Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites

An assumption commonly used in cable theory is revised by taking into account electrical amplification due to intracellular capacitive effects in passive dendritic cables. A generalized cable equation for a cylindrical volume representation of a dendritic segment is derived from Maxwell's equat...

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Main Author: Poznanski, R.R.
Format: Article
Published: American Physical Society 2010
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Online Access:http://eprints.um.edu.my/15254/
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spelling my.um.eprints.152542015-12-23T03:05:43Z http://eprints.um.edu.my/15254/ Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites Poznanski, R.R. Q Science (General) An assumption commonly used in cable theory is revised by taking into account electrical amplification due to intracellular capacitive effects in passive dendritic cables. A generalized cable equation for a cylindrical volume representation of a dendritic segment is derived from Maxwell's equations under assumptions: (i) the electric-field polarization is restricted longitudinally along the cable length; (ii) extracellular isopotentiality; (iii) quasielectrostatic conditions; and (iv) homogeneous medium with constant conductivity and permittivity. The generalized cable equation is identical to Barenblatt's equation arising in the theory of infiltration in fissured strata with a known analytical solution expressed in terms of a definite integral involving a modified Bessel function and the solution to a linear one-dimensional classical cable equation. Its solution is used to determine the impact of thermal noise on voltage attenuation with distance at any particular time. A regular perturbation expansion for the membrane potential about the linear one-dimensional classical cable equation solution is derived in terms of a Green's function in order to describe the dynamics of free charge within the Debye layer of endogenous structures in passive dendritic cables. The asymptotic value of the first perturbative term is explicitly evaluated for small values of time to predict how the slowly fluctuating (in submillisecond range) electric field attributed to intracellular capacitive effects alters the amplitude of the membrane potential. It was found that capacitive effects are almost negligible for cables with electrotonic lengths L > 0.5, contributes up to 10% of the signal for cables with electrotonic lengths in the range between 0.25 < L < 0.5, and dominates the membrane potential for electrotonically short cables (L < 0.2). These results show that electrotonically short dendritic cables with both ends sealed are prone to significant neurobiological thermal noise due to intracellular capacitive effects. The presence of significant thermal noise weakens the assumption of intracellular isopotentiality when approximating dendrites with compartments. American Physical Society 2010 Article PeerReviewed Poznanski, R.R. (2010) Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites. Physical Review E (PRE), 81 (2, 1).
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Research Repository
url_provider http://eprints.um.edu.my/
topic Q Science (General)
spellingShingle Q Science (General)
Poznanski, R.R.
Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites
description An assumption commonly used in cable theory is revised by taking into account electrical amplification due to intracellular capacitive effects in passive dendritic cables. A generalized cable equation for a cylindrical volume representation of a dendritic segment is derived from Maxwell's equations under assumptions: (i) the electric-field polarization is restricted longitudinally along the cable length; (ii) extracellular isopotentiality; (iii) quasielectrostatic conditions; and (iv) homogeneous medium with constant conductivity and permittivity. The generalized cable equation is identical to Barenblatt's equation arising in the theory of infiltration in fissured strata with a known analytical solution expressed in terms of a definite integral involving a modified Bessel function and the solution to a linear one-dimensional classical cable equation. Its solution is used to determine the impact of thermal noise on voltage attenuation with distance at any particular time. A regular perturbation expansion for the membrane potential about the linear one-dimensional classical cable equation solution is derived in terms of a Green's function in order to describe the dynamics of free charge within the Debye layer of endogenous structures in passive dendritic cables. The asymptotic value of the first perturbative term is explicitly evaluated for small values of time to predict how the slowly fluctuating (in submillisecond range) electric field attributed to intracellular capacitive effects alters the amplitude of the membrane potential. It was found that capacitive effects are almost negligible for cables with electrotonic lengths L > 0.5, contributes up to 10% of the signal for cables with electrotonic lengths in the range between 0.25 < L < 0.5, and dominates the membrane potential for electrotonically short cables (L < 0.2). These results show that electrotonically short dendritic cables with both ends sealed are prone to significant neurobiological thermal noise due to intracellular capacitive effects. The presence of significant thermal noise weakens the assumption of intracellular isopotentiality when approximating dendrites with compartments.
format Article
author Poznanski, R.R.
author_facet Poznanski, R.R.
author_sort Poznanski, R.R.
title Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites
title_short Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites
title_full Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites
title_fullStr Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites
title_full_unstemmed Thermal noise due to surface-charge effects within the Debye layer of endogenous structures in dendrites
title_sort thermal noise due to surface-charge effects within the debye layer of endogenous structures in dendrites
publisher American Physical Society
publishDate 2010
url http://eprints.um.edu.my/15254/
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