined in a single run.     

Chiral recognition in the solid state: crystallographically characterized diastereomeric co-crystals between a synthetic chiral selector (Whelk-O1) and a representative chiral analyte

Designed to distinguish between the enantiomers of compounds possessing commonly occurring structural features, the chiral selector used in the chiral stationary phase (CSP) 1 (Whelk-O1) is broadly applicable. In an effort to further the understanding of the mechanism of chiral recognition with this chiral selector, both diastereomeric combinations of selector 1 and a representative analyte, the pivalamide of p-bromo-α-phenylethylamine, 2, were successfully co-crystallized and characterized by single crystal X-ray diffraction. The crystal corresponding to the complex that is more stable in solution is consistent with our previously reported chiral recognition model. The aromatic portion of 2 is in the cleft of selector 1, displaying both face-to-face and face-to-edge π–π interactions as well as a hydrogen bond between the benzamide proton of the selector and the carbonyl oxygen of the analyte. For the crystal corresponding to the complex, which is less stable in solution, the aromatic portion of 2 is not in the cleft of selector 1, having approached from the opposite face of the π-acidic dinitrobenzamide moiety so as to undergo face-to-face π–π and hydrogen bonding interactions. Comparisons of these structures and their relevance to enantioselective chromatography are also discussed.     

Apparent and true enantioselectivity of single- and binary-selector chiral stationary phases in gas chromatography

Almost all gas-chromatographic chiral stationary phases (CSPs) are complex systems containing one or more chiral selector(s) dissolved in, or bonded to, an achiral solvent such as squalane or poly(dimethylsiloxane). The presence of different components in the total CSP, interacting independently with the analyte enantiomers, impairs the elucidation of enantiorecognition mechanisms and complicates the optimization of enantioseparations. In the present work a quantitative analysis of the influence of different factors on the observed enantioselectivity is performed. The parameters varied in this study were the composition of the CSP, the concentration and the enantiomeric excess of the chiral selector(s) and the presence of achiral selectors (including racemic compositions). Special attention is given to the determination of distribution and association constants, as well as apparent and true enantioseparation factors.     

Use of NMR binding interaction mapping techniques to examine interactions of chiral molecules with molecular micelles

NMR spectroscopy was used to investigate the association of four chiral molecules with the molecular micelle poly(sodium N-undecanoyl-l-leucylvalinate) (poly(SULV)). Adding poly(SULV) to the background electrolyte in electrokinetic chromatography (EKC) allows enantiomeric resolution to be achieved because enantiomers interact differentially with the chiral centers on the micelle headgroups as they both move in the electric field. Pulsed field gradient diffusion experiments were used to measure molecular micelle association constants for enantiomers of each analyte. These association constants were consistent with EKC elution order for the compounds 1,1'-binaphthyl-2,2'-diyl hydrogen phosphate (BNP), 1,1'-bi-2-naphthol (BOH), and Troger's base. In addition, nuclear Overhauser enhancement spectroscopy, nuclear Overhauser effect difference, and intermolecular cross relaxation diffusion experiments were used to generate binding interaction maps for each chiral analyte. These maps showed that BNP and BOH inserted into the surfactant headgroup's major chiral groove and interacted predominately with the leucine chiral center. (+)-Troger's base was also found to insert into the major chiral groove. However, this compound instead interacted with the valine chiral atom. In diffusion experiments with long diffusion times, the linearized diffusion plots for each analyte-molecular micelle mixture showed curvature characteristic of intermolecular cross relaxation. The magnitude of this effect scaled linearly with the analytes' free energies of binding.     

Resolution of the enantiomers of oxamniquine by capillary electrophoresis and high-performance liquid chromatography with cyclodextrins and heparin as chiral selectors

