A biomimetic hybrid material consisting of CaCO mesoporous microspheres and an alternating copolymer for reversed-phase HPLC

We developed a biomineral-inspired hybrid material composed of CaCO 3 and an organic polymer as a column packing material for HPLC. This material combines a hierarchical mesoporous structure and the functionality of the polymer. The surface of monodispersed mesoporous CaCO 3 microspheres was modifie...

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Published in:Journal of materials chemistry. B, Materials for biology and medicine Materials for biology and medicine, 2019-08, Vol.7 (31), p.4771-4777
Main Authors: Mochida, Mai, Nagai, Yuta, Kumagai, Hiroto, Imai, Hiroaki, Citterio, Daniel, Hiruta, Yuki
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Summary:We developed a biomineral-inspired hybrid material composed of CaCO 3 and an organic polymer as a column packing material for HPLC. This material combines a hierarchical mesoporous structure and the functionality of the polymer. The surface of monodispersed mesoporous CaCO 3 microspheres was modified with poly(maleic acid- alt -1-octadecene) (PMAcO) comprising hydrophobic alkyl chains and anionic carboxylate groups. PMAcO adsorbed onto the surface of CaCO 3 through electrostatic interaction between Ca 2+ sites and carboxylate groups, resulting in an octadecene coated microsphere interface. These microspheres were applied as a HPLC column and exhibited reversed-phase retention behavior in the separation of alkylbenzenes. This column showed high alkaline mobile phase resistance compared with the conventionally applied ODS column packing material. Quantitative analysis of the basic antidepressants clomipramine and imipramine spiked into whole blood was achieved with an alkaline mobile phase, demonstrating the potential of the biomineral-inspired material as a HPLC stationary phase for practical applications in routine analyses of basic drugs requiring alkaline mobile phases. Inspired by egg shells, amphiphilic copolymer-modified monodisperse mesoporous CaCO 3 microspheres were applied as a separation material.
ISSN:2050-750X
2050-7518
DOI:10.1039/c9tb01014a