Modeling radiation-induced lung injury risk with an ensemble of support vector machines

Todd W. Schiller; Yixin Chen; Issam El Naqa; Joseph O. Deasy

doi:10.1016/j.neucom.2009.09.023

Modeling radiation-induced lung injury risk with an ensemble of support vector machines

Todd W. Schiller, Yixin Chen, Issam El Naqa, Joseph O. Deasy

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

11 Scopus citations

Abstract

Radiation-induced lung injury, radiation pneumonitis (RP), is a potentially fatal side-effect of thoracic radiation therapy. In this work, using an ensemble of support vector machines (SVMs), we build a binary RP risk model from clinical and dosimetric parameters. Patient/treatment data is partitioned into balanced subsets to prevent model bias. Forward feature selection, maximizing the area under the curve (AUC) for a cross-validated receiver operating characteristic (ROC) curve, is performed on each subset. Model parameter selection and construction occurs concurrently via alternating SVM and gradient descent steps to minimize estimated generalization error. We show that an ensemble classifier with a mean fusion function, five component SVMs, and limit of five features per classifier exhibits a mean AUC of 0.818-an improvement over previous SVM models of RP risk.

Original language	English
Pages (from-to)	1861-1867
Number of pages	7
Journal	Neurocomputing
Volume	73
Issue number	10-12
DOIs	https://doi.org/10.1016/j.neucom.2009.09.023
State	Published - Jun 2010

Keywords

Ensemble learning
Feature selection
Radiation pneumonitis
Support vector machine
Unbalanced data

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10.1016/j.neucom.2009.09.023

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title = "Modeling radiation-induced lung injury risk with an ensemble of support vector machines",

abstract = "Radiation-induced lung injury, radiation pneumonitis (RP), is a potentially fatal side-effect of thoracic radiation therapy. In this work, using an ensemble of support vector machines (SVMs), we build a binary RP risk model from clinical and dosimetric parameters. Patient/treatment data is partitioned into balanced subsets to prevent model bias. Forward feature selection, maximizing the area under the curve (AUC) for a cross-validated receiver operating characteristic (ROC) curve, is performed on each subset. Model parameter selection and construction occurs concurrently via alternating SVM and gradient descent steps to minimize estimated generalization error. We show that an ensemble classifier with a mean fusion function, five component SVMs, and limit of five features per classifier exhibits a mean AUC of 0.818-an improvement over previous SVM models of RP risk.",

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author = "Schiller, \{Todd W.\} and Yixin Chen and \{El Naqa\}, Issam and Deasy, \{Joseph O.\}",

year = "2010",

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T1 - Modeling radiation-induced lung injury risk with an ensemble of support vector machines

AU - Schiller, Todd W.

AU - Chen, Yixin

AU - El Naqa, Issam

AU - Deasy, Joseph O.

PY - 2010/6

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N2 - Radiation-induced lung injury, radiation pneumonitis (RP), is a potentially fatal side-effect of thoracic radiation therapy. In this work, using an ensemble of support vector machines (SVMs), we build a binary RP risk model from clinical and dosimetric parameters. Patient/treatment data is partitioned into balanced subsets to prevent model bias. Forward feature selection, maximizing the area under the curve (AUC) for a cross-validated receiver operating characteristic (ROC) curve, is performed on each subset. Model parameter selection and construction occurs concurrently via alternating SVM and gradient descent steps to minimize estimated generalization error. We show that an ensemble classifier with a mean fusion function, five component SVMs, and limit of five features per classifier exhibits a mean AUC of 0.818-an improvement over previous SVM models of RP risk.

AB - Radiation-induced lung injury, radiation pneumonitis (RP), is a potentially fatal side-effect of thoracic radiation therapy. In this work, using an ensemble of support vector machines (SVMs), we build a binary RP risk model from clinical and dosimetric parameters. Patient/treatment data is partitioned into balanced subsets to prevent model bias. Forward feature selection, maximizing the area under the curve (AUC) for a cross-validated receiver operating characteristic (ROC) curve, is performed on each subset. Model parameter selection and construction occurs concurrently via alternating SVM and gradient descent steps to minimize estimated generalization error. We show that an ensemble classifier with a mean fusion function, five component SVMs, and limit of five features per classifier exhibits a mean AUC of 0.818-an improvement over previous SVM models of RP risk.

KW - Ensemble learning

KW - Feature selection

KW - Radiation pneumonitis

KW - Support vector machine

KW - Unbalanced data

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DO - 10.1016/j.neucom.2009.09.023

M3 - Article

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SN - 0925-2312

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SP - 1861

EP - 1867

JO - Neurocomputing

JF - Neurocomputing

IS - 10-12

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Modeling radiation-induced lung injury risk with an ensemble of support vector machines

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Keywords

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