Chiral recognition in surface explosion

The vast majority of chiral compounds crystallize into racemic crystals. It has been predicted and was experimentally established as a rule that chiral molecules on surfaces are more easily separated into homochiral domains due to confinement into a plane and lower entropic contributions. We investigated the formation and stability of two-dimensional tartrate crystals on a Cu(110) surface for the racemic mixture for the first time by means of temperature-programmed desorption (TPD), low-energy electron diffraction (LEED), and X-ray photoelectron spectroscopy (XPS). At low coverage, a bitartrate species becomes separated into homochiral domains, while at high coverage a monotartrate species forms a racemic mixture. At the same coverage and lateral arrangement, the thermally induced autocatalytic decomposition reaction occurs for the monotartrate racemate at a lower temperature than for the pure enantiomers. The stereochemistry in this so-called "surface explosion" reaction is explained by a higher stability of the enantiopure lattice due to lateral hydrogen-bond formation. The higher stability of the enantiopure two-dimensional lattice is in contrast to the higher stability of racemic three-dimensional tartaric acid crystals but is consistent with the observation that homochirality is preferred in hydrogen-bonded self-assembled biomolecular structures.     

Chiral recognition in cucurbituril cavities

For the first time, achiral cucurbiturils (CBs) were endowed with significant enantiomeric and distereomeric discrimination by incorporating a strong chiral binder. Calorimetric, nuclear magnetic, light-scattering, and mass spectral studies revealed that (S)-2-methylbutylamine (as a strong binder) can be discriminated by two enantiomeric supramolecular hosts, composed of CB[6] and (R)- or (S)-2-methylpiperazine, with an unprecedented 95% enantioselectivity in aqueous NaCl solution. This is the highest enantioselectivity ever reported for a supramolecular system derived from an achiral host. Similarly, CB[7], with a larger cavity, exhibited diastereoselectivities up to 8 times higher for diastereomeric dipeptides, as demonstrated for L-Phe-L-Leu-NH3+ versus L-Phe-D-Leu-NH3+.     

Chiral recognition of carbon nanoforms

The selective recognition of chiral carbon nanoforms poses a fundamental challenge. New design principles must be devised to construct hosts capable of enantiodiscrimination between species in which chirality does not arise from asymmetric carbon atoms. In this emerging area article, we provide an overview of some of the relatively few successful examples of chiral recognition of carbon nanoforms, highlighting their common features with the aim of helping to develop general trends for the design of new generations of hosts.     

Chiral recognition of dipeptides in phosphatidylcholine aggregates

Enantiodiscrimination of ditryptophan enantiomers (l-Trp-l-Trp and d-Trp-d-Trp, l-Trp-d-Trp and d-Trp-l-Trp) was observed in bio-membrane models, such as micellar aggregates of 1,2-diheptanoyl-sn-glycero-3-phospatidylcholine (DHPC) and multilamellar vesicles of either 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) or 1,2-dimyristoyl-sn-glycero-3-phospatidylcholine (DMPC) by solution ¹H NMR and HR-MAS ¹H NMR, respectively. The attainment of resolved signals, allowed the first detection of enantiodiscrimination at a molecular level, and the identification of the site of chiral recognition and of the interactions and conformations of homo- and heterochiral dipeptides in large-sized aggregates formed by a common component of bio-membranes.     

Chiral recognition in the resolution of enantiomers by GLC

Summary Chiral recognition of many enantiomeric solutes by a chiral amide stationary phase is based mainly on hydrogen bonding. A chiral-recognition-factor CHI is proposed, given by the difference of the enthalpy change in the enantiomer discrimination, standardized with respect to the specific interaction of the solutes with the diamide core of the stationary phase. The r?le of the entropy part is also discussed. By extrapolation of the retention behaviour to elevated temperature, peak inversion of enantiomers is predicted. Presented at the 15th International Symposium on Chromatography, Nürnberg, October 1984     

Chiral recognition of dipeptides in Langmuir monolayers

The recognition of the enantiomeric couples of ditryptophan in Langmuir films of N-hexadecanoyl-l-proline was investigated by surface pressure–area (π–A) isotherm measurements and Brewster angle microscopy experiments. The π–A isotherms relative to the films including the enantiomeric dipeptides show small differences whereas an evident enantiodiscrimination is observed by Brewster angle microscopy images.     

