Modeling and Experimental Validation of DNA Motion in Uniform and Nonuniform DC Electric Fields

Regis A. David; Justin L. Black; Larry L. Howell; Sandra H. Burnett; Brian D. Jensen

Source: Journal of Nanotechnology in Engineering and Medicine:;2010:;volume( 001 ):;issue: 004::page 41007

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DOI: 10.1115/1.4002321

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: We are developing a new technique to insert foreign DNA into a living cell using a microelectromechanical system. This new technique relies on electrical forces to move DNA in a nonuniform electric field. To better understand this phenomenon, we perform integrated modeling and experiments of DNA electrophoresis. This paper describes the protocol and presents the results for DNA motion experiments using fabricated gel electrophoresis devices. We show that DNA motion is strongly correlated with ion transport (current flow) in the system. A better understanding of electrophoretic fundamentals allows for the creation of a mathematical model to predict the motion of DNA during electrophoresis in both uniform and nonuniform electric fields. The mathematical model is validated within 4% through comparison with the experimental results.

keyword(s): Electric fields , Motion , DNA , Electric potential , Electrophoresis , Electrodes AND Modeling ,

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Modeling and Experimental Validation of DNA Motion in Uniform and Nonuniform DC Electric Fields

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contributor author	Regis A. David
contributor author	Justin L. Black
contributor author	Larry L. Howell
contributor author	Sandra H. Burnett
contributor author	Brian D. Jensen
date accessioned	2017-05-09T00:40:11Z
date available	2017-05-09T00:40:11Z
date copyright	November, 2010
date issued	2010
identifier issn	1949-2944
identifier other	JNEMAA-28046#041007_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/144511
description abstract	We are developing a new technique to insert foreign DNA into a living cell using a microelectromechanical system. This new technique relies on electrical forces to move DNA in a nonuniform electric field. To better understand this phenomenon, we perform integrated modeling and experiments of DNA electrophoresis. This paper describes the protocol and presents the results for DNA motion experiments using fabricated gel electrophoresis devices. We show that DNA motion is strongly correlated with ion transport (current flow) in the system. A better understanding of electrophoretic fundamentals allows for the creation of a mathematical model to predict the motion of DNA during electrophoresis in both uniform and nonuniform electric fields. The mathematical model is validated within 4% through comparison with the experimental results.
publisher	The American Society of Mechanical Engineers (ASME)
title	Modeling and Experimental Validation of DNA Motion in Uniform and Nonuniform DC Electric Fields
type	Journal Paper
journal volume	1
journal issue	4
journal title	Journal of Nanotechnology in Engineering and Medicine
identifier doi	10.1115/1.4002321
journal fristpage	41007
identifier eissn	1949-2952
keywords	Electric fields
keywords	Motion
keywords	DNA
keywords	Electric potential
keywords	Electrophoresis
keywords	Electrodes AND Modeling
tree	Journal of Nanotechnology in Engineering and Medicine:;2010:;volume( 001 ):;issue: 004
contenttype	Fulltext

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