BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning

BACKGROUND: A wide variety of benign and malignant processes can manifest as non-mass enhancement (NME) in breast MRI. Compared to mass lesions, there are no distinct features that can be used for differential diagnosis. The purpose is to use the BI-RADS descriptors and models developed using radiom...

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Autores principales: Zhou, Jiejie, Liu, Yan-Lin, Zhang, Yang, Chen, Jeon-Hor, Combs, Freddie J., Parajuli, Ritesh, Mehta, Rita S., Liu, Huiru, Chen, Zhongwei, Zhao, Youfan, Pan, Zhifang, Wang, Meihao, Yu, Risheng, Su, Min-Ying
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2021
Materias:
Oncology
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8591227/
https://www.ncbi.nlm.nih.gov/pubmed/34790569
http://dx.doi.org/10.3389/fonc.2021.728224
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author Zhou, Jiejie
Liu, Yan-Lin
Zhang, Yang
Chen, Jeon-Hor
Combs, Freddie J.
Parajuli, Ritesh
Mehta, Rita S.
Liu, Huiru
Chen, Zhongwei
Zhao, Youfan
Pan, Zhifang
Wang, Meihao
Yu, Risheng
Su, Min-Ying
author_facet Zhou, Jiejie
Liu, Yan-Lin
Zhang, Yang
Chen, Jeon-Hor
Combs, Freddie J.
Parajuli, Ritesh
Mehta, Rita S.
Liu, Huiru
Chen, Zhongwei
Zhao, Youfan
Pan, Zhifang
Wang, Meihao
Yu, Risheng
Su, Min-Ying
author_sort Zhou, Jiejie
collection PubMed
description BACKGROUND: A wide variety of benign and malignant processes can manifest as non-mass enhancement (NME) in breast MRI. Compared to mass lesions, there are no distinct features that can be used for differential diagnosis. The purpose is to use the BI-RADS descriptors and models developed using radiomics and deep learning to distinguish benign from malignant NME lesions. MATERIALS AND METHODS: A total of 150 patients with 104 malignant and 46 benign NME were analyzed. Three radiologists performed reading for morphological distribution and internal enhancement using the 5th BI-RADS lexicon. For each case, the 3D tumor mask was generated using Fuzzy-C-Means segmentation. Three DCE parametric maps related to wash-in, maximum, and wash-out were generated, and PyRadiomics was applied to extract features. The radiomics model was built using five machine learning algorithms. ResNet50 was implemented using three parametric maps as input. Approximately 70% of earlier cases were used for training, and 30% of later cases were held out for testing. RESULTS: The diagnostic BI-RADS in the original MRI report showed that 104/104 malignant and 36/46 benign lesions had a BI-RADS score of 4A–5. For category reading, the kappa coefficient was 0.83 for morphological distribution (excellent) and 0.52 for internal enhancement (moderate). Segmental and Regional distribution were the most prominent for the malignant group, and focal distribution for the benign group. Eight radiomics features were selected by support vector machine (SVM). Among the five machine learning algorithms, SVM yielded the highest accuracy of 80.4% in training and 77.5% in testing datasets. ResNet50 had a better diagnostic performance, 91.5% in training and 83.3% in testing datasets. CONCLUSION: Diagnosis of NME was challenging, and the BI-RADS scores and descriptors showed a substantial overlap. Radiomics and deep learning may provide a useful CAD tool to aid in diagnosis.
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spelling pubmed-85912272021-11-16 BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning Zhou, Jiejie Liu, Yan-Lin Zhang, Yang Chen, Jeon-Hor Combs, Freddie J. Parajuli, Ritesh Mehta, Rita S. Liu, Huiru Chen, Zhongwei Zhao, Youfan Pan, Zhifang Wang, Meihao Yu, Risheng Su, Min-Ying Front Oncol Oncology BACKGROUND: A wide variety of benign and malignant processes can manifest as non-mass enhancement (NME) in breast MRI. Compared to mass lesions, there are no distinct features that can be used for differential diagnosis. The purpose is to use the BI-RADS descriptors and models developed using radiomics and deep learning to distinguish benign from malignant NME lesions. MATERIALS AND METHODS: A total of 150 patients with 104 malignant and 46 benign NME were analyzed. Three radiologists performed reading for morphological distribution and internal enhancement using the 5th BI-RADS lexicon. For each case, the 3D tumor mask was generated using Fuzzy-C-Means segmentation. Three DCE parametric maps related to wash-in, maximum, and wash-out were generated, and PyRadiomics was applied to extract features. The radiomics model was built using five machine learning algorithms. ResNet50 was implemented using three parametric maps as input. Approximately 70% of earlier cases were used for training, and 30% of later cases were held out for testing. RESULTS: The diagnostic BI-RADS in the original MRI report showed that 104/104 malignant and 36/46 benign lesions had a BI-RADS score of 4A–5. For category reading, the kappa coefficient was 0.83 for morphological distribution (excellent) and 0.52 for internal enhancement (moderate). Segmental and Regional distribution were the most prominent for the malignant group, and focal distribution for the benign group. Eight radiomics features were selected by support vector machine (SVM). Among the five machine learning algorithms, SVM yielded the highest accuracy of 80.4% in training and 77.5% in testing datasets. ResNet50 had a better diagnostic performance, 91.5% in training and 83.3% in testing datasets. CONCLUSION: Diagnosis of NME was challenging, and the BI-RADS scores and descriptors showed a substantial overlap. Radiomics and deep learning may provide a useful CAD tool to aid in diagnosis. Frontiers Media S.A. 2021-11-01 /pmc/articles/PMC8591227/ /pubmed/34790569 http://dx.doi.org/10.3389/fonc.2021.728224 Text en Copyright © 2021 Zhou, Liu, Zhang, Chen, Combs, Parajuli, Mehta, Liu, Chen, Zhao, Pan, Wang, Yu and Su https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Oncology
Zhou, Jiejie
Liu, Yan-Lin
Zhang, Yang
Chen, Jeon-Hor
Combs, Freddie J.
Parajuli, Ritesh
Mehta, Rita S.
Liu, Huiru
Chen, Zhongwei
Zhao, Youfan
Pan, Zhifang
Wang, Meihao
Yu, Risheng
Su, Min-Ying
BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning
title BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning
title_full BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning
title_fullStr BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning
title_full_unstemmed BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning
title_short BI-RADS Reading of Non-Mass Lesions on DCE-MRI and Differential Diagnosis Performed by Radiomics and Deep Learning
title_sort bi-rads reading of non-mass lesions on dce-mri and differential diagnosis performed by radiomics and deep learning
topic Oncology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8591227/
https://www.ncbi.nlm.nih.gov/pubmed/34790569
http://dx.doi.org/10.3389/fonc.2021.728224
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