Chiral recognition of functionalized cyclodextrins in capillary electrophoresis

The chiral recognition of hydroxypropylated, dimethylated, and sulfated cyclodextrins was evaluated by utilizing them as chiral additives in capillary electrophoresis. Although each selector yielded enantiomeric separations of most of the target analytes, differences were observed in the electrophoretic results for the different derivatized cyclodextrins and for additives having varying degrees of substitution. The results for the sulfated cyclodextrins also highlighted the importance of knowing the degree of substitution as well as the location of the substituents when comparing chiral selectors.     

Chiral recognition of dipeptides in a biomembrane model

Chiral recognition of the enantiomeric couples of ditryptophan and diphenylalanine was observed by (1)H NMR spectroscopy in micelles formed by sodium N-dodecanoyl-L-prolinate. Ditryptophan showed a selective association with the Z domains of the amidic aggregates, whereas diphenylalanine did not show any selectivity in the association. Partition coefficients between water and aggregates were evaluated by diffusion NMR experiments. Intramolecular distances of ditryptophan isomers associated with chiral aggregates were obtained by ROESY experiments and were used as constraints in molecular mechanics calculations. From these calculations, information on the conformation of the peptides in the chiral aggregates was obtained.     

Chiral recognition in aggregates formed by chiral bola-amphiphiles

The aggregates of three new isomeric chiral bola-amphiphiles have been taken into consideration as models for investigating chiral recognition in biological membranes. The recognition capabilities of the aggregates were explored following (by CD and HPLC experiments) the shift in the equilibrium between the inter-converting enantiomers of a biphenylic derivative and bilirubin, used as markers of chirality. The chiral recognition experiments were performed under different pH and concentration conditions. The results were compared with those relative to the aggregates formed by an equimolar mixture of single head/single chain amphiphiles that mimic the structure of the bola surfactant devoid of a covalent link.     

Chiral studies in amorphous solids: the effect of the polymeric glassy state on the racemization kinetics of bridged paddled binaphthyls

Optical activity, used here for the first time to gain information about the amorphous solid state, allows previously unavailable insight into the dynamic properties of polymer glasses and their effect on a chemical process. This is accomplished by dispersing in polymer glasses atropisomeric bridged binaphthyls with appended oligophenyl paddles of varying sizes and studying the racemization kinetics as a function of temperature. The racemization occurs by a simple one-dimensional twisting motion and, without effect on the intrinsic mechanism, sweeps out a variable volume of the matrix as the paddle length is increased. The racemization is limited by the polymer matrix only for probes with a minimum paddle size and only when the time scale for racemization is comparable to the time scale for segmental motion of the polymer matrix. The high barrier for this racemization is unique in probe studies of glasses and causes these overlapping time scales to occur significantly below the glass transition temperature. These measurements yield a clear quantitative view of the role of segmental dynamics on the racemization kinetics of the binaphthyls and allow the important demonstration, via the transition from first-order to stretched exponential kinetics, that heterogeneous dynamics persist deep within the glassy state.     

The problem of recognition in chemistry

A purposeful search for effective biologically active substances with required properties is possible only under the condition that the mechanisms of the chemical reactions taking place in biological systems are understood. The complexity of biochemical processes has forced investigators to devise models for studying and isolating various parameters of these processes. Just such an approach has yielded important results in bioorganic chemistry. One of the most crucial problems in biochemistry and biophysics is the recognition of a specific substrate by a receptor. The theory advanced by E. Fischer at the end of the nineteenth century, that enzymes interact with substrates according to a lock-and-key principle, has been transformed into a fairly rigorous conception of the recognition of molecules of different chemical compounds. The present paper is devoted to a discussion of the problems related to the improvement of the physicochemical model of recognition.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 22, No. 4, pp. 450–463, July–August, 1986.     

