Microfluidic Development of Bubble-templated Microstructured Materials
This thesis presented a microfluidic preparation of bubbles-templated micro-size materials. In particular, this thesis focused on the microfluidic formation and dissolution of CO2 bubbles. First, this thesis described pH-regulated behaviours of CO2 bubbles in the microfluidic channel. This method op...
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ndltd-LACETR-oai-collectionscanada.gc.ca-OTU.1807-263772013-04-17T04:18:44ZMicrofluidic Development of Bubble-templated Microstructured MaterialsPark, Jai Ilmicrofluidicsmicrobubblescarbon dioxidecolloidspickering emulsionultrasound imagingmagnetic resonance imagingnanoparticles04950485This thesis presented a microfluidic preparation of bubbles-templated micro-size materials. In particular, this thesis focused on the microfluidic formation and dissolution of CO2 bubbles. First, this thesis described pH-regulated behaviours of CO2 bubbles in the microfluidic channel. This method opened a new way to generate small (<10 µm in diameter) with a narrow size distribution (CV<5%). Second, the microfluidic dissolution of CO2 bubbles possessed the important feature: the local change of pH on the bubble surface. This allowed us to encapsulate the bubbles with various colloidal particles. The bubbles coated with particles showed a high stability against coalescences and Ostwald ripening. The dimensions and shapes of bubbles with a shell of colloidal particle were manipulated by the hydrodynamic and chemical means, respectively. Third, we proposed a microfluidic method for the generation of small and stable bubbles coated with a lysozyme-alginate shell. The local pH decrease at the periphery of CO2 bubbles led to the electrostatic attraction between lysozyme on the bubble surface and alginate in the continuous phase. This produced the bubbles with a shell of biopolymers, which gave a long-term stability (up to a month, at least) against the dissolution and coalescence. Fourth, we presented a single-step method to functionalize bubbles with a variety of nanoparticles. The bubbles showed the corresponding properties of nanoparticles on their surface. Further, we explored the potential applications of these bubbles as contrast agents in ultrasound and magnetic resonance imaging.Kumacheva, Eugenia2010-112011-02-23T20:35:59ZNO_RESTRICTION2011-02-23T20:35:59Z2011-02-23T20:35:59ZThesishttp://hdl.handle.net/1807/26377en_ca |
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microfluidics microbubbles carbon dioxide colloids pickering emulsion ultrasound imaging magnetic resonance imaging nanoparticles 0495 0485 |
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microfluidics microbubbles carbon dioxide colloids pickering emulsion ultrasound imaging magnetic resonance imaging nanoparticles 0495 0485 Park, Jai Il Microfluidic Development of Bubble-templated Microstructured Materials |
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This thesis presented a microfluidic preparation of bubbles-templated micro-size materials. In particular, this thesis focused on the microfluidic formation and dissolution of CO2 bubbles. First, this thesis described pH-regulated behaviours of CO2 bubbles in the microfluidic channel. This method opened a new way to generate small (<10 µm in diameter) with a narrow size distribution (CV<5%). Second, the microfluidic dissolution of CO2 bubbles possessed the important feature: the local change of pH on the bubble surface. This allowed us to encapsulate the bubbles with various colloidal particles. The bubbles coated with particles showed a high stability against coalescences and Ostwald ripening. The dimensions and shapes of bubbles with a shell of colloidal particle were manipulated by the hydrodynamic and chemical means, respectively. Third, we proposed a microfluidic method for the generation of small and stable bubbles coated with a lysozyme-alginate shell. The local pH decrease at the periphery of CO2 bubbles led to the electrostatic attraction between lysozyme on the bubble surface and alginate in the continuous phase. This produced the bubbles with a shell of biopolymers, which gave a long-term stability (up to a month, at least) against the dissolution and coalescence. Fourth, we presented a single-step method to functionalize bubbles with a variety of nanoparticles. The bubbles showed the corresponding properties of nanoparticles on their surface. Further, we explored the potential applications of these bubbles as contrast agents in ultrasound and magnetic resonance imaging. |
author2 |
Kumacheva, Eugenia |
author_facet |
Kumacheva, Eugenia Park, Jai Il |
author |
Park, Jai Il |
author_sort |
Park, Jai Il |
title |
Microfluidic Development of Bubble-templated Microstructured Materials |
title_short |
Microfluidic Development of Bubble-templated Microstructured Materials |
title_full |
Microfluidic Development of Bubble-templated Microstructured Materials |
title_fullStr |
Microfluidic Development of Bubble-templated Microstructured Materials |
title_full_unstemmed |
Microfluidic Development of Bubble-templated Microstructured Materials |
title_sort |
microfluidic development of bubble-templated microstructured materials |
publishDate |
2010 |
url |
http://hdl.handle.net/1807/26377 |
work_keys_str_mv |
AT parkjaiil microfluidicdevelopmentofbubbletemplatedmicrostructuredmaterials |
_version_ |
1716580463650275328 |