Title :
Fabrication of BioInspired Inorganic Nanocilia Sensors
Author :
Hein, Matthew A. ; Maqableh, Mazin M. ; Delahunt, Michael J. ; Tondra, Mark ; Flatau, Alison B. ; Shield, Carol K. ; Stadler, Bethanie J H
Author_Institution :
Electr. & Comput. Eng. Dept., Univ. of Minnesota-Twin Cities, Minneapolis, MN, USA
Abstract :
In nature, microscale hair-like projections called cilia are used ubiquitously for both sensing and motility. In this paper, biomimetic nanoscale cilia arrays have been fabricated through templated growth of Co in anodized aluminum oxide. The motion of arrays of Co cilia was then detected using magnetic sensors. These signals were used to prove the feasibility of two types of sensors: flow sensors and vibration sensors. The flow sensors were tested in a microfluidic channel. They showed the ability to detect flows from 0.5 ml/min to 6 ml/min with a signal to noise (SNR) of 44 using only 140 μW of power and no amplification. The vibration sensors were tested using a shake table in the low earthquake-like frequency range of 1-5 Hz. The vibration response was a mW signal at twice the frequency of the shake table.
Keywords :
bioMEMS; biomimetics; biosensors; cellular biophysics; cobalt; flow sensors; magnetic sensors; microfluidics; nanobiotechnology; nanofabrication; nanosensors; nanowires; vibrations; Co; anodized aluminum oxide; array motion; bioinspired inorganic nanocilia sensors; biomimetic nanoscale cilia arrays; flow sensors; frequency 1 Hz to 5 Hz; low earthquake-like frequency range; magnetic sensors; microfluidic channel; microscale hair-like projections; power 140 muW; signal-noise; templated growth; vibration response; vibration sensors; Biosensors; Educational institutions; Fabrication; Magnetic sensors; Sensor arrays; Vibrations; Artificial cilia; bidirectional flow sensor; biomimetic; cilia; lab on a chip; magnetic nanowire; microfluidics; nanowires; vibration measurement;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2012.2224852
