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http://hdl.handle.net/11375/27989
Title: | A multifaceted approach towards advancing the sterile filtration of therapeutic viruses |
Authors: | Wright, Evan |
Advisor: | Latulippe, David |
Department: | Chemical Engineering |
Keywords: | bioprocessing;viruses;sterile filtration;host cell impurities;microfabrication;nanoparticles |
Publication Date: | 2022 |
Abstract: | Therapeutic viruses are a class of biotherapeutic which have enabled new treatments and medical advances in the areas of vaccines, cancer treatment, gene therapy, and more. In the production and purification of these products, the sterile filtration unit operation is known to have poor yields and contribute to the high cost of the final product, significantly hampering the large-scale production of some therapeutic viruses. Thus, this thesis seeks to explore various aspects of process development and fundamental understanding in the sterile filtration of therapeutic viruses. This thesis explores the mechanisms and membrane properties which govern how bacteria are retained during filtration, and applies these insights to improve the sterile filtration recovery of a therapeutic virus through proper membrane selection. To better understand the factors which cause membrane fouling and loss of virus during sterile filtration, the effect of host cell impurities on filtration performance was investigated. This revealed that small amounts of host cell protein are a major factor in both membrane fouling and reduced virus yield, and that there is a synergistic effect between the virus and the host cell protein adsorbing to the membrane surface. Recognizing that conventional polymeric membranes have many limitations, a novel ultrathin, isoporous, microfabricated silicon nitride membrane was tested for suitability as a sterile filter. Finally, the application of nanoparticles as model virus particles in filtration testing was examined, and a process was developed through which nanoparticles could be fused together to create controlled amounts of particle aggregates, similar to how viruses can be prone to aggregation. The work described here will help enable the development of next generation sterile filtration membranes and provides both insights and methodologies for improving sterile filtration performance. |
URI: | http://hdl.handle.net/11375/27989 |
Appears in Collections: | Open Access Dissertations and Theses |
Files in This Item:
File | Description | Size | Format | |
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Evan Wright - Full thesis Final.pdf | 4.87 MB | Adobe PDF | View/Open |
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