Karolis Petrauskas scite author profile

This paper presents one-dimensional (1-D) and two-dimensional (2-D) in-space mathematical models for amperometric biosensors with an outer perforated membrane. The biosensor action was modelled by reaction-diffusion equations with a nonlinear term representing the Michaelis-Menten kinetics of an enzymatic reaction. The conditions at which the 1-D model can be applied to simulate the biosensor response accurately were investigated numerically. The accuracy of the biosensor response simulated by using 1-D model was evaluated by the response simulated with the corresponding 2-D model. A procedure for a numerical evaluation of the effective diffusion coefficient to be used in 1-D model was proposed. The numerically calculated effective diffusion coefficient was compared with the corresponding coefficients derived analytically. The numerical simulation was carried out using the finite difference technique.

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Modelling Carbon Nanotubes-Based Mediatorless Biosensor

Baronas

Kulys

Petrauskas

et al. 2012

Sensors

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This paper presents a mathematical model of carbon nanotubes-based mediatorless biosensor. The developed model is based on nonlinear non-stationary reaction-diffusion equations. The model involves four layers (compartments): a layer of enzyme solution entrapped on a terylene membrane, a layer of the single walled carbon nanotubes deposited on a perforated membrane, and an outer diffusion layer. The biosensor response and sensitivity are investigated by changing the model parameters with a special emphasis on the mediatorless transfer of the electrons in the layer of the enzyme-loaded carbon nanotubes. The numerical simulation at transient and steady state conditions was carried out using the finite difference technique. The mathematical model and the numerical solution were validated by experimental data. The obtained agreement between the simulation results and the experimental data was admissible at different concentrations of the substrate.

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Modified SWCNTs for Reagentless Glucose Biosensor: Electrochemical and Mathematical Characterization

et al. 2012

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An original concept in technology of biosensitive electrodes based on single‐wall carbon nanotubes (SWCNT) is proposed. According to a newly proposed technique the electrode surface consisting of SWCNT’s embedded in a porous polycarbonate film was preoxidized enzymatically using laccase from Basidiomycete Lac. An efficient electron transfer from the active centre of PQQ‐dependent glucose dehydrogenase (s‐PQQ‐GDH) to the SWCNT electrode surface allowed the application of the s‐PQQ‐GDH as recognition element for the reagentless biosensor design. The residual activity of the biosensor was found to be 40 % after one month of operational working. A mathematical model of the biosensor has been developed and an admissible agreement between the simulation results and the experimental data was obtained. The model appears to be promising for optimization of amperometric analysis.

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Computational Modeling of Mediator Oxidation by Oxygen in an Amperometric Glucose Biosensor

Šimelevičius

Petrauskas

Baronas

et al. 2014

Sensors

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In this paper, an amperometric glucose biosensor is modeled numerically. The model is based on non-stationary reaction-diffusion type equations. The model consists of four layers. An enzyme layer lies directly on a working electrode surface. The enzyme layer is attached to an electrode by a polyvinyl alcohol (PVA) coated terylene membrane. This membrane is modeled as a PVA layer and a terylene layer, which have different diffusivities. The fourth layer of the model is the diffusion layer, which is modeled using the Nernst approach. The system of partial differential equations is solved numerically using the finite difference technique. The operation of the biosensor was analyzed computationally with special emphasis on the biosensor response sensitivity to oxygen when the experiment was carried out in aerobic conditions. Particularly, numerical experiments show that the overall biosensor response sensitivity to oxygen is insignificant. The simulation results qualitatively explain and confirm the experimentally observed biosensor behavior.

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