Finite-Element Modelling of Biotransistors

M. W. Shinwari; M. J. Deen; P. R. Selvaganapathy

doi:10.1007/s11671-009-9522-4

Finite-Element Modelling of Biotransistors

M. W. Shinwari, M. J. Deen, P. R. Selvaganapathy

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Current research efforts in biosensor design attempt to integrate biochemical assays with semiconductor substrates and microfluidic assemblies to realize fully integrated lab-on-chip devices. The DNA biotransistor (BioFET) is an example of such a device. The process of chemical modification of the FET and attachment of linker and probe molecules is a statistical process that can result in variations in the sensed signal between different BioFET cells in an array. In order to quantify these and other variations and assess their importance in the design, complete physical simulation of the device is necessary. Here, we perform a mean-field finite-element modelling of a short channel, two-dimensional BioFET device. We compare the results of this model with one-dimensional calculation results to show important differences, illustrating the importance of the molecular structure, placement and conformation of DNA in determining the output signal.

Original language	English
Pages (from-to)	494-500
Number of pages	7
Journal	Nanoscale Research Letters
Volume	5
Issue number	3
DOIs	https://doi.org/10.1007/s11671-009-9522-4
State	Published - Mar 2010
Externally published	Yes

Keywords

Biosensor
DNA
Microarray
Model
Sensitivity

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics

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10.1007/s11671-009-9522-4

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title = "Finite-Element Modelling of Biotransistors",

abstract = "Current research efforts in biosensor design attempt to integrate biochemical assays with semiconductor substrates and microfluidic assemblies to realize fully integrated lab-on-chip devices. The DNA biotransistor (BioFET) is an example of such a device. The process of chemical modification of the FET and attachment of linker and probe molecules is a statistical process that can result in variations in the sensed signal between different BioFET cells in an array. In order to quantify these and other variations and assess their importance in the design, complete physical simulation of the device is necessary. Here, we perform a mean-field finite-element modelling of a short channel, two-dimensional BioFET device. We compare the results of this model with one-dimensional calculation results to show important differences, illustrating the importance of the molecular structure, placement and conformation of DNA in determining the output signal.",

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AU - Shinwari, M. W.

AU - Deen, M. J.

AU - Selvaganapathy, P. R.

PY - 2010/3

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N2 - Current research efforts in biosensor design attempt to integrate biochemical assays with semiconductor substrates and microfluidic assemblies to realize fully integrated lab-on-chip devices. The DNA biotransistor (BioFET) is an example of such a device. The process of chemical modification of the FET and attachment of linker and probe molecules is a statistical process that can result in variations in the sensed signal between different BioFET cells in an array. In order to quantify these and other variations and assess their importance in the design, complete physical simulation of the device is necessary. Here, we perform a mean-field finite-element modelling of a short channel, two-dimensional BioFET device. We compare the results of this model with one-dimensional calculation results to show important differences, illustrating the importance of the molecular structure, placement and conformation of DNA in determining the output signal.

AB - Current research efforts in biosensor design attempt to integrate biochemical assays with semiconductor substrates and microfluidic assemblies to realize fully integrated lab-on-chip devices. The DNA biotransistor (BioFET) is an example of such a device. The process of chemical modification of the FET and attachment of linker and probe molecules is a statistical process that can result in variations in the sensed signal between different BioFET cells in an array. In order to quantify these and other variations and assess their importance in the design, complete physical simulation of the device is necessary. Here, we perform a mean-field finite-element modelling of a short channel, two-dimensional BioFET device. We compare the results of this model with one-dimensional calculation results to show important differences, illustrating the importance of the molecular structure, placement and conformation of DNA in determining the output signal.

KW - Biosensor

KW - DNA

KW - Microarray

KW - Model

KW - Sensitivity

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EP - 500

JO - Nanoscale Research Letters

JF - Nanoscale Research Letters

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Finite-Element Modelling of Biotransistors

Abstract

Keywords

ASJC Scopus subject areas

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