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In what manner the microtubules, cytoskeletal nanotubes, handle and process electrical signals is still uncompleted puzzle. These bio–macromolecules have highly charged surfaces that enable them to conduct electric signals. In the context of electrodynamic properties of microtubule, the paper proposes an improved electrical model based on its cylindrical structure with nano–pores in its wall. Relying on our earlier ideas, we represent this protein–based nanotube with the surrounding ions as biomolecular nonlinear transmission line with corresponding nanoscale electric elements in it. One of the key aspects is the nonlinearity of associated capacitance due to the effect of shrinking/stretching and oscillation of C–terminal tails. Accordingly, a characteristic voltage equation of electrical model of microtubule and influence of capacitance nonlinearity on the propagation of electrical pulses are numerically analyzed here.

J. Zimmerman, R. Parameswaran and B Tian, "Nanoscale Semiconductor Devices as New Biomaterials", Biomater. Sci., vol. 2, pp. 619–626, May 2014.

D. Havelka, M. Cifra and O. Kucera, "Multi-mode Electro-mechanical Vibrations of a Microtubule: In Silico Demonstration of Electric Pulse Moving along a Microtubule", Appl. Phys. Lett., vol. 104, pp. 243702.1–4, June 2014.

J. L. Malcos and W. O. Hancock, "Engineering Tubulin: Microtubule Functionalization Approaches for Nanoscale Device Applications", Appl. Microbiol. Biotechnol., vol. 90, pp. 1–10, April 2011.

S. Sahu, S. Ghosh, K. Hirata, D. Fujita and A. Bandyopadhyay, "Multi-level Memory-switching Properties of a Single Brain Microtubule", Appl. Phys. Lett., vol. 102, pp. 123701.1–4, March 2013.

J. A. Tuszynski, T. J. A. Craddock and E. J. Carpenter, "Bio-Ferroelectricity at the Nanoscale", J. Comput. Theor. Nanosci., vol. 5, pp. 2022–2032, October 2008.

F. Pampaloni and E. L. Florin, "Microtubule Architecture: Inspiration for Novel Carbon Nanotube-based Biomimetic Materials", Trends Biotechnol., vol. 26, pp. 302–310, June 2008.

D. L. Sekulic, B. M. Sataric, J. A. Tuszynski and M. V. Sataric, "Nonlinear Ionic Pulses along Microtubules", Eur. Phys. J. E., vol. 34, art. no. 49, May 2011.

A. Priel, A. J. Ramos, J. A. Tuszynski and H. F. Cantiello, "A Biopolymer Transistor: Electrical Amplification by Microtubules", Biophys. J., vol. 90, pp. 4639–4643, June 2006.

N. A. Baker, D. Sept, S. Joseph, M. J. Holst and J. A. McCammon, "Electrostatics of Nanosystems: Application to Microtubules and the Ribosome", Proc. Nat. Acad. Sci. USA, vol. 98, pp. 10037–10041, August 2001.

D. L. Sekulic and M. V. Sataric, "An Improved Electrical Model of Microtubule as Biomolecular Nonlinear Transmission Line", In Proceedings of the 29th International Conference on Microelectronics-MIEL 2014, Belgrade, 2014, pp. 111–114.

M. V. Sataric, D. Sekulic and M. Zivanov, "Solitonic Ionic Currents along Microtubules", J. Comput. Theor. Nanosci., vol. 7, pp. 2281–2290, November 2010.

G. S. Manning, "The Molecular Theory of Polyelectrolyte Solutions with Applications to the Electrostatic Properties of Polynucleotides", Q. Rev. Biophys., vol. 11, pp. 179–246, May 1978.

D. L. Sekulic and M. V. Sataric, "Microtubule as Nanobioelectronic Nonlinear Circuit", Serbian Journal of Electrical Engineering, vol. 9, pp. 107–119, February 2012.

H. Freedman, V. Rezania, A. Priel, E. Carpenter, S. Y. Noskov and J. A. Tuszynski, "Model of Ionic Currents through Microtubule Nanopores and the Lumen", Phys. Rev. E, vol. 81, pp. 051912.1–11, May 2010.

D. L. Sekulic, M. V. Sataric, M. B. Zivanov and J. S. Bajic, "Soliton-like Pulses along Electrical Nonlinear Transmission Line", Elektronika ir Elektrotechnika, vol. 121, pp. 53–58, May 2012.