Chiral recognition of (18-crown-6)-tetracarboxylic acid as a chiral selector determined by NMR spectroscopy

Bang, Eunjung; Jung, Jinwon; Lee, Won–Jae; Lee, Dai Woon; Lee, Weontae

doi:10.1039/b102026i

Cited by 76 publications

(68 citation statements)

References 36 publications

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“…11). 이외에도 NMR spectroscopy 분석기기를 이용하여 (+)-18-C-6-TA를 키랄선택자로 하여 PG와 alanine 그리고 그들의 ester 유도체 뿐만 아니라 thrombin inhibitor의 저해제의 키 랄 선구물질로 사용되는 diphenylalanine의 chiral solvating agent와 관련된 광학분리 연구가 보고되었다 [31][32][33]. H NMR spectra of Phe-ME and Phe-ME/18-C-6-TA complex with equimolar mixtures (20 mM each); (a) (L)-Phe-ME with 18-C-6-TA, (b) racemic Phe-ME with 18-C-6-TA, (c) racemic Phe-ME.…”

Section: 1'-binaphthyl에 기초한 키랄 크라운 에테르를 이용 한 광학분리unclassified

The Development and Application of Chirotechnology Using Chiral Crown Ethers for Enantiomer Separation

백만정¹,

윤원남²,

이원재³

2012

KSBB Journal

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1) Chiral crown ethers are synthetic macrocyclic polyethers that bind protonated chiral primary amines with high selectivity and affinity. They have been widely used to separate or distinguish the enantiomers of chiral compounds containing a primary amino moiety by high-performance liquid chromatography, capillary electrophoresis, and NMR spectroscopy. In this paper, two important chiral crown ethers including chiral binaphthyl unit and (18-crown-6)-2,3,11,12-tetracarboxylic acid as chiral selectors are focused. And several chiral resolution techniques and their applications in chirotechnology using these chiral crown ethers with related chiral recognition mechanism studies are reviewed. Especially, it was shown that the commercially available HPLC columns based on (18-crown-6)-2,3,11,12-tetracarboxylic acid have been developed and successfully applied for the resolution of various primary amino compounds including amino acids.

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Section: 1'-binaphthyl에 기초한 키랄 크라운 에테르를 이용 한 광학분리unclassified

The Development and Application of Chirotechnology Using Chiral Crown Ethers for Enantiomer Separation

백만정¹,

윤원남²,

이원재³

2012

KSBB Journal

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“…[9] In a search for the origin of the chiral recognition of a-amino acids in the presence of 18C6TA as a chiral selector, the interactions responsible for the differential affinities towards enantiomers were investigated for the specific case of phenylglycine by NMR spectroscopy and molecular dynamics calculations. [10] It was revealed that the polyether ring forms a bowl that is shaped by intramolecular hydrogen bonding involving the carboxylic groups located under the plane of the ring and situated on carbon atoms 3 and 12 of the polyether ring (Scheme 2). As a consequence, the upper face is open to allow intermolecular hydrogen bonding between the hydrogen atoms of the ammonium group and three oxygen atoms of the crown ether.…”

Section: Introductionmentioning

confidence: 99%

“…The key features for enantiomeric discrimination are 1) the three + NH···O hydrogen bonds in a tripod arrangement between polyether oxygen atoms and the ammonium moiety of the l or d enantiomer, 2) a hydrophobic interaction between the polyether ring of the host molecule and the phenyl moiety of the enantiomers, and 3) a hydrogen bond between the carboxylic acid of the crown ether and the carbonyl oxygen atom for the d enantiomer only. [10] This additional hydrogen bond is considered to be crucial for effective chiral discrimination because, as a consequence, the d isomer of phenylglycine would form a more favorable complex with chiral (+)-18C6TA than the l isomer. [10] Chiral discrimination requires the cooperative interaction of several weak forces, such as dipole-dipole, hydrophobic, electrostatic, van der Waals, and hydrogen-bonding interactions.…”

