Enantiodiscrimination by a quinine-based chiral stationary phase: a computational study

A detailed computational study of a derivatized quinine chiral stationary phase (CSP) interacting with enantiomeric 3, 5-dinitrobenzoyl derivatives of leucine was carried out to understand where and how chiral discrimination takes place. The most stable structure of the CSP derived from a conformer search gave a structure whose geometry agrees with an X-ray structure (rmsd 0.6 A). The computed retention order and enantiodiscriminating free energy differences also agree with chromatographic data. The location and characteristics of the analyte binding site were assessed. An evaluation of total energies and intermolecular energies responsible for complex formation and for chiral discrimination was performed. Molecular dynamics trajectories of those intermolecular forces as well as distributions of the stabilizing and destabilizing forces are presented. A partitioning of the CSP into molecular fragments and the role each fragment plays in complexation and chiral recognition is also described.     

Separating enantiomers by HPLC on silica dynamically coated with a chiral stationary phase of permethylated β-cyclodextrin

The paper demonstrates that the technique of solvent generated liquid--solid chromatography can be used to create normal phase systems for chiral separations. The chiral adsorption layer was generated by pumping a binary hexane:ethanol eluent containing a small fraction of permethylated β-cyclodextrin through a column packed with microparticulate silica. This technique leads to columns with good time stability and reproducibility. The possibility of generating normal phase systems with permethylated β-cyclodextrin as chiral component via the mobile phase broadens the range of phase system which can be used to separate enantiomers by HPLC.     

Novel chiral stationary phases based on 3,5-dimethyl phenylcarbamoylated β-cyclodextrin combining cinchona alkaloid moiety

Novel chiral selectors based on 3,5-dimethyl phenylcarbamoylated β-cyclodextrin connecting quinine (QN) or quinidine (QD) moiety were synthesized and immobilized on silica gel. Their chromatographic performances were investigated by comparing to the 3,5-dimethyl phenylcarbamoylated β-cyclodextrin (β-CD) chiral stationary phase (CSP) and 9-O-(tert-butylcarbamoyl)-QN-based CSP (QN-AX). Fmoc-protected amino acids, chiral drug cloprostenol (which has been successfully employed in veterinary medicine), and neutral chiral analytes were evaluated on CSPs, and the results showed that the novel CSPs characterized as both enantioseparation capabilities of CD-based CSP and QN/QD-based CSPs have broader application range than β-CD-based CSP or QN/QD-based CSPs. It was found that QN/QD moieties play a dominant role in the overall enantioseparation process of Fmoc-amino acids accompanied by the synergistic effect of β-CD moiety, which lead to the different enantioseparation of β-CD-QN-based CSP and β-CD-QD-based CSP. Furthermore, new CSPs retain extraordinary enantioseparation of cyclodextrin-based CSP for some neutral analytes on normal phase and even exhibit better enantioseparation than the corresponding β-CD-based CSP for certain samples.     

Molecular and supramolecular chirality: R2PI spectroscopy as a tool for the gas-phase recognition of chiral systems of biological interest

In life sciences, diastereomeric chiral molecule/chiral receptor complexes are held together by a different combination of intermolecular forces and are therefore endowed with different stability and reactivity. Determination of these forces, which are normally affected in the condensed phase by solvent and supramolecular interactions, can be accomplished through the generation of diastereomeric complexes in the isolated state and their spectroscopic investigation. This review presents a detailed discussion of the mass resolved Resonant Two Photon Ionization (R2PI-TOF) technique in supersonic beams and introduces an overview of various other technologies currently available for the spectroscopic study of gas phase chiral molecules and supramolecular systems. It reports case studies primarily from our recent work using R2PI-TOF methodology for chiral recognition in clusters containing molecules of biological interest. The measurement of absorption spectra, ionization and fragmentation thresholds of diastereomeric clusters by this technique allow the determination of the nature of the intrinsic interactions, which control their formation and which affect their stability and reactivity.     

Fluorometric and liquid chromatographic study of the binding of two coumarins to β-cyclodextrin

The fluorescences of warfarin and phenprocoumon are enhanced following complexation with β-cyclodextrin; (+)-(R)- and (?)-(S)-phenprocoumons have different affinities for this cyclodextrin, whereas the corresponding enantiomers of warfarin have similar binding constants. Apparently, hemiketal formation in the case of warfarin minimizes chiral discrimination. This is confirmed using a β-cyclodextrin bonded chromatography column on which the phenprocoumon enantiomers are separated, whereas those of warfarin are not.     