Chiral softballs: synthesis and molecular recognition properties.

Studies on the different congeners of the softball were undertaken to explore structural variants for enantioselective encapsulation. Two different spacer elements in the monomeric subunit render the dimeric softball chiral although the monomer itself is achiral. The dimers represent capsules with dissymmetric cavities with volumes ranging from 190 to 390 A(3). The cavities are distorted spheres, and asymmetric guests, such as naturally occurring terpenes, generally prefer one enantiomer of the capsule to its mirror image. The selectivities are moderate (up to 4:1). The complexation studies show that the host capsules are flexible enough to arrange themselves comfortably around a guest but still maintain enough rigidity to be influenced by the occupancy of a chiral guest. The enantiomeric capsules can interconvert (racemize) by dissociation and recombination of their subunits.     

Chiral recognition by molecularly imprinted polymers in aqueous media

Summary Molecularly imprinted polymers were prepared using 2-vinylpyridine and/or methacrylic acid as functional monomers in a self-assembly imprinting protocol. The resulting polymers were analyzed in aqueous media, and the effects from the pH of the mobile phase and the degree of added organic solvent were investigated. The results are indicative of the importance of ionic bonds in conjunction with hydrophobic interactions in the formation of the complexes between the analyte and the polymers.     

Chiral recognition in aggregation of gold nanoparticles grafted with helicenes

Chiral recognition was observed in the interactions of gold nanoparticles grafted with (±)-, (M)-, and (P)-helicenethiol. Although the nanoparticles contain equal enantiomeric excess, a 1:1 mixture of (M)- and (P)-nanoparticles aggregated more rapidly in solution than (±)-nanoparticles.     

Chiral recognition capabilities of melamine and cyanuric acid supramolecular structures

Currently, there are numerous papers that discuss local chiral domains in supramolecular structures of achiral molecules established using the STM method, and by using DFT calculations. However, there are no data regarding the obtainment of macroscopically chiral 2D-supramolecular structures from achiral molecules. In this study, melamine and cyanuric acid supramolecular structures were self-assembled on a graphitized carbon black surface, which had a surface structure that was identical to HOPG, and also on the surface of an inert solid support for chromatography. Chirality induction according to the Kondepudi effect was used. For the supramolecular structures, MD calculations showed the possibility of obtaining a chiral structure. To establish macroscopic chirality, we proposed the use of the difference in enantiomer adsorption on the modified adsorbents. For this, two indirect methods were used: static adsorption with a polarimetric control and gas chromatography. Both methods indicated the chiral recognition ability of the adsorbents used.     

Synthesis of hybrid structures comprising diaziridine and cyclopropane rings in one molecule

1. Download high-res image (148KB)
2. Download full-size image

     

Chiral recognition conducted by tartaric acid derivatives in nonaqueous media

Chiral recognition of hydroxycaboxylic acid, amino acid and 1,2-diol derivatives using diastereomeric complexation based on hydrogen bond with L(+)-N,N′-diisopropyl-tartramide (DIPTA) is described.     

The problem of small negatively ionized water clusters

Structures of the negatively charged water clusters (H₂O)⁻_n with n up to 6 were optimized at the UHF/4–31 + + G** level without any geometrical restriction. There was found a chainlike structure for the trimer anion and both chainlike and cyclic geometries for the larger clusters. According to the MP2 energy estimates, all the clusters with n ≥ 3 are more stable than the combinations of separated water molecules and a free electron. The energy of the cycles is lower than that of the chains of the same size. However, the latter species are energetically closer to the neutral oligomers of the same geometry. The energy of vertical detachment of an electron from the chainlike hexamer anion is already about zero. Addition of a diffuse s function centered equidistantly between the oxygen atoms proved metastability, in particular, of the cyclic (H₂O)⁻₄ structure. © 1997 John Wiley & Sons, Inc. Int J Quant Chem 63: 737–748, 1997