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Manufacturing of agarose-based chromatographic adsorbents with controlled pore and particle size

Ioannidis, Nicolas; Pacek, Andrzej W.; Bowen, James and Zhang, Zhibing (2011). Manufacturing of agarose-based chromatographic adsorbents with controlled pore and particle size. In: 69th Annual Technical Conference of the Society of Plastics Engineers 2011, pp. 1025–1031.

URL: https://www.academia.edu/9828584/Manufacturing_of_...
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Abstract

The effect of ionic strength of agarose solution and quenching temperature of the emulsion on the structure and mechanical strength of agarose-based chromatographic adsorbents was investigated. Solutions of agarose containing different amounts of NaCl were emulsified at elevated temperature in mineral oil using a high-shear mixer. The hot emulsion was quenched at different temperatures leading to the gelation of agarose and formation of soft particles. Analysis of Atomic Force Microscopy (AFM) images of particle surfaces shows that pore size of particles increases with ionic strength and/or high quenching temperature. Additionally it has been found that the compressive strength of particles measured by micromanipulation also increases with ionic strength of the emulsion and/or high quenching temperature but these two parameters have no significant effect on the resulting particle size and particle size distribution. Results from both characterization methods were compared with Sepharose 4B, a commercial agarose-based adsorbent. This is the first report examining the effect of ionic strength and cooling conditions on the microstructure of micron-sized agarose beads for bioseparation.

Item Type: Conference or Workshop Item
Copyright Holders: 2011 Society of Petroleum Engineers
ISBN: 1-61782-960-9, 978-1-61782-960-4
Keywords: chromatography; atomic force microscopy; adsorbents; particle technology; agarose hydrogel
Academic Unit/School: Faculty of Science, Technology, Engineering and Mathematics (STEM) > Engineering and Innovation
Faculty of Science, Technology, Engineering and Mathematics (STEM)
Item ID: 43416
Depositing User: James Bowen
Date Deposited: 18 Jun 2015 08:19
Last Modified: 10 Nov 2016 17:18
URI: http://oro.open.ac.uk/id/eprint/43416
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