Enantioselective separations using capillary electrophoresis

The preconditions are outlined for enantioselective separations in capillary electrophoresis (CE) with chiral selectors as additives to the background electrolyte. Free solution capillary electrophoresis conditions are characterised by a single solution phase. Chiral separations are reviewed by selector type (chiral ligand exchange, cyclodextrins, crown ethers, glycoproteins) with the extensive studies on cyclodextrins grouped into sections on amino acids, pharmaceuticals, and speciality chemicals, optimisation, biological fluids, and quantitative aspects. In micellar electrokinetic capillary chromatography, enantioselective discrimination occurs by partition in a two-phase system, with a chiral micellar phase as selector. Optimum separation conditions can be readily predicted for a given selector–selectand combination, and absolute values of binding constants determined by CE. Advantages of CE in comparison with HPLC using a chiral stationary phase include robust, rapid assays and the use of small volumes of aqueous solutions; disadvantages include less favourable detection limits. © 1994 Wiley-Liss, Inc.     

Enantiomeric separation of tetrahydroisoquinoline alkaloids by high-performance liquid chromatography with β-cyclodextrin as chiral selector

Tetrahydroisoquinoline alkaloids, which are known to be present not only in plants but also in animals, including mammals, can be considered as condensation products of 2-phenylethylamines (e.g., catecholamines) with aldehydes (e.g., acetaldehyde) or 2-oxo acids (e.g., pyruvic acid). In this study the possibility of separating the optical isomers of several tetrahydroisoquinolines by high-performance liquid chromatography was investigated. For isosalsoline, tetrahydropapaveroline and laudanosoline a good enantiomeric separation could be achieved by applying β-cyclodextrin-bonded silica as stationary phase in connection with various mobile phases. With respect to laudanosoline, the addition of β-cyclodextrin as chiral selector to the mobile phase using a C₁₈ reversed-phase column as stationary phase revealed an even higher resolution when compared with the chiral columns. All tested tetrahydroisoquinolines which could be well separated into enantiomers bear a hydroxyl group at carbon atom 7 as a common structural feature. Those alkaloids substituted with a methoxy group on position 7 instead of a hydroxyl group (e.g., salsolidine) failed to be resolved into their optical isomers. Therefore, the presence of a hydroxyl group on C7 of the aromatic ring seems to be conducive to steric discrimination. However, the separation results for 1-carboxysalsolinol were unsatisfactory although this molecule possesses a 7-hydroxyl group. In this case the existence of a carboxyl group on C1 reduced the chiral recognition and thus the enantiomeric resolution. © 1995 Wiley-Liss, Inc.     

NMR studies of chiral discrimination relevant to the enantioseparation of N-acylarylalkylamines by an (R)-phenylglycinol-derived chiral selector

Recently, it was reported that the chiral recognition ability of (R)-N-3,5-dinitrobenzoyl phenylglycinol derivative was examined as a new HPLC chiral stationary phase (CSP 1) for the resolution of racemic N-acylnaphthylalkylamines. However, the mechanism of chiral discrimination on the CSP remained elusive until now. In this study, a spectroscopic investigation of the chiral discrimination mechanism of CSP 1 was undertaken using mixtures of (R)-N-3,5-dinitrobenzoyl phenylglycinol-derived chiral selector (2) and each of the enantiomers of N-acylnaphthylalkylamines (3) by NMR study. First, the differences in free energy changes (DeltaDeltaG) upon diastereomeric complexation in solution between the complex of each isomer with chiral selector 2 by NMR titration were calculated. The values were then compared with those estimated by chiral HPLC. The chemical shift changes of each proton on the chiral selector and analytes were also checked and it was found that the chemical shift changes decreased continuously as the acyl group on analytes increased in length. This observation was consistent with the HPLC data. From these experimental results, the interaction mechanism of chiral discrimination between the chiral selector and the analytes is more precisely explained.     

