The major and ultimate aim of metabolomics is to obtain an answer to a specific biological or clinical question. For that, many strategies have been applied in this field, including NMR and MS... Show moreThe major and ultimate aim of metabolomics is to obtain an answer to a specific biological or clinical question. For that, many strategies have been applied in this field, including NMR and MS-based approaches. CE-MS is one of the techniques in this field but remains underappreciated because of issues such as compromised sensitivity and poor reproducibility. In this thesis, we proposed standardized protocols for CE-MS studies using a sheathless interface and applied them in the metabolic analysis of ultra-small biological samples, such as low numbers of HepG2 cells. Another CE-MS technique used in this thesis is the traditional sheath liquid CE-MS, and it was successfully used in the metabolic profiling of plasma samples. We also introduced CE-MS with both interfaces in the field of nanosciences with our efforts in revealing the adsorption characteristics of polar metabolites to the surface of nanomaterials. This work clearly demonstrates that CE-MS can be reliably performed for metabolomics studies with acceptable repeatability. The use of sheathless CE-MS interface enables us to have in-depth profiling for ultra-small samples, and may become a powerful tool in the emerging field of single-cell analysis. Show less
This thesis is a collection of experimental attempts to enhance photoluminescence of fluorescent molecules and quantum dots with single gold nanorods (GNRs) and relevant applications. Special... Show moreThis thesis is a collection of experimental attempts to enhance photoluminescence of fluorescent molecules and quantum dots with single gold nanorods (GNRs) and relevant applications. Special attention is focused on the interactions between single emitters and GNRs. The idea is to increase the emission of weak emitters by the excellent optical properties of GNRs so that weak light emitters will then be bright enough to be detected and studied individually. We can thus generalize single-molecule fluorescence spectroscopy to weakly emitting species which are currently undetectable by conventional single-molecule spectroscopy. The research is important for extending the scope of single-molecule spectroscopy, which is a powerful technique for understanding the dynamic behaviors at the nanometer scale in biological systems and other materials. Show less
