林震煌張喦升2019-09-042007-6-302019-09-042005http://etds.lib.ntnu.edu.tw/cgi-bin/gs32/gsweb.cgi?o=dstdcdr&s=id=%22G0069142001%22.&%22.id.&http://rportal.lib.ntnu.edu.tw:80/handle/20.500.12235/99874本篇實驗應用紫外光發光二極體(UV-LED)誘導螢光搭配毛細管電泳層析技術,並結合線上濃縮技術對於螢光性(核黃素)及非螢光性(色氨酸)進行偵測。本實驗所使用的UV-LED發光波長在380 nm,功率約在2 mW。在偵測核黃素的部分使用速度變化誘導聚焦(Velocity-Difference Induced Focusing, V-DIF)來進行實驗,成功將偵測極限由原來僅使用微胞電動電泳層析的200ppb提高到3~7ppb。在色氨酸的偵測部分,則利用螢光試劑衍生色氨酸,使其適合UV-LED的激發,並利用掃集技術(sweeping)將偵測極限從原來使用微胞電動電泳層析的1.5ppm提高至3ppb。在真實樣品的應用上分別偵測啤酒裡面的核黃素,以及尿液、牛奶裡面的色氨酸均可以成功快速達到定性及定量的結果。Abstract The application of an ultraviolet (UV) light emitting diode (LED) to on-line sample concentration/fluorescence detection in capillary electrophoresis (CE) is described. The utility of UV-LED (peak emission wavelength at 380 nm, ~ 2 mW) for fluorescence detection is demonstrated by examining a naturally fluorescent (riboflavin) and a non-fluorescent compound (tryptophan), respectively. The detection limit for riboflavin was determined to be 0.2 ppm by the normal MEKC mode and this was improved to 3 ~ 7 ppb when a dynamic pH-junction techniques were applied. On the other hand, the detection limit of the tryptophan derivative was determined to be 1.5 ppm using the MEKC mode and this was improved to 3 ppb when the sweeping-MEKC mode was applied. In an analysis of an actual sample, the concentrations of riboflavin and tryptophan in beer and urine/milk samples were determined, respectively.毛細管電泳發光二極體紫外光發光二極體誘導螢光偵測法結合毛細管電泳/線上濃縮技術之開發與應用