Interactions of chiral molecules with an (r)-n-(3,5-dinitrobenzoyl) phenylglycine HPLC stationary phase

Forty different chiral molecules were studied by liquid chromatography with a Pirkle-type, (R)-N-(3,5-dinitrobenzoyl) phenylglycine (DNBPG), chiral stationary phase column. The dramatic effect of a small molecular change on chiral recognition was demonstrated using DL-amino acid derivatives. The inductive effect on chiral recognition was also studied using trifluoro-, trichloro-, dichloro-, monochloroacetyl, and acetyl derivatives of four different chiral amines. The study of the enantiomer separation of 11 different crown ethers of 2,2′-binaphthyldiyl showed that the rigidity of the chiral center can be an additional parameter in chiral recognition for the DNBPG phase but not for a β-cyclodextrin bonded chiral phase. It is apparent from this study that steric effects, inductive effects, and molecular rigidity play important roles in chiral recognition with DNBPG chiral stationary phases.     

Preparation of cyclodextrin chiral stationary phases by organic soluble catalytic 'click' chemistry

We describe an effective and simple protocol that uses click chemistry to attach native β-cyclodextrin (β-CD) to silica particles, resulting in a chiral stationary phase (CCNCSP) that can be used for the enantioseparation of chiral drugs by high-performance liquid chromatography (HPLC). Starting from β-CD, the CCNCSP is prepared in several steps: (i) reaction of β-CD with 1-(p-toluenesulfonyl)-imidazole to afford mono-6-toluenesulfonyl-β-CD; (ii) azidolysis of mono-6-toluenesulfonyl-β-CD in dimethylformamide to give mono-6-azido-β-CD (N(3)-CD); (iii) reaction of cuprous iodide with triphenylphosphine to form an organic soluble catalyst CuI(PPh(3)); (iv) preparation of alkynyl-modified silica particles; and (v) click chemistry immobilization of N(3)-CD onto alkynyl-modified silica to afford the desired chiral stationary phase. Synthesis of the stationary phase and column packing takes ～1 week.     

Effect of phosphatidylcholine vesicle size on chirality induction and chiral discrimination

The effect of the size of phosphatidylcholine (PC) vesicles on the induction of chirality and chiral discrimination was examined. Three kinds of vesicles formed with l-dimyristoyl, l-dipalmitoyl, or egg yolk PCs induced circular dichroisms (CDs) with the sign and intensity of the Cotton effect different from those of monomeric PCs. The CD intensity of the vesicles increased with a decrease in the vesicle size. Furthermore, the helicity of heterohelicene derivatives in a rapid equilibrium between right-handed (P) and left-handed (M) enantiomers was biased toward the M enantiomer side in l-PC vesicles, implying chiral discrimination by the vesicles. The extent of the bias toward the M enantiomer increased with an increase in vesicle size. Both the chirality induction and chiral discrimination were enhanced in a low-fluidity gel phase in comparison with those in a high-fluidity liquid-crystalline phase for every kind of vesicle of every size examined.     

Enantioselective and nonenantioselective degradation of organic pollutants in the marine ecosystem

Enantiomeric ratios of 11 chiral environmental pollutants determined in different compartments of the marine ecosystem by chiral capillary gas chromatography and chiral high-performance liquid chromatography allow discrimination between the following processes: enantioselective decomposition of both enantiomers with different velocities by marine microorganisms (α-HCH, β-PCCH, γ-PCCH); enantioselective decomposition of one enantiomer only by marine microorganisms (DCPP); enantioselective decomposition by enzymatic processes in marine biota (α-HCH, β-PCCH, trans-chlordane, cis-chlordane, octachlordane MC4, octachlordane MC5, octachlordane MC7, oxychlordane, heptachlor epoxide); enantioselective active transport through the “blood–brain barrier” (α-HCH); nonenantioselective photochemical degradation (α-HCH, β-PCCH). © 1993 Wiley-Liss, Inc.     

The nature of chiral recognition: Is it a three-point interaction?

Evolution of the initial “three-point attachment model” resulted in the understanding that an interaction in at least three configuration-dependent points is needed for a chiral selector to recognize entantiomers. Thermodynamic enantioselectivity of this interaction can result in chiral discrimination of the enantiomers, with the exception of a temperature range where enthalpic and entropic contributions to the free energy of discrimination balance each other. Similarly, a three-point interaction is needed for a chiral inductor to modify enantiospecifically a prochiral molecule. The difference between a theoretical interaction point and real interaction sites in chemical molecules is emphasized. The role of conformational rigidity of chiral species is discussed in relation to the dependence of spatial arrangement of three active points on the configuration of the species. Chirality 9:99–102, 1997. © 1997 Wiley-Liss, Inc.     

