Systematic computation of nonlinear cellular and molecular dynamics with low-power cytomimetic circuits: a simulation study
Systematic computation of nonlinear cellular and molecular dynamics with low-power cytomimetic circuits: a simulation study
This paper presents a novel method for the systematic implementation of low-power microelectronic circuits aimed at computing nonlinear cellular and molecular dynamics. The method proposed is based on the Nonlinear Bernoulli Cell Formalism (NBCF), an advanced mathematical framework stemming from the Bernoulli Cell Formalism (BCF) originally exploited for the modular synthesis and analysis of linear, time-invariant, high dynamic range, logarithmic filters. Our approach identifies and exploits the striking similarities existing between the NBCF and coupled nonlinear ordinary differential equations (ODEs) typically appearing in models of naturally encountered biochemical systems. The resulting continuous-time, continuous-value, low-power CytoMimetic electronic circuits succeed in simulating fast and with good accuracy cellular and molecular dynamics. The application of the method is illustrated by synthesising for the first time microelectronic CytoMimetic topologies which simulate successfully: 1) a nonlinear intracellular calcium oscillations model for several Hill coefficient values and 2) a gene-protein regulatory system model. The dynamic behaviours generated by the proposed CytoMimetic circuits are compared and found to be in very good agreement with their biological counterparts. The circuits exploit the exponential law codifying the low-power subthreshold operation regime and have been simulated with realistic parameters from a commercially available CMOS process. They occupy an area of a fraction of a square-millimetre, while consuming between 1 and 12 microwatts of power. Simulations of fabrication-related variability results are also presented
e53591
Papadimitriou, Konstantinos I
c0535540-f862-41b1-9cf3-92b1f46a4145
Stan, Guy-Bart V.
a5d173be-9712-45cd-9bc7-d540965c9465
Drakakis, Emmanuel M.
e90f288a-ba96-4e6b-af0f-bb7ab850ce99
5 February 2013
Papadimitriou, Konstantinos I
c0535540-f862-41b1-9cf3-92b1f46a4145
Stan, Guy-Bart V.
a5d173be-9712-45cd-9bc7-d540965c9465
Drakakis, Emmanuel M.
e90f288a-ba96-4e6b-af0f-bb7ab850ce99
Papadimitriou, Konstantinos I, Stan, Guy-Bart V. and Drakakis, Emmanuel M.
(2013)
Systematic computation of nonlinear cellular and molecular dynamics with low-power cytomimetic circuits: a simulation study.
PLoS ONE, 8 (2), .
(doi:10.1371/journal.pone.0053591).
Abstract
This paper presents a novel method for the systematic implementation of low-power microelectronic circuits aimed at computing nonlinear cellular and molecular dynamics. The method proposed is based on the Nonlinear Bernoulli Cell Formalism (NBCF), an advanced mathematical framework stemming from the Bernoulli Cell Formalism (BCF) originally exploited for the modular synthesis and analysis of linear, time-invariant, high dynamic range, logarithmic filters. Our approach identifies and exploits the striking similarities existing between the NBCF and coupled nonlinear ordinary differential equations (ODEs) typically appearing in models of naturally encountered biochemical systems. The resulting continuous-time, continuous-value, low-power CytoMimetic electronic circuits succeed in simulating fast and with good accuracy cellular and molecular dynamics. The application of the method is illustrated by synthesising for the first time microelectronic CytoMimetic topologies which simulate successfully: 1) a nonlinear intracellular calcium oscillations model for several Hill coefficient values and 2) a gene-protein regulatory system model. The dynamic behaviours generated by the proposed CytoMimetic circuits are compared and found to be in very good agreement with their biological counterparts. The circuits exploit the exponential law codifying the low-power subthreshold operation regime and have been simulated with realistic parameters from a commercially available CMOS process. They occupy an area of a fraction of a square-millimetre, while consuming between 1 and 12 microwatts of power. Simulations of fabrication-related variability results are also presented
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Accepted/In Press date: 3 December 2012
Published date: 5 February 2013
Organisations:
Bioengineering Group
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Local EPrints ID: 376755
URI: http://eprints.soton.ac.uk/id/eprint/376755
ISSN: 1932-6203
PURE UUID: a69efc28-2daf-4dc6-8fbe-eabad2215b84
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Date deposited: 08 May 2015 11:24
Last modified: 14 Mar 2024 19:49
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Author:
Konstantinos I Papadimitriou
Author:
Guy-Bart V. Stan
Author:
Emmanuel M. Drakakis
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