Nanogap dielectric spectroscopy for aptamer-based protein detection
Document Type
Article
Publication Date
2-17-2010
Abstract
Among the various label-free methods for monitoring biomolecular interactions, capacitive sensors stand out due to their simple instrumentation and compatibility with multiplex formats. However, electrode polarization due to ion gradient formation and noise from solution conductance limited early dielectric spectroscopic measurements to high frequencies only, which in turn limited their sensitivity to biomolecular interactions, as the applied excitation signals were too fast for the charged macromolecules to respond. To minimize electrode polarization effects, capacitive sensors with 20 nm electrode separation were fabricated using silicon dioxide sacrificial layer techniques. The nanoscale separation of the capacitive electrodes in the sensor results in an enhanced overlapping of electrical double layers, and apparently a more ordered "ice-like" water structure. Such effects in turn reduce low frequency contributions from bulk sample resistance and from electrode polarization, and thus markedly enhance sensitivity toward biomolecular interactions. Using these nanogap capacitive sensors, highly sensitive, label-free aptamer-based detection of protein molecules is achieved. © 2010 by the Biophysical Society.
Identifier
77249084137 (Scopus)
Publication Title
Biophysical Journal
External Full Text Location
https://doi.org/10.1016/j.bpj.2009.10.042
e-ISSN
15420086
ISSN
00063495
First Page
724
Last Page
732
Issue
4
Volume
98
Recommended Citation
Mannoor, Manu Sebastian; James, Teena; Ivanov, Dentcho V.; Beadling, Les; and Braunlin, William, "Nanogap dielectric spectroscopy for aptamer-based protein detection" (2010). Faculty Publications. 6389.
https://digitalcommons.njit.edu/fac_pubs/6389
