Noise factor analysis for cDNA microarrays

Yoganand Balagurunathan; Naisyin Wang; Edward R. Dougherty; Danh Nguyen; Yidong Chen; Michael L. Bittner; Jeffrey Trent; Raymond Carroll

doi:10.1117/1.1755232

Noise factor analysis for cDNA microarrays

Yoganand Balagurunathan, Naisyin Wang, Edward R. Dougherty, Danh Nguyen, Yidong Chen, Michael L. Bittner, Jeffrey Trent, Raymond Carroll

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

21 Scopus citations

Abstract

A microarray-image model is used that takes into account many factors, including spot morphology, signal strength, background fluorescent noise, and shape and surface degradation. The model yields synthetic images whose appearance and quality reflect that of real microarray images. The model is used to link noise factors to the fidelity of signal extraction with respect to a standard image-extraction algorithm. Of particular interest is the identification of the noise factors and their interactions that significantly degrade the ability to accurately detect the true gene-expression signal. This study uses statistical criteria in conjunction with the simulation of various noise conditions to better understand the noise influence on signal extraction for cDNA microarray images. It proposes a paradigm that is implemented in software. It specifically considers certain kinds of noise in the noise model and sets these at certain levels; however, one can choose other types of noise or use different noise levels. In sum, it develops a statistical package that can work in conjunction with the existing image simulation toolbox.

Original language	English (US)
Pages (from-to)	663-678
Number of pages	16
Journal	Journal of biomedical optics
Volume	9
Issue number	4
DOIs	https://doi.org/10.1117/1.1755232
State	Published - Jul 2004
Externally published	Yes

Keywords

Experimental design
Factorial experiment
Image simulation
Signal detection
cDNA microarray

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Biomaterials
Atomic and Molecular Physics, and Optics
Biomedical Engineering

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10.1117/1.1755232

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title = "Noise factor analysis for cDNA microarrays",

abstract = "A microarray-image model is used that takes into account many factors, including spot morphology, signal strength, background fluorescent noise, and shape and surface degradation. The model yields synthetic images whose appearance and quality reflect that of real microarray images. The model is used to link noise factors to the fidelity of signal extraction with respect to a standard image-extraction algorithm. Of particular interest is the identification of the noise factors and their interactions that significantly degrade the ability to accurately detect the true gene-expression signal. This study uses statistical criteria in conjunction with the simulation of various noise conditions to better understand the noise influence on signal extraction for cDNA microarray images. It proposes a paradigm that is implemented in software. It specifically considers certain kinds of noise in the noise model and sets these at certain levels; however, one can choose other types of noise or use different noise levels. In sum, it develops a statistical package that can work in conjunction with the existing image simulation toolbox.",

keywords = "Experimental design, Factorial experiment, Image simulation, Signal detection, cDNA microarray",

author = "Yoganand Balagurunathan and Naisyin Wang and Dougherty, {Edward R.} and Danh Nguyen and Yidong Chen and Bittner, {Michael L.} and Jeffrey Trent and Raymond Carroll",

note = "Funding Information: Y.B. was supported by the Center for Environmental and Rural Health at Texas A&M University. E.R.D. was supported by the National Human Genome Research Institute. D.V.N. was supported by the National Cancer Institute (CA-90301). R.J.C. was supported by a grant from the National Cancer Institute (CA-57030), and by the Texas A&M Center for Environmental and Rural Health via a grant from the National Institute of Environmental Health Sciences (P30-ES09106). N.W. was supported by the National Cancer Institute (CA-74552).",

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AU - Balagurunathan, Yoganand

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AU - Chen, Yidong

AU - Bittner, Michael L.

AU - Trent, Jeffrey

AU - Carroll, Raymond

N1 - Funding Information: Y.B. was supported by the Center for Environmental and Rural Health at Texas A&M University. E.R.D. was supported by the National Human Genome Research Institute. D.V.N. was supported by the National Cancer Institute (CA-90301). R.J.C. was supported by a grant from the National Cancer Institute (CA-57030), and by the Texas A&M Center for Environmental and Rural Health via a grant from the National Institute of Environmental Health Sciences (P30-ES09106). N.W. was supported by the National Cancer Institute (CA-74552).

PY - 2004/7

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N2 - A microarray-image model is used that takes into account many factors, including spot morphology, signal strength, background fluorescent noise, and shape and surface degradation. The model yields synthetic images whose appearance and quality reflect that of real microarray images. The model is used to link noise factors to the fidelity of signal extraction with respect to a standard image-extraction algorithm. Of particular interest is the identification of the noise factors and their interactions that significantly degrade the ability to accurately detect the true gene-expression signal. This study uses statistical criteria in conjunction with the simulation of various noise conditions to better understand the noise influence on signal extraction for cDNA microarray images. It proposes a paradigm that is implemented in software. It specifically considers certain kinds of noise in the noise model and sets these at certain levels; however, one can choose other types of noise or use different noise levels. In sum, it develops a statistical package that can work in conjunction with the existing image simulation toolbox.

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Noise factor analysis for cDNA microarrays

Abstract

Keywords

ASJC Scopus subject areas

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