Polystyrene-co-Divinylbenzene PolyHIPE Monoliths in 1.0 mm Column Formats for Liquid Chromatography

Choudhury, Sidratul; Fitzhenry, Laurence; White, Blánaid; Connolly, Damian

doi:10.3390/ma9030212

Cited by 11 publications

(19 citation statements)

References 54 publications

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“…Besides traditional monoliths formed by in situ polymerization of a mixture consisting of functional monomers, crosslinker, initiator and porogens, macroporous monoliths can be prepared by high internal phase emulsion (HIPE) polymerization technique. In the last case, polymerization of an emulsion with an internal phase volume fraction higher than 74% provides the formation of a porous polymer monolith with a network of large pores (up to 10 µm) pierced by smaller ones (~1-2 µm) [84,85]. For the water-in-oil emulsions water acts as the porogen and is dispersed in the organic phase, which contains polymerizable monomers and finally forms "continuous phase".…”

Section: Polyhipe Monolithic Layersmentioning

confidence: 99%

Macroporous Polymer Monoliths in Thin Layer Format

2021

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Nowadays, macroporous polymer monoliths represent widely used stationary phases for a number of dynamic interphase mass exchange processes such as high-performance liquid chromatography, gas chromatography, electrochromatography, solid-phase extraction, and flow-through solid-state biocatalysis. This review represents the first summary in the field of current achievements on the preparation of macroporous polymer monolithic layers, as well as their application as solid phases for thin-layer chromatography and different kinds of microarray.

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Section: Polyhipe Monolithic Layersmentioning

confidence: 99%

Macroporous Polymer Monoliths in Thin Layer Format

2021

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“…Various porous materials as stationary phases have been widely used and exhibited excellent performance in chromatographic separation [3]. PolyHIPEs as stationary phase exhibited higher permeability in comparison with other porous materials, such as organic polymer, inorganic zeolites, and MOFs, and thus have been applied in chromatographic separation such as CEC [73, 90, 91], TLC [74], nano‐liquid chromatography (nano‐LC) [92], and HPLC [76, 93, 94]. The chromatographic separation performance of polyHIPE monoliths mainly depended on the molecular sieving effect, van der Waals interactions, and the special group interactions (e.g., π‐π interaction, hydrogen‐bonding interactions), therefore, the pore size and distribution of polyHIPEs should be carefully controlled in confined spaces, and the higher shearing stress in HIPEs preparation was deemed to be better for the resulting polyHIPEs, providing a narrower void size distribution and improved homogeneity [95].…”

Section: Separation Strategiesmentioning

confidence: 99%

“…Although the overall separation capacity of the produced columns was low, the polyHIPE coatings improved the peak shape of alkylbenzenes, decreased the total run time, and enhanced the peak symmetries relative to comparable unmodified open‐tubular columns. For preparation of polyHIPE‐based HPLC column, STY/DVB polyHIPEs was covalently attached to the walls of the silcosteel column housing by prior wall modification with 3‐(trimethoxysilyl) propyl methacrylate, and the resulting polyHIPE‐based HPLC column could completely separate five alkylbenzenes within 30 min and withstand operating backpressures in excess of 200 bar at a flow rate of 1.2 mL/min [93]. As nano‐LC column stationary phase, amphiphilic polyHIPEs exhibited excellent chromatographic performance for selective separation of benzene derivatives (toluene, ethylbenzene, propylbenzene, butylbenzene, pentylbenzene) (see Fig.…”

Section: Separation Applicationsmentioning

confidence: 99%

Recent advances in separation applications of polymerized high internal phase emulsions

Luo

Huang

Liu

et al. 2020

J of Separation Science

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Polymerized high internal phase emulsions as highly porous adsorption materials have received increasing attention and wide applications in separation science in recent years due to their remarkable merits such as highly interconnected porosity, high permeability, good thermal and chemical stability, and tailorable chemistry. In this review, we attempt to introduce some strategies to utilize polymerized high internal phase emulsions for separation science, and highlight the recent advances made in the applications of polymerized high internal phase emulsions for diverse separation of small organic molecules, carbon dioxide, metal ions, proteins, and other interesting targets. Potential challenges and future perspectives for polymerized high internal phase emulsion research in the field of separation science are also speculated at the end of this review.

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“…4, the linear dependence of monolith column backpressure on flowrate shows good mechanical stability to reached R 2 = 0.9971. In addition, it also means the monolith column has high sustainibility to be used frequently [18].…”

Section: Figure 3 Morphology Of Monolith At 10000x Magnificationmentioning

confidence: 99%

Preparation and utilization of monolithic column as HPLC stationary phase for alkyl benzene separation with low mobile phase usage

Angga¹,

Septiana²,

Amalia³

et al. 2018

AIP Conference Proceedings

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One of the long-known separation methods is chromatography, such as high performance liquid chromatography (HPLC). This separation essentially uses column containing particle-packed which generates high flow-resistance and low mass transfer. As matter of fact, it has an impact to high amount mobile phase usage. Meanwhile, organic polymer monolithic column has been widely used as alternative due to its high mass transfer. In addition, the resulting column has stability over wide pH range, high temperature, shrinkage and swelling of the reservoir. The aim of this research was to produce monolithic column which able to utilized for separation with low amount of mobile phase usage. Preparation of monolithic column begins with pretreatment of polyetereterketone tubing column inner wall. It conducted by activating the inner wall with H 2 SO 4 49% (v/v), followed by vinylization with glycidyl methacrylate. Furthermore, pretreated column filled by polymer mixture consisted of 30 wt% of monomers glycidyl methacrylate:trimetilolpropane trimethacrylate 4:1 (w/v), 70 wt% of pore-forming agents (1-propanol/1,4-butanediol/water 7:4:1 w/v), and azoisobutyronitrile 1 wt% of total monomers amount. The polymerization conducted at 60°C for 12 h. Produced column connected to HPLC then applied to separate toluene and amylbenzene. The result shows both compounds successfully n flow rate of acetonitrile:water (75:25) at 84 and 132 min respectively.

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Polystyrene-co-Divinylbenzene PolyHIPE Monoliths in 1.0 mm Column Formats for Liquid Chromatography

Cited by 11 publications

References 54 publications

Macroporous Polymer Monoliths in Thin Layer Format

Macroporous Polymer Monoliths in Thin Layer Format

Recent advances in separation applications of polymerized high internal phase emulsions

Preparation and utilization of monolithic column as HPLC stationary phase for alkyl benzene separation with low mobile phase usage

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