The methods of separation of the enantiomers of the chiral drug oxamniquine are compared, between HPLC with either cyclodextrins and their related derivatives as chiral selectors in the mobile phase or immobilisedin a chiral stationary phase (as Cyclobond I and II) and between capillary zone electrophoresis (CZE) where the cyclodextrins are added to the buffer solution. The HPLC experiments, which included structured method optimisation were largely unsuccessful in resolving the enantiomers, with the exception of when a Chiral-AGP protein stationary phase was introduced into the programme. However although this chiral stationary phase provided baseline resolution of the enantiomers the stability of the method was suspect to small changes in the pH (0.2 units). In contrast the CZE method developed for both cyclodextrins and their derivatives gave good resolution of the enantiomers and method stability (R.S.D. <1%, N = 10 on precision). The basis of the interaction mechanism between selector and selectand was shown as a 1:2 relationship of cyclodextrin to analyte by NMR. In addition the polysaccharide, heparin was investigated as a chiral additive and excellent resolution of the oxaminiquine was achieved with 3 mM heparin in 50 mM sodium dihydrogenphosphate (pH 3.0) as buffer in CZE, which also gave a stable procedure. This method allowed the detection of each of the enantiomers in the presence of the other down to 0.23% (m/m). The overall composition of the heparin material from different sources can however be slightly variable and this can result in small differences in resolution capability.     

Green high‐performance liquid chromatography enantioseparation of lansoprazole using a cellulose‐based chiral stationary phase under ethanol/water mode

A simple and environmentally friendly reversed‐phase high‐performance liquid chromatography method for the separation of the enantiomers of lansoprazole has been developed. The chromatographic resolution was carried out on the cellulose‐based Chiralpak IC‐3 chiral stationary phase using a green and low‐toxicity ethanol‐aqueous mode. The effects of water content in the mobile phase and column temperature on the retention of the enantiomers of lansoprazole and its chiral and achiral related substances have been carefully investigated. A mixed‐mode hydrophilic interaction liquid chromatography and reversed‐phase retention mechanism operating on the IC‐3 chiral stationary phase allowed us to achieve simultaneous enantioselective and chemoselective separations in water‐rich conditions. The enantiomers of lansoprazole were baseline resolved with a mobile phase consisting of ethanol/water 50:50 without any interference coming from chiral and achiral impurities within 10 min.     

Chiral analysis by mass spectrometry using the kinetic method in flow systems

Chiral analysis is an important task of analytical chemistry. Besides separation techniques, mass spectrometry can be applied in this field. One mass spectrometric approach is based on Cooks' kinetic method. The method was successfully applied in a static system in which the concentration of the analyte as well as the chiral selector solution was constant during the experiment. The application of the kinetic method in dynamic systems (changing concentration of analyte) is presented. Such systems allow the speeding up of the analytical process (flow injection analysis (FIA)) or the use of the kinetic method for chiral detection after liquid chromatographic separation.The influence of the concentration of the components of the chiral selector solution as well as its flow rate on the recognition of enantiomers was evaluated. A new procedure for correction for the differences between ratio of enantiomers in the liquid phase and their observed ratio in the gas phase is also described. A significant improvement in accuracy using this procedure was achieved. Applicability of the method was demonstrated in the analysis of amino acids using FIA as well as HPLC/MS. After an achiral separation of leucine and isoleucine, chiral mass spectrometric detection was successfully used for enantiomeric recognition.     

Synthetic macrocyclic receptors in chiral analysis and separation

Chiral synthetic macrocyclic receptors that can achieve chiral discrimination by NMR spectroscopy and/or chiral separation by HPLC are overviewed. Synthetic macrocycles introduced here include crown ethers, calixarenes/calixresorcinarenes/calixpyrroles, macrocyclic amides/amines, and porphyrins. These macrocyclic frameworks are advantageous because intermolecular interactions can take place effectively, such as the ion–dipole interactions in crown ethers, the CH/π and π–π interactions in calixarenes, hydrogen bonding and salt formation in macrocyclic amides and amines, and π–π stacking and metal coordination in porphyrins. Additional functional groups on the periphery of the macrocyclic platforms not only make the whole molecule chiral but also act as the interaction sites. Chiral macrocyclic receptors can show a high degree of chiral recognition/discrimination by using the peripheral functional groups as well as the macrocyclic skeletons (preorganization). Both hosts and guests are shown in the figures to quickly overview the molecular recognition scope of synthetic macrocyclic receptors in chiral analysis and separation.     

