Absorbance Detection in Multireflection Microfluidic Channels Using a Commercial Microplate Reader System

Absorbance detection is often prohibited in microfluidic channels due to the limited optical path length available in these systems. However, this optical distance may be significantly increased by guiding the probing light beam along the channel length via multiple reflections by patterned metallic surfaces. In this work, we demonstrate enhanced absorbance detection in glass microfluidic channels using a commercial microplate reader based on this principle, yielding detection limits comparable to that measured on standard microwell plates. This improvement in detectability was realized through careful optimization of the mirror lengths and locations combined with the appropriate design of a microchip holder to suitably position the microchannels in the microplate reader. Additionally, it was determined that the angle by which our device was tilted relative to the horizontal plane played an important role in this optimization. For an optimum choice of parameters accessible with our design, the sensitivity of our absorbance measurements in a 30 mu m-deep channel was improved by as much as 52-fold, raising this quantity to about 84% of the corresponding value realized for 75 mu L samples placed within 7 mm i.d. standard cylindrical microwells. Quantitative ELISAs employing the absorbance detection method were demonstrated on the noted multireflection microchip device for assessing West Nile viral IgM antibody levels in human serum samples yielding analyte detection limits comparable to that measured on standard microwell plates.