Local sensing of global DNA topology: from crossover geometry to type II topoisomerase processivity

Type II topoisomerases are ubiquitous enzymes that control the topology and higher order structures of DNA. Type IIA enzymes have the remarkable property to sense locally the global DNA topology. Although many theoretical models have been proposed, the molecular mechanism of chiral discrimination is still unclear. While experimental studies have established that topoisomerases IIA discriminate topology on the basis of crossover geometry, a recent single-molecule experiment has shown that the enzyme has a different processivity on supercoiled DNA of opposite sign. Understanding how cross-over geometry influences enzyme processivity is, therefore, the key to elucidate the mechanism of chiral discrimination. Analysing this question from the DNA side reveals first, that the different stability of chiral DNA cross-overs provides a way to locally sense the global DNA topology. Second, it shows that these enzymes have evolved to recognize the G- and T-segments stably assembled into a right-handed cross-over. Third, it demonstrates how binding right-handed cross-overs across their large angle imposes a different topological link between the topoIIA rings and the plectonemes of opposite sign thus directly affecting the enzyme freedom of motion and processivity. In bridging geometry and kinetic data, this study brings a simple solution for type IIA topoisomerase chiral discrimination.     

Development and validation of an experimental and theoretical method for the chiral discrimination of dinotefuran

Dinotefuran is a low-cost agrochemical considered a highly toxic product. In this sense, there is a need for its constant environmental, biological, and food control, aiming to ensure its use to humans as well as to preserve biodiversity and ecosystems. In the present work, we developed an experimental and theoretical method for dinotefuran chiral discrimination. According to the main results, the dinotefuran enantioselective separation was efficiently optimized by high-performance liquid chromatography evaluating the influence of different percentage compositions in the mobile phase to improve the resolution of the peaks in the chromatogram. The novelty of this work was the proposition of a reduced molecular model for the chiral selector amylose-Tris-(3,5-dimethylphenylcarbamate) polysaccharide that was able to adequately describe at the molecular level its interaction with the dinotefuran enantiomers. Besides, the thermodynamic and structural parameters obtained via density functional theory calculations pointed out the chiral discrimination as well as the enantiomeric elution order of the analyte studied, confirming the experimental data, thus validating our proposed method. Finally, hydrogen bonds and repulsive interactions played a key role in the discrimination between the diastereomeric complexes, and consequently, for the dinotefuran enantioselective separation.     

Elucidation of the chromatographic enantiomer elution order for praziquantel: An experimental and theoretical assessment

In this work, we have studied both experimentally and theoretically the praziquantel (PZQ) chiral discrimination. According to the main results, the enantioseparation of PZQ was efficiently optimized by HPLC on the reverse phase from the Chiralpak IB column, which has cellulose tris (3,5-dimethylphenylcarbamate) (CDMPC) as a chiral selector. The thermodynamic and structural parameters obtained via density functional theory (DFT) calculations pointed out the chiral discrimination as well as the enantiomeric elution order of PZQ, thus elucidating the experimental data and validating our proposed method. Finally, the hydrogen bonds and π-π stacking interactions played a key role in the discrimination between the PZQ diastereomeric complexes formed.     

