Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty

ADVANCED IMAGING ANALYSIS FOR PREDICTING TUMOR RESPONSE AND IMPROVING CONTOUR DELINEATION UNCERTAINTY By Rebecca Nichole Mahon, MS A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at Virginia Commonwealth University. Virginia Commonwealth Uni...

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Main Author: Mahon, Rebecca N
Format: Others
Published: VCU Scholars Compass 2018
Subjects:
MRI
Online Access:https://scholarscompass.vcu.edu/etd/5516
https://scholarscompass.vcu.edu/cgi/viewcontent.cgi?article=6604&context=etd
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spelling ndltd-vcu.edu-oai-scholarscompass.vcu.edu-etd-66042019-10-20T22:06:06Z Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty Mahon, Rebecca N ADVANCED IMAGING ANALYSIS FOR PREDICTING TUMOR RESPONSE AND IMPROVING CONTOUR DELINEATION UNCERTAINTY By Rebecca Nichole Mahon, MS A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at Virginia Commonwealth University. Virginia Commonwealth University, 2018 Major Director: Dr. Elisabeth Weiss, Professor, Department of Radiation Oncology Radiomics, an advanced form of imaging analysis, is a growing field of interest in medicine. Radiomics seeks to extract quantitative information from images through use of computer vision techniques to assist in improving treatment. Early prediction of treatment response is one way of improving overall patient care. This work seeks to explore the feasibility of building predictive models from radiomic texture features extracted from magnetic resonance (MR) and computed tomography (CT) images of lung cancer patients. First, repeatable primary tumor texture features from each imaging modality were identified to ensure a sufficient number of repeatable features existed for model development. Then a workflow was developed to build models to predict overall survival and local control using single modality and multi-modality radiomics features. The workflow was also applied to normal tissue contours as a control study. Multiple significant models were identified for the single modality MR- and CT-based models, while the multi-modality models were promising indicating exploration with a larger cohort is warranted. Another way advances in imaging analysis can be leveraged is in improving accuracy of contours. Unfortunately, the tumor can be close in appearance to normal tissue on medical images creating high uncertainty in the tumor boundary. As the entire defined target is treated, providing physicians with additional information when delineating the target volume can improve the accuracy of the contour and potentially reduce the amount of normal tissue incorporated into the contour. Convolution neural networks were developed and trained to identify the tumor interface with normal tissue and for one network to identify the tumor location. A mock tool was presented using the output of the network to provide the physician with the uncertainty in prediction of the interface type and the probability of the contour delineation uncertainty exceeding 5mm for the top three predictions. 2018-01-01T08:00:00Z text application/pdf https://scholarscompass.vcu.edu/etd/5516 https://scholarscompass.vcu.edu/cgi/viewcontent.cgi?article=6604&context=etd © The Author Theses and Dissertations VCU Scholars Compass machine learning radiomics MRI lung cancer convolutional neural networks Investigative Techniques
collection NDLTD
format Others
sources NDLTD
topic machine learning
radiomics
MRI
lung cancer
convolutional neural networks
Investigative Techniques
spellingShingle machine learning
radiomics
MRI
lung cancer
convolutional neural networks
Investigative Techniques
Mahon, Rebecca N
Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty
description ADVANCED IMAGING ANALYSIS FOR PREDICTING TUMOR RESPONSE AND IMPROVING CONTOUR DELINEATION UNCERTAINTY By Rebecca Nichole Mahon, MS A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at Virginia Commonwealth University. Virginia Commonwealth University, 2018 Major Director: Dr. Elisabeth Weiss, Professor, Department of Radiation Oncology Radiomics, an advanced form of imaging analysis, is a growing field of interest in medicine. Radiomics seeks to extract quantitative information from images through use of computer vision techniques to assist in improving treatment. Early prediction of treatment response is one way of improving overall patient care. This work seeks to explore the feasibility of building predictive models from radiomic texture features extracted from magnetic resonance (MR) and computed tomography (CT) images of lung cancer patients. First, repeatable primary tumor texture features from each imaging modality were identified to ensure a sufficient number of repeatable features existed for model development. Then a workflow was developed to build models to predict overall survival and local control using single modality and multi-modality radiomics features. The workflow was also applied to normal tissue contours as a control study. Multiple significant models were identified for the single modality MR- and CT-based models, while the multi-modality models were promising indicating exploration with a larger cohort is warranted. Another way advances in imaging analysis can be leveraged is in improving accuracy of contours. Unfortunately, the tumor can be close in appearance to normal tissue on medical images creating high uncertainty in the tumor boundary. As the entire defined target is treated, providing physicians with additional information when delineating the target volume can improve the accuracy of the contour and potentially reduce the amount of normal tissue incorporated into the contour. Convolution neural networks were developed and trained to identify the tumor interface with normal tissue and for one network to identify the tumor location. A mock tool was presented using the output of the network to provide the physician with the uncertainty in prediction of the interface type and the probability of the contour delineation uncertainty exceeding 5mm for the top three predictions.
author Mahon, Rebecca N
author_facet Mahon, Rebecca N
author_sort Mahon, Rebecca N
title Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty
title_short Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty
title_full Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty
title_fullStr Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty
title_full_unstemmed Advanced Imaging Analysis for Predicting Tumor Response and Improving Contour Delineation Uncertainty
title_sort advanced imaging analysis for predicting tumor response and improving contour delineation uncertainty
publisher VCU Scholars Compass
publishDate 2018
url https://scholarscompass.vcu.edu/etd/5516
https://scholarscompass.vcu.edu/cgi/viewcontent.cgi?article=6604&context=etd
work_keys_str_mv AT mahonrebeccan advancedimaginganalysisforpredictingtumorresponseandimprovingcontourdelineationuncertainty
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