Title :
Design and fabrication of a multianalyte-capable optical biosensor using a multiphysics approach
Author :
Chang-Yen, D.A. ; Gale, B.K.
Author_Institution :
Dept. of Mech. Eng., Utah Univ., Salt Lake City, UT, USA
Abstract :
An evanescent-wave biosensor was designed and fabricated using simple and robust microfabrication technology. The significance of the sensor is the design method, in which a multiphysical approach is used to draw from much broader field than is customary for these sensor types. The sensor uses a microscale NOA61 optical waveguide that is surface-altered with a custom chemical modification process, coupled with modified self-assembly of a fluorescent dye and enzyme. To interface the analyte with the waveguide surface, a multilayer PDMS fluidic mold is designed to fit over the waveguide. Interfacing of both optics and fluidics are achieved using specifically-designed couplings. The entire device has been successfully fabricated and assembled, with preliminary analyte response testing completed.
Keywords :
biosensors; chemical analysis; fibre optic sensors; microfluidics; optical fibre couplers; polymer films; self-assembly; chemical modification process; enzyme; evanescent-wave biosensor design; fluorescent dye; microfabrication technology; microscale NOA61 optical waveguide; multianalyte-capable optical biosensor fabrication; multilayer PDMS fluidic mold; multiphysics approach; self-assembly; specifically-designed couplings; Biomedical optical imaging; Biosensors; Chemical and biological sensors; Optical design; Optical device fabrication; Optical sensors; Optical surface waves; Optical waveguides; Surface fitting; Surface waves; Multiphysical; biosensor; design;
Conference_Titel :
Microtechnology in Medicine and Biology, 2005. 3rd IEEE/EMBS Special Topic Conference on
Print_ISBN :
0-7803-8711-2
DOI :
10.1109/MMB.2005.1548462