Section: Introductionmentioning

confidence: 99%

Noncovalent Interactions between ([18]Crown‐6)‐Tetracarboxylic Acid and Amino Acids: Electrospray‐Ionization Mass Spectrometry Investigation of the Chiral‐Recognition Processes

Gerbaux

Winter

Cornil

et al. 2008

Chemistry A European J

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Chiral recognition of enantiomers by host compounds is one of the most challenging topics in modern host-guest chemistry. Amongst the well-established methods, mass spectrometry (MS) is increasingly used nowadays, due to its low detection limit, short analysis time, and suitability for analyzing mixtures and for studying chiral effects in the gas phase. The development of electrospray-ionization (ESI) techniques provides an invaluable tool to study, in the gas phase, diastereoisomeric complex ions prepared from enantiomer ions and a chiral selector. This paper reports on an ESIMS and ESIMSMS study of the molecular mechanisms that intervene in the chiral-recognition phenomena observed between amino acids and a chiral crown ether. The modified crown ether, namely (+)-([18]crown-6)-2,3,11,12-tetracarboxylic acid, is used as the chiral selector when covalently bound on a stationary phase in liquid chromatography. This study was stimulated by the fact that, except with threonine and proline, consistent elution orders were observed, which indicates that the D enantiomers interact more strongly with the chiral selector than the L enantiomers. For proline, the lack of a primary amino group is likely to be responsible for the nonresolution of the two forms, whereas the second stereogenic center on threonine could explain the reversed elution order. In light of those observations, we performed mass spectrometry experiments to understand more deeply the enantiomeric recognition phenomena, both in solution by the enantiomer-labeled guest method and in the gas phase by gas-phase ligand-exchange ion/molecule reactions. The results have been further supported by quantum chemical calculations. One of the most interesting features of this work is the identification of a nonspecific interaction between proline and the crown ether upon ESIMS analysis.

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“…A different type of crown ether used to separate enantiomers is derived from 18-crown-6 tetracarboxylic acid, covalently immobilised on silica gel via the reaction between 18-crown-6 tetracarboxylic acid and amino propyl silica gel [51,52]. NMR spectroscopy of the complex between the 18-crown-6 tetracarboxylic acid and phenylglycine or phenylglycine methyl ester showed for the chiral recognition of the more stable complex the following interactions: 1) three -NH … O hydrogen bonds in a tripod arrangement between the polyether oxygens of 18-crown-6-tetra carboxylic acid and the ammonium moiety of the enantiomer; 2) a hydrophobic interaction between the polyether ring of 18-crown-6-crown ether and the phenyl ring of the enantiomer; 3) hydrogen bonding between the carboxylic acid of the crown ether and the carbonyl oxygen of the enantiomer [53]; 4) if the analyte contains an aromatic moiety, in some instances CH - interactions are possible from the carbon adjacent to the carboxyl group and the aromatic moiety. Table 6.4 gives the HPLC mobile phase composition for the enantiomeric separation of selected compounds on the CSP containing (+/-)-18-crown-6 ether.…”

Section: R-x-h + :Y-r'⇄ R-x-h … Y-r'mentioning

confidence: 99%

Chiral Separation for Enantiomeric Determination in the Pharmaceutical Industry

Grinberg¹,

Pan²

2012

Physico-Chemical Methods in Drug Discovery and Development

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Chiral recognition of (18-crown-6)-tetracarboxylic acid as a chiral selector determined by NMR spectroscopy

Cited by 76 publications

References 36 publications

The Development and Application of Chirotechnology Using Chiral Crown Ethers for Enantiomer Separation

The Development and Application of Chirotechnology Using Chiral Crown Ethers for Enantiomer Separation

Noncovalent Interactions between ([18]Crown‐6)‐Tetracarboxylic Acid and Amino Acids: Electrospray‐Ionization Mass Spectrometry Investigation of the Chiral‐Recognition Processes

Chiral Separation for Enantiomeric Determination in the Pharmaceutical Industry

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