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Hindi Vertically aligned carbon nano-fiber biosensors
Nicole McFarlane
University of Tennessee, USA
: J Electr Eng Electron Technol
Abstract
Electro-physiological, electrochemical and electro-analytical detection performed using electrodes in the nanometer range have emerged as promising avenues for the interrogation and monitoring of real time biochemical dynamics at the single cell level. The promise of these electrodes lie in their fast response times, high mass sensitivity, small size, large linear dynamic range, and molecules of interest which can be followed without the need for chemical derivitization, as is necessary with fluorescent probe techniques. In the large variety of sensor materials available, carbon is a popular sensing electrode due to its unique structural and material properties. These properties include high conductivity, durability in harsh environment, and inertness to processing steps. The crucial advantage of aligned carbon nano-fibers over other nanostructures, such an carbon nanotubes, is that they can be grown deterministically such that their position, height, tip diameter, and, to some extent, shape and orientation can all be controlled. Additionally, reliable mechanical and electrical contact to the substrate can be established because of their excellent conductive and structural properties. In collaboration with Syed Islam’s group and Oak Ridge National Lab, we have demonstrated an electrochemical biosensing platform using vertically aligned carbon nano-fibers. The sensor is capable of sensing a wide range of physiologically relevant glucose levels and has shown excellent repeatability, linearity, sensitivity and resolution. This talk will present the status of our work including our experimental results and future plans for the technology
Biography
Nicole McFarlane received her BS and MS degrees in electrical engineering from Howard University, Washington DC, in 2001 and 2003, respectively, and her PhD in Electrical Engineering at the University of Maryland, College Park in 2010. Her research experience includes growing and characterizing III–V Nitrides, understanding information and power efficiency trade-offs in mixed signal integrated circuit design, CMOS biosensors, and CMOS/MEMS integration for lab-on-achip technologies. She has been an Assistant Professor at the University of Tennessee since 2010, working on sensors, devices and electronics for portable and implantable applications.
