Radiomics-Based Machine Learning in Differentiation Between Glioblastoma and Metastatic Brain Tumors

Chen, Chaoyue; Ou, Xuejin; Wang, Jian; Guo, Wen; Ma, Xuelei

doi:10.3389/fonc.2019.00806

Cited by 78 publications

(65 citation statements)

References 23 publications

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“…Regarding the differentiation of GBM from SBM, we know that there are multiple radiological techniques available for pre-operative or non-invasive applications ( 5 , 8 – 11 , 13 , 15 – 17 , 55 ); besides, intraoperative histopathological techniques are currently the reference parameter for decision-making ( 56 ). Our study does not intend to make a comparison with the techniques mentioned above but to demonstrate, on the one hand, the high value that ultrasound and especially elastography owns in the study of brain tumors, and on the other hand, highlight that automatic image processing is a highly reliable technique.…”

Section: Discussionmentioning

confidence: 99%

Comparison of Intraoperative Ultrasound B-Mode and Strain Elastography for the Differentiation of Glioblastomas From Solitary Brain Metastases. An Automated Deep Learning Approach for Image Analysis

et al. 2021

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BackgroundThe differential diagnosis of glioblastomas (GBM) from solitary brain metastases (SBM) is essential because the surgical strategy varies according to the histopathological diagnosis. Intraoperative ultrasound elastography (IOUS-E) is a relatively novel technique implemented in the surgical management of brain tumors that provides additional information about the elasticity of tissues. This study compares the discriminative capacity of intraoperative ultrasound B-mode and strain elastography to differentiate GBM from SBM.MethodsWe performed a retrospective analysis of patients who underwent craniotomy between March 2018 to June 2020 with glioblastoma (GBM) and solitary brain metastases (SBM) diagnoses. Cases with an intraoperative ultrasound study were included. Images were acquired before dural opening, first in B-mode, and then using the strain elastography module. After image pre-processing, an analysis based on deep learning was conducted using the open-source software Orange. We have trained an existing neural network to classify tumors into GBM and SBM via the transfer learning method using Inception V3. Then, logistic regression (LR) with LASSO (least absolute shrinkage and selection operator) regularization, support vector machine (SVM), random forest (RF), neural network (NN), and k-nearest neighbor (kNN) were used as classification algorithms. After the models’ training, ten-fold stratified cross-validation was performed. The models were evaluated using the area under the curve (AUC), classification accuracy, and precision.ResultsA total of 36 patients were included in the analysis, 26 GBM and 10 SBM. Models were built using a total of 812 ultrasound images, 435 of B-mode, 265 (60.92%) corresponded to GBM and 170 (39.8%) to metastases. In addition, 377 elastograms, 232 (61.54%) GBM and 145 (38.46%) metastases were analyzed. For B-mode, AUC and accuracy values of the classification algorithms ranged from 0.790 to 0.943 and from 72 to 89%, respectively. For elastography, AUC and accuracy values ranged from 0.847 to 0.985 and from 79% to 95%, respectively.ConclusionAutomated processing of ultrasound images through deep learning can generate high-precision classification algorithms that differentiate glioblastomas from metastases using intraoperative ultrasound. The best performance regarding AUC was achieved by the elastography-based model supporting the additional diagnostic value that this technique provides.

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Section: Discussionmentioning

confidence: 99%

Comparison of Intraoperative Ultrasound B-Mode and Strain Elastography for the Differentiation of Glioblastomas From Solitary Brain Metastases. An Automated Deep Learning Approach for Image Analysis

et al. 2021

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“…Two classi cation tasks of different di culty levels were performed using radiomics features extracted from brain magnetic resonance imaging (MRI). The rst task was a "simple" task of differentiating between glioblastoma (GBM) and single metastasis; the accuracy of radiomics-based ML for this task has been reported to be up to 90% (12,13). In the current study, the rst task dataset consisted of 167 adult patients with pathologically con rmed single GBM (n=109) or brain metastasis (n=58) following brain MRI between January 2014 and December 2017.…”

