Deep Learning for Classification of Bone Lesions on Routine MRI

Eweje, Feyisope; Bao, Bingting; Wu, Jing; Dalal, Deepa; