Functionalized membranes for membrane chromatography

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Date
2011
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University of Alabama Libraries
Abstract

The focus of this thesis is synthesis and quantification of homopolymer and block copolymer grafts and understanding controlled polymer growth. The homopolymer and block copolymer grafts were synthesized through sequential cationic polymerization of styrene and substituted styrene monomers chloromethylstyrene (CMS) and 4-ethoxystyrene (ES) in the pores of microfiltration polyethersulfone (PES) membrane. Polymer growth aspects like kinetics of reaction, amount of monomer reacted, ion-exchange capacity (IEC), and graft length were studied with respect to initiator contact time and monomer feed concentration. Functionalization of the microfiltration membrane was achieved by a two step procedure. The first step was to introduce sulfonic acid initiator sites by mild sulfonation with 0.5N H2SO4. This was followed by cycling through each type of monomer solution (styrene and substituted styrenes). Successful introduction of homopolymer and block copolymer grafts was confirmed by material balances on the monomer/toluene permeate solutions. Analytical techniques used for quantification of polymer grafting include UV-Visible spectroscopy, gas chromatography and atomic absorption. The functionalized membrane showed a steep decrease in membrane permeability compared to the raw membrane indicating the presence of polymeric chains in the membrane flow path. Functionalized membranes prepared by this method have as many as 125 repeat units per chain. Given the initiator concentration, this equates to an IEC of 4.9 meq/g, indicating high dynamic and equilibrium binding capacity. Pseudo-first-order kinetic expression correlated well with the experimental data for each monomer reacted. At lower initiator surface density, graft length and IEC were impacted by both monomer feed concentration and initiator contact time. However, for higher initiator surface density, monomer feed concentration parameter dominates. Block copolymer formation is the first step to synthesizing an analog of the phenylalanine/tyrosine dipeptide structure in protein A, which is shown in literature for selective adsorption of immunoglobulin G (IgG). This work will lead to further development of functionalized membranes as membrane adsorbers for high throughput production of monoclonal antibodies for new cancer therapies. In addition, it will lead to discoveries in sequential polymerization to generate customized structures and design of synthetic affinity ligands.

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Electronic Thesis or Dissertation
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Chemical engineering
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