Section: Subjectsmentioning

confidence: 99%

Radiomics machine learning study with small sample size: single random training-test set split may result in unreliable results

Park

Ahn

et al. 2020

Preprint

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Objective: This study aims to determine how randomly splitting a dataset into training and test sets affects the estimated performance of a machine learning model under different conditions, using real-world brain tumor radiomics data.Materials and Methods: We conducted two classification tasks of different difficulty levels with magnetic resonance imaging (MRI) radiomics features: (1) “Simple” task, glioblastomas [n=109] vs. brain metastasis [n=58] and (2) “difficult” task, low- [n=163] vs. high-grade [n=95] meningiomas. Additionally, two undersampled datasets were created by randomly sampling 50% from these datasets. We performed random training-test set splitting for each dataset repeatedly to create 1,000 different training and test set pairs. For each dataset pair, the least absolute shrinkage and selection operator model was trained by five-fold cross-validation (CV) or nested CV with or without repetitions in the training set and tested with the test set, using the area under the curve (AUC) as an evaluation metric.Results: The AUCs in CV and testing varied widely based on data composition, especially with the undersampled datasets and the difficult task. The mean (±standard deviation) AUC difference between CV and testing was 0.029 (±0.022) for the simple task without undersampling and 0.108 (±0.079) for the difficult task with undersampling. In a training-test set pair, the AUC was high in CV but much lower in testing (0.840 and 0.650, respectively); in another dataset pair with the same task, however, the AUC was low in CV but much higher in testing (0.702 and 0.836, respectively). None of the CV methods helped overcome this issue.Conclusions: Machine learning after a single random training-test set split may lead to unreliable results in radiomics studies, especially when the sample size is small.

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“…Radiomics allows advanced non-invasive assessment of complex imaging features obtained by MRI that may serve as biomarkers [ 46 , 47 ] of disease aggressivity or response. Although these major advances in imaging techniques have substantially improved our ability to diagnose brain tumors, including GBM, overall survival and prognosis for patients with GBM continues to be poor, mostly due to inherent and developed resistance against standard-of-care therapy.…”

Section: History and Current Status Of Gbm Detection And Imaging Tmentioning

confidence: 99%

Radioresistance in Glioblastoma and the Development of Radiosensitizers

Ali

Oliva

Noman

et al. 2020

Cancers

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Ionizing radiation is a common and effective therapeutic option for the treatment of glioblastoma (GBM). Unfortunately, some GBMs are relatively radioresistant and patients have worse outcomes after radiation treatment. The mechanisms underlying intrinsic radioresistance in GBM has been rigorously investigated over the past several years, but the complex interaction of the cellular molecules and signaling pathways involved in radioresistance remains incompletely defined. A clinically effective radiosensitizer that overcomes radioresistance has yet to be identified. In this review, we discuss the current status of radiation treatment in GBM, including advances in imaging techniques that have facilitated more accurate diagnosis, and the identified mechanisms of GBM radioresistance. In addition, we provide a summary of the candidate GBM radiosensitizers being investigated, including an update of subjects enrolled in clinical trials. Overall, this review highlights the importance of understanding the mechanisms of GBM radioresistance to facilitate the development of effective radiosensitizers.

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Radiomics-Based Machine Learning in Differentiation Between Glioblastoma and Metastatic Brain Tumors

Cited by 78 publications

References 23 publications

Comparison of Intraoperative Ultrasound B-Mode and Strain Elastography for the Differentiation of Glioblastomas From Solitary Brain Metastases. An Automated Deep Learning Approach for Image Analysis

Comparison of Intraoperative Ultrasound B-Mode and Strain Elastography for the Differentiation of Glioblastomas From Solitary Brain Metastases. An Automated Deep Learning Approach for Image Analysis

Radiomics machine learning study with small sample size: single random training-test set split may result in unreliable results

Radioresistance in Glioblastoma and the Development of Radiosensitizers

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