A Bayesian framework for performance assessment and comparison of imaging biomarker quantification methods

Quantitative biomarkers derived from medical images are being used increasingly to help diagnose disease, guide treatment, and predict clinical outcomes. Measurement of quantitative imaging biomarkers is subject to bias and variability from multiple sources, including the scanner technologies that p...

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Bibliographic Details
Published in:Statistical methods in medical research Vol. 28; no. 4; p. 1003
Main Authors: Smith, Brian J, Beichel, Reinhard R
Format: Journal Article
Language:English
Published: England 01.04.2019
Subjects:
agreement
sample size
Quantitative imaging biomarkers
Bayesian
bias
precision
ISSN:1477-0334, 1477-0334
Online Access:Get more information
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Summary:Quantitative biomarkers derived from medical images are being used increasingly to help diagnose disease, guide treatment, and predict clinical outcomes. Measurement of quantitative imaging biomarkers is subject to bias and variability from multiple sources, including the scanner technologies that produce images, the approaches for identifying regions of interest in images, and the algorithms that calculate biomarkers from regions. Moreover, these sources may differ within and between the quantification methods employed by institutions, thus making it difficult to develop and implement multi-institutional standards. We present a Bayesian framework for assessing bias and variability in imaging biomarkers derived from different quantification methods, comparing agreement to a reference standard, studying prognostic performance, and estimating sample size for future clinical studies. The statistical methods are illustrated with data obtained from a positron emission tomography challenge conducted by members of the NCI's Quantitative Imaging Network program, in which tumor volumes were measured manually and with seven different semi-automated segmentation algorithms. Estimates and comparisons of bias and variability in the resulting measurements are provided along with an R software package for the technical performance analysis and an online web application for sample size and power analysis.
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ISSN:1477-0334
1477-0334
DOI:10.1177/0962280217741334