There are two parts to this thesis: one is to separate different DNA-Ag nanoclusters (NCs) by combining capillary electrophoresis technique with laser-induced fluorescence detection system (CE-LIF); another is to apply fluorescent Cu/Ag NCs to measure H2O2 and glucose concentration in the aqueous solution by quenching effect. At first, forming DNA-Ag NCs from three kinds of single DNA fragments with different sequences and lengths (24, 32, 40 bases), which are then subsequently separated by using capillary electrophoresis. Under optimal conditions, we were able to separate the above mentioned DNA-Ag NCs in six minutes in the presence of EOF. The fact that SDS increases separation efficiency greatly might be attributed to a change in surface electron distribution of DNA-Ag NCs and decreasing DNA-Ag NCs and PEO attachment to capillary wall. We also developed a simple fluorescent sensor approach for the detection of H2O2 and glucose using a DNA-Cu/Ag NCs probe. Under the optimal condition, the DNA-Cu/Ag NCs probe was highly sensitive toward H2O2 ( LOD~0.5 μM ) and the linear range was found to be between 1 to 100 μM. Moreover, the production of H2O2 in the glucose solution was owing to the presence of glucose oxidase (GOx). DNA-Cu/Ag NCs probe can be used to detect glucose concentration with an LOD of 15 μM. Finally, we used it to analyze blood glucose as 4.58 (± 0.32) mM.