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http://hdl.handle.net/11375/24014
Title: | DEVELOPING HYDROGELS WITH SELF-ORGANIZED M13 FILAMENTOUS PHAGE |
Authors: | Peivandi, Azadeh |
Advisor: | Hosseini-Doust, Zeinab |
Department: | Chemical Engineering |
Keywords: | Hydrogels, M13 phage |
Publication Date: | 2018 |
Abstract: | Bacteriophages (phages) are bacterial viruses. Phages offer remarkable diversity and can be found in many shapes and sizes; however, what they all have in common is that they are made of protein nano-shells that encase their genome (DNA or RNA). In other words, phages are proteinous bionanoparticles. In this work, we use the filamentous phage M13. M13 is a simple virus with a high aspect ratio. It has 11 genes and only 5 structural proteins. The phage filament is almost entirely made of 2700 copies of pVIII, the major coat protein, and is capped off on one end by five copies each of the proteins pIII and pVI, while the opposite end displays five copies each of the proteins pVII and pIX. M13 phage can be genetically engineered to display certain peptides with affinity toward cancer cells, specific tissue, or even minerals and polymers. These filaments can further self-organize to form liquid crystals at high concentrations. All these properties make M13 a unique building block for the bottom up synthesis of advanced bioactive material. The objective of my proposed research is to develop hydrogels using M13 phage. Hydrogels can absorb large quantities of water without dissolving. They mark a breakthrough in the field of biomaterials, owing to their high water content, porosity and soft consistency. I crosslinked M13 at liquid crystalline concentrations using glutaraldehyde. The resulting hydrogels were characterized for swelling and mechanical properties. These hydrogels exhibited self-healing and autofluorescence properties. In addition, I demonstrated that M13 can from self-healing hydrogels at lower concentrations by adding the small globular protein, BSA. The developed M13 hydrogels mark the first step in the development of bioactive hydrogels that could be utilized to direct cell destiny and genuinely mimic the natural tissue. |
URI: | http://hdl.handle.net/11375/24014 |
Appears in Collections: | Open Access Dissertations and Theses |
Files in This Item:
File | Description | Size | Format | |
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Peivandi_Azadeh_Finalsubmission2018Dec_M.Sc..pdf | 3.56 MB | Adobe PDF | View/Open |
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