论文信息 - Integration of microfluidic and microoptical elements using a single-mask photolithographic step

Integration of microfluidic and microoptical elements using a single-mask photolithographic step

Abstract We present a design and process to fabricate an integrated microfluidic/microoptical device—the microfluidic optical waveguide sensor (“μFlOWs”). Optical waveguides and fluidic microchannels have been defined using only a single photolithographic masking step. This integration has been demonstrated with three device types: (A) a hybrid structure with embedded SU-8 waveguides and polydimethylsiloxane (PDMS) channels; (B) a structure using only SU-8 for both the waveguides and microchannel walls and (C) a structure as a modification to the all-SU-8 structure. Testing has demonstrated the ability of the waveguides to transmit light to and receive light from the microchannels, which contain a fluorescent dye that emits upon laser excitation. This type of strategy can find effective use in a variety of bio-assay experiments.

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