Energy Science and Technology

The objective of this paper is to analyze the yeast cell, liver cell and blood cell under both infected and healthy conditions by applying electrical signal through dual nanoprobe from source to cell. Knowledge of nanoprobe based bio-cell analysis can be used to differentiate infected cells from healthy ones, since their electrical behaviour is different. The voltage can be applied either inside the cytoplasm penetrating the cell wall, or at the outer surface of cell membrane. In this paper, the simulation has been carried out by applying voltage inside the cytoplasm using ABAQUS 6.10 CAE, powerful finite element software and the results obtained from simulation shows current flow healthy yeast and dead yeast cells are 1·9nA and 34pA respectively whereas the value of the current measured for the leukaemia affected blood cell is 21·2nA, being 2% less than the White Blood Cell (WBC). Since the conductivity of the cytoplasm of the healthy cell is theoretically higher than that of dead or infected cell, which is verified by simulation. The results from simulation show that the measured cell current from liver tumour cell is 2-7 times larger than healthy liver cell including membrane as it is supposed to be since the conductivity of cell including cell membrane is theoretically greater for dead or infected cell than healthy cell.

Dual nanoprobe; Cell viability test; Yeast cell; WBC; Liver cell; Axon cell; ECD; ABAQUS 6.10 CAE; Electrical conductivity

Ahmad, M.R., Nakajima, M., Fukuda, T., Kojima S., & Homma, M. (2009). In Proceedings of the Single Cells Electrical Characterizations using Nanoprobe via ESEM-Nanomanipulator System, Genoa, 26-30 July 2009 (pp. 589-292). IEEE Xplore.
Cone C.D. (1970). Variation of the transmembrane potential level as a basic mechanism of mitosis control. Oncology, 24(6), 438-470.
Cure J.C. (1991). Cancer an electrical phenomenon. Resonant.
Ingebrandt, S., Wrobel, G., Eick, S., Schafer, S., & Offenhausser A. (2007) Probing the Adhesion and Viability of Individual Cells with Field-Effect Transistors. In Proceedings of the Solid-State Sensors, Actuators and Microsystems Conference, Lyon, 10-14 June 2007(pp. 803-806). IEEE Xplore.
Sahu, R.K., Zelig, U., Huleihel, M., Brosh, N., Talyshinsky, M., Ben-Harosh, M., Mordechai, S., & Kapelushnik, J.(2005). Continuous monitoring of WBC (biochemistry) in an adult leukemia patient using advanced FTIR-spectroscopy. Leukemia Research, 30(6), 687-693.
Steve Haltiwanger M.D., C.C.N,. The Electrical Properties of Cancer Cell. Retrieved from website: http://www.royalrife.com/haltiwanger1.pdf.
Sulaiman, A.H.M. (2012). Modeling and simulation of Novel Method of Cell Viability Detection via Electrical Measurement using Dual Nanoprobes. In Proceedings of the Enabling Science and Nanotechnology (ESciNano), Johor Bahru, 5-7 Jan 2012 (pp. 1-2). IEEE Xplore.
Tandon, T. (2012). Novel Detection of Hematological Cancer: A Proposed Conductivity Based Analysis for Early Leukemia Cell Identification. California, USA.