Chiral bifurcation in aggregating insulin: an induced circular dichroism study

The structural unambiguity of folding is lost when disordered protein molecules convert into β-sheet-rich fibrils. The resulting polymorphism of protein aggregates has been studied in the context of its biomedical consequences. Events underlying the conformational variance of amyloid fibrils, as well as physicochemical boundaries between folding and misfolding pathways, remain obscure. Bifurcation and chiral mesoscopic-scale organization of amyloid fibrils are new aspects of protein misfolding. Here we characterize bifurcation events accompanying insulin fibrillation upon intensive vortexing. Upon agitation, two types of insulin fibrils with opposite chiral senses are formed; however, predominance of either species is only stochastically determined. The uncertainty of fibrils’ chiral sense holds only for fibrils grown within the physiological temperature range, while above 50 °C, the bifurcation is no longer observed—fibrils’ chiral moieties become uniformly biased towards ligand probes, as revealed by the extrinsic Cotton effect of thioflavin T, Congo red, and molecular iodine. According to transmission electron microscopy and scanning electron microscopy data, chiral variants of insulin fibrils consist of fibrous superstructures, distinct from spherulites, formed by the protein in nonagitated solutions. Gradual dissociation of the fibrils in the presence of dimethyl sulfoxide is noncooperative and can be resolved into three distinct phases: decay of the higher-order chiral structures, breakdown of fibrils, and unfolding of intermolecular β-sheet. The chiral aggregates are also destabilized by elution of NaCl implying that Debye screening of charged β-sheets provided by chloride counterions is needed for sustaining their kinetic stability. At elevated temperatures, cross-seeding of agitated insulin samples with preformed fibrils revealed a chiral conflict that prevented the passing of structural features of mother seeds to daughter fibrils in a manner typical of amyloid “strains.”     

Direct enantioselective separation of some propranolol analogs by HPLC on normal and reversed cellulose chiral stationary phases

The enantiomeric separation of several racemic aryloxyaminopropan-2-ol derivatives related to propranolol on normal and reversed phase of cellulose tris (3,5-dimethylphenylcarbamate) chiral stationary phases known as Chiralcel OD and Chiralcel OD-R were studied. It was observed that the chiral separation depends on the substitution pattern of the aryl group, i.e., 1-naphthyl, 2-naphthyl, and phenyl group and polarity on the basic nitrogen in the side chain. In both normal and reversed phase modes the (+)-R-enantiomer eluted first in all of the analogs resolved. It can be concluded that: (1) substituents on the side chain did affect the interaction of the enantiomers with the polar carbamate moiety in the CSP; and (2) the dipole-dipole stacking between the π-donor 3,5-dimethylphenyl carbamate group pending from the glucose rings of the CSP and π-acceptor aryl group of the analyte is crucial for the efficient chiral discrimination. The chiral recognition mechanism(s) between these analogs and the chiral stationary phases are proposed. © 1996 Wiley-Liss, Inc.     

Atomic force microscopy studies of the adhesive properties of DPPC vesicles containing β-carotene

A role of carotenoids as modulators of physical properties of model and biological membranes has been already postulated. However, there is a lack of information on the influence of these pigments on interactions between the lipids which form such membranes. This paper applies atomic force microscopy (AFM) in to study the effects of β-carotene on the adhesion properties of DPPC multilamellar liposomes. This allowed us to gain, for the first time, a direct insight into the interactions between the components in model systems on a molecular level. We observe that the adhesive forces in DPPC multilamellar liposomes containing 1mol% of β-carotene decrease exponentially with increasing temperature, and that at about 37°C they diminish. In the case of pure liposomes the decline in adhesion is of a different nature and the adhesive forces disappear at 34°C. The adhesive forces are about 5 times higher at 31°C in the presence of β-carotene than in its absence. However, measurements using differential scanning calorimetry (DSC) showed a shift of the lamellar-to-undulled-lamellar phase transition toward lower temperatures by about 0.8 ± 0.2°C in a system containing β-carotene. The enthalpy changes (ΔH) of this transition are similar for both systems. For the main transition, gel-to-liquid crystalline, the peak is shifted by about 0.5 ± 0.1°C, and ΔH decreases by about 30% in liposomes treated with β-carotene in comparison to pure liposomes. Our results suggest increased cooperation between liposome components in a system with enriched β-carotene, which cause a change in phase transition temperatures. Moreover, these interactions are very sensitive to temperature.     

Enantioselective influence of cyclodextrins on cleavage of chiralic esters

Assessing the reactivity of optical antipodes is of central importance in drug research. Using the model of 2-methoxy-2-phenylacetic acid-4-nitrophenylester (MPE), the rate of hydrolysis in the presence of β-cyclodextrin (CD), hydroxyethyl- and hydroxypropyl-β-CD, as well as methyl-β-CD is studied photometrically and by means of HPLC (Chiralcel-OD-R-column). Both β-CD and hydroxyalkylated-β-CD catalyze (?)-(R)-enantiomers to a larger extent than (+)-(S)-enantiomers, resulting in an enrichment of the latter. Methyl-β-CD stabilizes the ester trifold, thus abolishing chiral discrimination. © 1995 Wiley-Liss, Inc.