Master Degree / Yüksek Lisans Tezleri
Permanent URI for this collectionhttps://hdl.handle.net/11147/3008
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Master Thesis Development of Keratin Based Hydrogel Systems(Izmir Institute of Technology, 2022) Yalçın Göl, Damla; Top, AybenIn this study, keratin proteins from Merino sheep wool were obtained via oxidative extraction (Chapter 2), sulfitolysis extraction (Chapter 3) and sulfitolysis with reductive extraction methods (Chapter 4). Keratin proteins were characterized XRD and FTIR spectroscopy and thermal analysis. In the SDS-PAGE gel results of the keratins diffusive protein bands between ~23 kDa and >170 kDa and a discrete band at about 12 kDa were observed confirming highly polydisperse nature of the protein samples. Then, keratin-based hydrogel systems were obtained via different methodologies. In Chapter 2, oxidized keratins (keratoses) were crosslinked with THPC to form keratose hydrogels. Effect of the amount of the crosslinking agent on the viscoelastic, swelling, and morphological properties of hydrogels was investigated. In Chapter 3, the keratin hydrogels were obtained via reformation of disulfide bridge and self-assembly of the keratin chains. In Chapter 4, keratins reduced with DTT were crosslinked with 2000 Da PEG-(C2H4-mal)2 and 6000 Da PEG-(C2H4-mal)2 to prepare PEG-hydrogels. Storage moduli of the hydrogels were obtained in the range of 63 ± 22 and 2613 ± 254 Pa and were shown to be tuned by the amount and chain length of the crosslinker. The highest swelling ratios were obtained for the THPC crosslinked hydrogels whereas the highest pore size was observed in PEG-keratin hydrogels. Cytocompatibility of the keratin based hydrogel systems was confirmed using L929 mouse fibroblast cells by applying CCK-8 tests. Of these hydrogels, PEG-keratin hydrogels were found to support cell proliferation with a higher rate than empty TCPS wells up to 4 days. These results demonstrate that low-cost keratin-based hydrogels can be used in a variety of biomedical applications, such as drug delivery systems for cancer therapy, and scaffolds in wound healing and soft tissue engineering.Master Thesis Hydrogels and Self-Assemled Nanostructures Based on Wool Keratose(Izmir Institute of Technology, 2017) Pakkaner, Efecan; Top, AybenIn this study, water soluble keratose proteins were extracted from “Ovis aries” wool using peracetic acid oxidation with a yield of 35 ± 5 %. Wool samples and the extracted keratose proteins were characterized by using FT-IR, XRD, SEM and TGA techniques. α-keratose fractions (MW = 43-53 kDa) along with cleaved fragments of α-keratoses with molecular weights between 23 and 33 kDa were identified in the extracted protein mixture using SDS-PAGE analysis. DLS and AFM experiments indicated self-assembled globular nanoparticles with diameters of 20-40 nm formed at 5 and 10 mg/ml keratose concentrations. On the other hand, at 10 % w/v keratose concentration interconnected keratose hydrogels with pore sizes of 6 ± 4 and 7 ± 4 μm were obtained upon incubation at 37 and 50 °C, respectively. Storage moduli (G’) of these physical hydrogels were increased from ~100 to ~1000 Pa, as gelation temperature was increased from 37 to 50 °C. Hydrogels were also obtained at 7.5 % w/v keratose concentration by the addition of a crosslinker, THPC. Amine group:crosslinker ratio was used as 1:1, 1:2 and 1:4. As the amount of crosslinker increased, network transformed from fibrous to more planar structures exhibiting a significant decrease in average pore size from 24 to 11 μm. G’ values of the crosslinked hydrogels were obtained between ~1 and ~5 kPa tuned by the crosslinking amount. Cell interaction properties of a select physical hydrogel prepared at 37 °C was tested using CCK-8 assay. It was observed that the keratose hydrogel supported L929 mouse fibroblast cell proliferation as much as collagen, which suggests that these keratose hydrogels can be promising candidates in soft tissue engineering applications.