FGX: a frequentist gene expression index for Affymetrix arrays

Vilda Purutçuoğlu; Ernst Wit

FGX: a frequentist gene expression index for Affymetrix arrays

Vilda Purutçuoğlu, Ernst Wit

Probability and Statistics

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Abstract

We consider a new frequentist gene expression index for Affymetrix oligonucleotide DNA arrays, using a similar probe intensity model as suggested previously, called the Bayesian gene expression index (BGX). According to this model, the perfect match and mismatch values are assumed to be correlated as a result of sharing a common gene expression signal. Rather than a Bayesian approach, we develop a maximum likelihood algorithm for estimating the underlying common signal. In this way, estimation is explicit and much faster than the BGX implementation. The observed Fisher information matrix, rather than a posterior credibility interval, gives an idea of the accuracy of the estimators. We evaluate our method using benchmark spike-in data sets from Affymetrix and GeneLogic by analyzing the relationship between estimated signal and concentration, i.e. true signal, and compare our results with other commonly used methods.

Original language	English
Number of pages	5
Journal	Biostatistics
Volume	8
Issue number	2
Publication status	Published - 2007

Keywords

Spike-in data sets
Probe-level analysis
Maximum likelihood
Gene expression
GeneChip
Fisher information matrix
Affymetrix

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title = "FGX: a frequentist gene expression index for Affymetrix arrays",

abstract = "We consider a new frequentist gene expression index for Affymetrix oligonucleotide DNA arrays, using a similar probe intensity model as suggested previously, called the Bayesian gene expression index (BGX). According to this model, the perfect match and mismatch values are assumed to be correlated as a result of sharing a common gene expression signal. Rather than a Bayesian approach, we develop a maximum likelihood algorithm for estimating the underlying common signal. In this way, estimation is explicit and much faster than the BGX implementation. The observed Fisher information matrix, rather than a posterior credibility interval, gives an idea of the accuracy of the estimators. We evaluate our method using benchmark spike-in data sets from Affymetrix and GeneLogic by analyzing the relationship between estimated signal and concentration, i.e. true signal, and compare our results with other commonly used methods.",

keywords = "Spike-in data sets, Probe-level analysis, Maximum likelihood, Gene expression, GeneChip, Fisher information matrix, Affymetrix",

author = "Vilda Purut{\c c}uoğlu and Ernst Wit",

note = "Relation: http://www.rug.nl/informatica/organisatie/overorganisatie/iwi Rights: University of Groningen. Research Institute for Mathematics and Computing Science (IWI)",

year = "2007",

language = "English",

volume = "8",

journal = "Biostatistics",

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T2 - a frequentist gene expression index for Affymetrix arrays

AU - Purutçuoğlu, Vilda

AU - Wit, Ernst

N1 - Relation: http://www.rug.nl/informatica/organisatie/overorganisatie/iwi Rights: University of Groningen. Research Institute for Mathematics and Computing Science (IWI)

PY - 2007

Y1 - 2007

N2 - We consider a new frequentist gene expression index for Affymetrix oligonucleotide DNA arrays, using a similar probe intensity model as suggested previously, called the Bayesian gene expression index (BGX). According to this model, the perfect match and mismatch values are assumed to be correlated as a result of sharing a common gene expression signal. Rather than a Bayesian approach, we develop a maximum likelihood algorithm for estimating the underlying common signal. In this way, estimation is explicit and much faster than the BGX implementation. The observed Fisher information matrix, rather than a posterior credibility interval, gives an idea of the accuracy of the estimators. We evaluate our method using benchmark spike-in data sets from Affymetrix and GeneLogic by analyzing the relationship between estimated signal and concentration, i.e. true signal, and compare our results with other commonly used methods.

AB - We consider a new frequentist gene expression index for Affymetrix oligonucleotide DNA arrays, using a similar probe intensity model as suggested previously, called the Bayesian gene expression index (BGX). According to this model, the perfect match and mismatch values are assumed to be correlated as a result of sharing a common gene expression signal. Rather than a Bayesian approach, we develop a maximum likelihood algorithm for estimating the underlying common signal. In this way, estimation is explicit and much faster than the BGX implementation. The observed Fisher information matrix, rather than a posterior credibility interval, gives an idea of the accuracy of the estimators. We evaluate our method using benchmark spike-in data sets from Affymetrix and GeneLogic by analyzing the relationship between estimated signal and concentration, i.e. true signal, and compare our results with other commonly used methods.

KW - Spike-in data sets

KW - Probe-level analysis

KW - Maximum likelihood

KW - Gene expression

KW - GeneChip

KW - Fisher information matrix

KW - Affymetrix

M3 - Article

SN - 1465-4644

VL - 8

JO - Biostatistics

JF - Biostatistics

IS - 2

ER -

FGX: a frequentist gene expression index for Affymetrix arrays

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