Master Degree / Yüksek Lisans Tezleri
Permanent URI for this collectionhttps://hdl.handle.net/11147/3008
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Master Thesis Investigation of Shell Microstructure of Microbubbles for Diagnostic Ultrasound(Izmir Institute of Technology, 2013) Köse, Derya; Kılıç Özdemir, Sevgi; Kılıç Özdemir, Sevgi; 03.02. Department of Chemical Engineering; 03. Faculty of Engineering; 01. Izmir Institute of TechnologyIn this study we reported the effect of shear stress, protein adhesion, temperature, secondary interactions and gas core on microbubble stability which are the main reasons of microbubble dissolution in body. Air filled DSPC/PEG40St microbubbles were examined under shear stress. Increasing PEG40St molar ratio increased the resistivity microbubbles against shear stress. To investigate effect of emulsifier type, microbubbles were produced by mixing DSPC with DSPE-PEG1000, DSPE-PEG2000 and PEG40St at 5:5 molar ratio and PEG40St microbubbles were more stable since it provide better curvature to microbubble shell due to its shape. Shear stress experiments were also performed at different temperatures. With increasing temperature microbubbles became less stable since van der Waals interactions between shell components decreased. When microbubbles were filled with perfluorocarbon, since its solubility is lower and more hydrophobic than air, the stability of microbubbles against shear stress increased. Protein adhesion to microbubble shell was investigated by Langmuir Blodgett (LB) and Surface Plasmon Resonance techniques. Both techniques showed that, as the PEG40St molar ratio and packing density increased, protein adhesion decreased. Secondary interactions between shell components were examined via LB technique and visualized via Brewster Angle Microscopy. As third component to DSPC/PEG40St mixture, StGly, StNH2, DSPS, DSTAP was added and ternary mixtures were generally miscible. Since StGly and StNH2 has single tail, they cannot provide curvature in bubble surface. DSPS and DSTAP mixtures may be recommended drug delivery.Master Thesis Design and Characterization of Shell Structure of Microbubbles Used in Ultrasound Imaging(Izmir Institute of Technology, 2012) Bölükçü, Elif Şeniz; Kılıç Özdemir, Sevgi; Kılıç Özdemir, Sevgi; 03.02. Department of Chemical Engineering; 03. Faculty of Engineering; 01. Izmir Institute of TechnologyThe main goal of the study is to redesign the microbubble (MB) shell structure and investigate the interactions between the shell components in the mixed monolayers treated as a model for MBs’ shell in order to improve the stability. To examine effects of emulsifier type (DSPC/PEG40 St, DSPC/DSPE-PEGn) and additional components (DSPC/PEG40 St/DSPG, DSPC/PEG40 St/DSPA, DSPC/PEG40 St/DSPE) on stability, molecular interactions and morphological properties, mixtures having various compositions were investigated by Langmuir Blodgett (LB) method and Atomic Force Microscope (AFM) and Brewster Angle Microscope (BAM). For DSPC/PEG40 St monolayers thermodynamically analysis indicated that the attractive forces between the components in the monolayer of 30% PEG40 St were very strong. It was observed that addition of large amount of peg-grafted phospholipids (lipopolymer) increased the attractive forces between molecules in DSPC/DSPE-PEG1000 and DSPC/DSPE-PEG350 monolayers unlike DSPC/DSPE-PEG2000 monolayers. Additionally, the use of different phospholipid as an additional component such as DSPG, DSPE and DSPA in DSPC/PEG40 St mixture signified that intermolecular forces were influenced by the monolayers’ compositions and polar headgroups differences. It was noticed that among the ternary mixtures consisting 70% DSPC, DSPC/PEG40 St/DSPE monolayers exhibited stronger molecular interaction than DSPC/PEG40 St/DSPG and DSPC/PEG40 St/DSPA monolayers while DSPC/PEG40 St/DSPA mixtures showed stronger interaction for mixtures composed of 50% PEG40 St. However, phase separations detected at some regions for these monolayers by BAM and AFM may affect the stability negatively. Therefore, thermodynamically analysis, BAM and AFM results should be evaluated together to assess potential MBs’ shell structures.