期刊
RSC ADVANCES
卷 11, 期 57, 页码 35754-35764出版社
ROYAL SOC CHEMISTRY
DOI: 10.1039/d1ra04697g
关键词
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资金
- Key Research and Development Program of Ningxia (Special Project for Foreign Cooperation) [2019BFH03004]
- Introduced Team Program of Ningxia (Rouxing) [2019RXTD0004]
- Graduate Innovation Project of North Minzu University [YCX20141]
A novel bridged bis(beta-cyclodextrin) chiral stationary phase (HTCDP) was synthesized for the first time, showing superior enantiomer separation and chiral recognition abilities. By optimizing chromatographic conditions, HTCDP successfully separated 19 analytes with high resolution, outperforming the native beta-CD chiral stationary phase (CDCSP).
A bridged bis(beta-cyclodextrin) ligand was firstly synthesized via a thiol-ene click chemistry reaction between allyl-ureido-beta-cyclodextrin and 4-4 '-thiobisthiophenol, which was then bonded onto a 5 mu m spherical silica gel to obtain a novel bridged bis(beta-cyclodextrin) chiral stationary phase (HTCDP). The structures of HTCDP and the bridged bis(beta-cyclodextrin) ligand were characterized by the H-1 nuclear magnetic resonance (H-1 NMR), solid state C-13 nuclear magnetic resonance (C-13 NMR) spectra spectrum, scanning electron microscope, elemental analysis, mass spectrometry, infrared spectrometry and thermogravimetric analysis. The performance of HTCDP in enantioseparation was systematically examined by separating 21 chiral compounds, including 8 flavanones, 8 triazole pesticides and 5 other common chiral drugs (benzoin, praziquantel, 1-1 '-bi-2-naphthol, Troger's base and bicalutamide) in the reversed-phase chromatographic mode. By optimizing the chromatographic conditions such as formic acid content, mobile phase composition, pH values and column temperature, 19 analytes were completely separated with high resolution (1.50-4.48), in which the enantiomeric resolution of silymarin, 4-hydroxyflavanone, 2-hydroxyflavanone and flavanone were up to 4.34, 4.48, 3.89 and 3.06 within 35 min, respectively. Compared to the native beta-CD chiral stationary phase (CDCSP), HTCDP had superior enantiomer separation and chiral recognition abilities. For example, HTCDP completely separated 5 other common chiral drugs, 2 flavanones and 3 triazole pesticides that CDCSP failed to separate. Unlike CDCSP, which has a small cavity (0.65 nm), the two cavities in HTCDP joined by the aryl connector could synergistically accommodate relatively bulky chiral analytes. Thus, HTCDP may have a broader prospect in enantiomeric separation, analysis and detection.
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