Evaluation and Comparison of a 3,5‐Dimethylphenyl Isocyanate Teicoplanin with Phenyl Isocyanate Teicoplanin Chiral Stationary Phase Using RP‐HPLC

HPLC enantiomeric separations of 8 α‐amino acids were achieved using two self‐made chiral stationary phases (CSP)–phenyl isocyanate teicoplanin (Phe‐TE) and 3,5‐dimethylphenyl isocyanate teicoplanin (DMP‐TE), using reversed phase mobile phases. The Phe‐TE or the DMP‐TE CSP was prepared from the TE using derivative agents, phenyl isocyanate or 3,5‐dimethylphenyl isocyanate, respectively. The chromatographic results were given as the retention, selectivity, resolution factor and the enantioselective free energy difference corresponding to the separation of the two enantiomers. The effect of pH, organic modifier type and amount were discussed, and the stereoselectivities for two TE‐based CSPs were compared. The chiral selectivity factor for six α‐amino acids on DMP‐TE is somewhat bigger than that on Phe‐TE CSP under reversed phase (RP) mode. Comparison of the enantiomeric separations using self‐made Phe‐TE and DMP‐TE was conducted to gain a better understanding of the chiral recognition mechanism of the macrocyclic glycopeptide CSP.     

Chiral separation of anionic and neutral compounds using a hepta-substituted cationic beta-cyclodextrin as a chiral selector in capillary electrophoresis

Enantiomeric separations of six anionic and two neutral racemates were achieved using a fully substituted heptakis(6-hydroxyethylamino-6-deoxy)-beta-cyclodextrin (beta-CD-EA) as a chiral selector. As beta-CD-EA provides a dynamic coating on the capillary wall, reverse-polarity capillary electrophoresis (CE) configuration is applied for separations of anionic and neutral chiral compounds. Chiral separations of various classes of anionic and neutral enantiomers were found to be highly dependent on pH because the degree of protonation of beta-CD-EA can alter the shape of the CD cavity by charge repulsion, altering complexation, aiding selectivity, and leading to better enantiomeric separation. In general, the chiral resolution of anionic enantiomers was enhanced at higher pH. This suggests that carboxylate or phosphate groups on the analyte may interact with the protonated amine groups of cationic CD. The successful enantioseparation was achieved in a pH range of 6.6-7.8 for all six anionic analytes, in the presence of 10 mM beta-CD-EA.     

The HPLC Enantioresolution of Phenyl Isocyanated Amino Acids, Peptides and Amino Alcohols on Cyclodextrin Bonded Phases Using the Acetonitrile-Based Mobile Phase

A variety of amino acids (primary and secondary), peptides and amino alcohols are pre-column phenyl isocyanated in alkaline medium and enantioresolved on the naphthylethylcarbamated β-cyclodextrin (i.e., RN- and SN-β-CD) bonded chiral phases (CSPs) using the acetonitrile-based mobile phase and on a native β-cyclodextrin (β-CD) phase for comparison. The resolution is believed to be a result of the hydrogen bonding between the secondary hydroxyl groups of cyclodextrin and the functional groups of analyte and is enhanced as the amino and the carboxyl groups are attached to the stereogenic center of analyte. Also, the enhancement is observed if the steric hindrance between the side-chain group of amino acid and the chiral selector exists. However, the resolution is deteriorated in the case that the side-chain group close to the stereogenic center of amino acid becomes bulky or is capable of forming hydrogen bonding with chiral selector. The aromatic moiety of the tagging reagent not only contributes the retention, but also benefits the resolution in some cases on the RN- and SN-β-CD phases through π-π interaction. The resolution is either not observed or unsatisfactory in the reversed-phase mode.     

应用四甲基氢氧化铵控制电渗流的毛细管电泳方法分离多沙唑嗪及其中间体的对映体

建立了毛细管电泳手性分离多沙唑嗪中间体对映体的方法,并同时分离了多沙唑嗪对映体。考察了不同种类季铵盐对电渗流及分离的影响,其中四甲基氢氧化铵(TMB)能有效控制电渗流并提高组分的分离度。实验还考察了其他因素,如pH值、分离电压和磷酸二氢钠浓度对分离的影响。所用的毛细管为40 cm(有效长度30 cm)×50 μm,缓冲液为12 mmol/L β-环糊精、30 mmol/L TMB、60 mmol/L 磷酸二氢钠(pH 2.2),分离电压为20 kV。在此条件下多沙唑嗪及其中间体的对映体均达到了基线分离。实验结果表明,一些用β-环糊精不能完全分离的对映体通过加入TMB控制电渗流能达到满意的分离效果。