Gene expression data analysis with a dynamically extended self-organized map that exploits class information

doi:10.1093/bioinformatics/18.11.1446

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Bioinformatics Vol. 18 no. 11 2002
Pages 1446-1453
© 2002 Oxford University Press

Gene expression data analysis with a dynamically extended self-organized map that exploits class information

Seferina Mavroudi ¹, Stergios Papadimitriou ¹^,2 and Anastasios Bezerianos ¹^,*

¹ Department of Medical Physics, School of Medicine, University of Patras, 26500 Patras, Greece
² Department of Information Management, Technological Educational Institute of Kavala, 65404 Kavala, Greece

Received on September 17, 2001 ; revised on March 20, 2002 ; accepted on May 9, 2002

Motivation: Currently the most popular approach to analyze genome-wide expression data is clustering. One of the majordrawbacks of most of the existing clustering methods is thatthe number of clusters has to be specified a priori. Furthermore,by using pure unsupervised algorithms prior biological knowledgeis totally ignored Moreover, most current tools lack an effectiveframework for tight integration of unsupervised and supervisedlearning for the analysis of high-dimensional expression dataand only very few multi-class supervised approaches are designedwith the provision for effectively utilizing multiple functionalclass labeling.

Results: The paper adapts a novel Self-Organizing map calledsupervised Network Self-Organized Map (sNet-SOM) to the peculiaritiesof multi-labeled gene expression data. The sNet-SOM determinesadaptively the number of clusters with a dynamic extensionprocess. This process is driven by an inhomogeneous measurethat tries to balance unsupervised, supervised and model complexitycriteria. Nodes within a rectangular grid are grown at theboundary nodes, weights rippled from the internal nodes towardsthe outer nodes of the grid, and whole columns inserted withinthe map The appropriate level of expansion is determined automatically.Multiple sNet-SOM models are constructed dynamically each fora different unsupervised/supervised balance and model selection criteria are used to select the one optimum one. The resultsindicate that sNet-SOM yields competitive performance to otherrecently proposed approaches for supervised classificationat a significantly reduced computational cost and it providesextensive exploratory analysis potentiality within the analysisframework. Furthermore, it explores simple design decisionsthat are easier to comprehend and computationally efficient.

Availability: The source code of the algorithms presented inthe paper can be downloaded from http://heart.med.upatras.gr.The implementation is in Borland C++ Builder 5.0.

Contact: severina{at}heart.med.upatras.gr

^* To whom correspondence should be addressed.

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