Browsing by Subject "PEGDA"
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Item Effect of network structure modifications on the light gas transport properties of cross-linked poly(ethylene oxide) membranes(2009-05) Kusuma, Victor Armanda; Freeman, B. D. (Benny D.); Yacamán, M. JoséCross-linked poly(ethylene oxide) (XLPEO) based on poly(ethylene glycol) diacrylate (PEGDA) is an amorphous rubbery material with potential applications for carbon dioxide removal from mixtures with light gases such as methane, hydrogen, oxygen and nitrogen. Changing the polymer network structure of XLPEO through copolymerization has previously been shown to influence gas transport properties, which correlated with fractional free volume according to the Cohen-Turnbull model. This project explores strategic modifications of the cross-linked polymer structure and their effect on the chemical, physical and gas transport properties with an aim to develop rational, molecular-based design rules for tailoring separation performance. Experimental results from calorimetric and dynamic thermal analysis studies are presented, along with pure gas permeability and solubility obtained at 35°C. Incorporation of dangling side chains by copolymerization of PEGDA with methoxy-terminated poly(ethylene glycol) methyl ether acrylate, n=8 (PEGMEA) was previously shown to be effective in increasing fractional free volume of XLPEO through the opening of local free volume elements, which in turn increased CO₂ permeability. Through a comparative study ofshort chain analogs to these co-monomers, incorporation of an ethoxy-terminated co-monomer was shown to be more effective than a comparable methoxy-terminated co-monomer in increasing gas permeability. For instance, copolymerization of PEGDA with 71 wt% ethoxy-terminated diethylene glycol ethyl ether acrylate increased CO₂ permeability from 110 barrer to 320 barrer. Gas permeability increase was not observed when hydroxy or phenoxy-terminated pendants were introduced, which was attributed to reduction in chain mobility due to increased inter-chain chemical interactions or steric restrictions, respectively. Based on these results, incorporation of a co-monomer containing a bulky non-polar terminal group, tris-(trimethylsiloxy)silyl, was examined in order to further increase gas permeability. Addition of 80 wt% TRIS-A co-monomer increased CO₂ permeability of cross-linked PEGDA to 800 barrer. However, the resulting changes in chemical character of the copolymer reduced CO₂/light gas selectivity, even as gas permeability increased. The effect of incorporating a bulky, stiff functional group in the cross-linker chain was studied using cross-linked bisphenol-A ethoxylate diacrylate, which showed 40% increase in permeability compared to cross-linked PEGDA. This study affirmed the importance of polymer chain interaction, in addition to free volume, in determining the gas transport properties of the polymer.Item Enhanced functionality of monodispersed polymeric nanocarriers in medicine(2012-08) Singh, Vikramjit; Sreenivasan, S. V.Polymeric monodispersed nanocarriers with controlled shape and size have been fabricated in the literature primarily using top down processes such as imprint lithography. In this dissertation, the geometric and material property limits of imprint based techniques have been studied. The resulting insight has led to the creation of new processes that significantly extend the limits of imprint processes in several ways: (i) Ability to print nanocarriers with ultra-soft biomaterials (<1MPa modulus); (ii) Sub-50nm diameter cylindrical particles with >3:1 aspect ratio with >5x enhanced wafer yield; (iii) Creation of reentrant barrel shapes that have the potential to be valuable in cellular uptake, such shapes being significant as they lead to fundamental demolding challenges in prior imprint processes; and (iv) Multi-layer nanocarriers which can potentially provide sophisticated functionality such as tailored release kinetics of one or more drugs. By understanding the requirements of bio-functional nanocarriers and related manufacturing constraints, a previously explored Bio Jet and Flash Imprint Lithography (Bio J-FIL) process was refined to perform successful imprints and improve the nanocarrier fabrication scalability. Next, two new fabrication processes have been developed. The first process is called Decoupled Functional Imprint Lithography (D-FIL) which allows fabrication of ultra-soft bio-functional materials (modulus of <1 MPa), challenging sizes (sub-50nm diameter cylinders with aspect ratio > 3:1), and reentrant barrel shapes. The second decoupled process, Dual Removable Layer Lithography (DRLL), has been developed to specifically create multi-layered cylindrical nanocarriers. Nanocarriers fabricated with D-FIL and DRLL process have been shown to chemically bind with an imaging agent, and model anti-cancer drugs. Drug (siRNA) retention (>90% over 9 days) and stimuli triggered release studies were performed on sub-100nm cylindrical PEGDA nanocarriers. It was found that these nanocarriers show accelerated triggered drug release when exposed to a hydrolase, Cathepsin B. While the exact mechanisms causing the triggered release are not fully understood, a few possible explanations are provided based on the experiments reported. Finally, the D-FIL, the DRLL, and the refined Bio J-FIL processes have been successfully demonstrated at the prototype scale as well as at the pilot scale in collaboration with an industrial partner, Molecular Imprints Inc.