Title :
Integrated sensor design using ion channels inserted into lipid bilayer membranes
Author :
Goryll, Michael ; Wilk, Seth ; Laws, Gerard M. ; Goodnick, Stephen M. ; Thornton, Trevor J. ; Saraniti, Marco ; Tang, John M. ; Eisenberg, Robert S.
Author_Institution :
Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ, USA
Abstract :
In this paper, we present an approach towards a biosensor based on the gating action of ion channel proteins integrated on a silicon chip using planar microfabrication technology. The ion channels are inserted into lipid bilayer membranes which are supported across apertures in the wafer. The use of deep silicon reactive ion etching allows fast and flexible fabrication of these apertures in the range of 150 μm diameter with the potential for future downscaling. A plasma-deposited surface modification layer was introduced to increase the hydrophobicity of the sample and allow reproducible bilayer formation with gigaohm seal resistances. Studies on patterned planar Ag/AgCl electrodes show a good longterm stability of the Nernst potential and an easy integration with the microfabricated aperture.
Keywords :
biomembrane transport; biosensors; elemental semiconductors; lipid bilayers; microsensors; molecular biophysics; plasma deposited coatings; proteins; silicon; silver; silver compounds; sputter etching; thermomagnetic effects; 150 micron; Ag-AgCl; Nernst potential; Si; biosensor; deep silicon reactive ion etching; gigaohm seal resistances; hydrophobicity; integrated sensor design; ion channel proteins; lipid bilayer membranes; microfabricated wafer aperture; planar Ag-AgCl electrodes; planar microfabrication technology; plasma deposited surface modification layer; silicon chip; Apertures; Biomembranes; Biosensors; Etching; Fabrication; Lipidomics; Plasma applications; Plasma stability; Proteins; Silicon;
Conference_Titel :
Nanotechnology, 2004. 4th IEEE Conference on
Print_ISBN :
0-7803-8536-5
DOI :
10.1109/NANO.2004.1392332
