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Journal of Liquid Chromatography Volume 11, 1988 - Issue 16
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Original Articles

Separation of Cyclodextrins Using Cyclodextrin Bonded Phases

Heng L. Jin Department of Chemistry, University of Missouri-Rolla, Rolla, Missouri, 65401
,
Apryll M. Stalcup Department of Chemistry, University of Missouri-Rolla, Rolla, Missouri, 65401
&
Daniel W. Armstrong Department of Chemistry, University of Missouri-Rolla, Rolla, Missouri, 65401
Pages 3295-3304 | Published online: 03 Jan 2007

Citations (24)

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Read on this site (4)

Haixiao Qiu, Mayumi Kiyono-Shimobe & DanielW. Armstrong. (2014) NATIVE/DERIVATIZED CYCLOFRUCTAN 6 BOUND TO RESINS VIA “CLICK” CHEMISTRY AS STATIONARY PHASES FOR ACHIRAL/CHIRAL SEPARATIONS. Journal of Liquid Chromatography & Related Technologies 37:16, pages 2302-2326.
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Chunlei Wang, ZacharyS. Breitbach & DanielW. Armstrong. (2010) Separations of Cycloinulooligosaccharides via Hydrophilic Interaction Chromatography (HILIC) and Ligand-Exchange Chromatography. Separation Science and Technology 45:4, pages 447-452.
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Alain Berthod, Laurence Berthod & Daniel W. Armstrong. (2005) Selectivity of a Native β‐Cyclodextrin Column in the Separation of Catechins. Journal of Liquid Chromatography & Related Technologies 28:11, pages 1669-1678.
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Alain Berthod, Heng Liang Jin & DanielW. Armstrong. (1991) Cyclodextrin Purification with Hollow Fibers. Separation Science and Technology 26:4, pages 515-527.
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Articles from other publishers (20)

Jeongjae Yu, Michael Wey, Sepideh Khaki Firooz & Daniel W. Armstrong. (2021) Ionizable Cyclofructan 6-Based Stationary Phases for Hydrophilic Interaction Liquid Chromatography Using Superficially Porous Particles. Chromatographia 84:9, pages 821-832.
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Abul K. Mallik, Sudhina Guragain, Mohammed Mizanur Rahman, Makoto Takafuji & Hirotaka Ihara. (2019) L-Lysine-derived highly selective stationary phases for hydrophilic interaction chromatography: Effect of chain length on selectivity, efficiency, resolution, and asymmetry. Separation Science Plus 2:2, pages 42-50.
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Yadi Wang, M. Farooq Wahab, Zachary S. Breitbach & Daniel W. Armstrong. (2016) Carboxylated cyclofructan 6 as a hydrolytically stable high efficiency stationary phase for hydrophilic interaction liquid chromatography and mixed mode separations. Analytical Methods 8:31, pages 6038-6045.
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Abul K. Mallik, Wee Keat Cheah, Kaori Shingo, Aika Ejzaki, Makoto Takafuji & Hirotaka Ihara. (2014) Highly hydrophilic and nonionic poly(2-vinyloxazoline)-grafted silica: a novel organic phase for high-selectivity hydrophilic interaction chromatography. Analytical and Bioanalytical Chemistry 406:19, pages 4585-4593.
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Nilusha L. T. Padivitage, Milan K. Dissanayake & Daniel W. Armstrong. (2013) Separation of nucleotides by hydrophilic interaction chromatography using the FRULIC-N column. Analytical and Bioanalytical Chemistry 405:27, pages 8837-8848.
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Bernard A. Olsen, Donald S. Risley, V. Scott Sharp, Brian W. Pack & Michelle L. Lytle. 2013. Hydrophilic Interaction Chromatography. Hydrophilic Interaction Chromatography 111 168 .
Haixiao Qiu, Daniel W. Armstrong & Alain Berthod. (2013) Thermodynamic studies of a zwitterionic stationary phase in hydrophilic interaction liquid chromatography. Journal of Chromatography A 1272, pages 81-89.
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Nilusha L. T. Padivitage & Daniel W. Armstrong. (2011) Sulfonated cyclofructan 6 based stationary phase for hydrophilic interaction chromatography. Journal of Separation Science 34:14, pages 1636-1647.
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D. M. Milan Krishantha, Zachary S. Breitbach, Nilusha L. T. Padivitage, Daniel W. Armstrong & Xiyun Guan. (2011) Rapid determination of sample purity and composition by nanopore stochastic sensing. Nanoscale 3:11, pages 4593.
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Chunlei Wang, Chunxia Jiang & Daniel W. Armstrong. (2008) Considerations on HILIC and polar organic solvent‐based separations: Use of cyclodextrin and macrocyclic glycopetide stationary phases. Journal of Separation Science 31:11, pages 1980-1990.
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J. Szemán, K. Csabai, K. Kékesi, L. Szente & G. Varga. (2006) Novel stationary phases for high-performance liquid chromatography analysis of cyclodextrin derivatives. Journal of Chromatography A 1116:1-2, pages 76-82.
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Thumnoon Nhujak & David M. Goodall. (2001) Trace analysis of γ-cyclodextrin in a sample of β-cyclodextrin by capillary electrophoresis. Journal of Chromatography A 907:1-2, pages 313-320.
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P.K Zarzycki, M Wierzbowska, J Nowakowska, A Chmielewska & H Lamparczyk. (1999) Interactions between native cyclodextrins and n-alcohols studied using thermostated thin-layer chromatography. Journal of Chromatography A 839:1-2, pages 149-156.
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Yuzhi Fang, Feiyan Gong, Xiaoming Fang & Chonggang Fu. (1998) Separation and determination of cyclodextrins by capillary electrophoresis with amperometric detection. Analytica Chimica Acta 369:1-2, pages 39-45.
Crossref
Ying‐Haur Lee & Tsung‐I. Lin. (2005) Capillary electrophoretic analysis of cyclodextrins and determination of formation constants for inclusion complexes. ELECTROPHORESIS 17:2, pages 333-340.
Crossref
Peter Schreier, Alexander Bernreuther & Manfred Huffer. 1995. Analysis of Chiral Organic Molecules. Analysis of Chiral Organic Molecules 68 131 .
Shirley C. Churms. 1995. Carbohydrate Analysis. Carbohydrate Analysis 103 146 .
Jim Yu & Ziad El Rassi. (2005) Preparation of amino‐zirconia bonded phases and their evaluation in hydrophilic interaction chromatography of carbohydrates with pulsed amperometric detection. Journal of High Resolution Chromatography 17:11, pages 773-778.
Crossref
Sharron G. Penn, Rick W. Chiu & Curtis A. Monnig. (1994) Separation and analysis of cyclodextrins by capillary electrophoresis with dynamic fluorescence labelling and detection. Journal of Chromatography A 680:1, pages 233-241.
Crossref
Andrew J. Alpert. (1990) Hydrophilic-interaction chromatography for the separation of peptides, nucleic acids and other polar compounds. Journal of Chromatography A 499, pages 177-196.
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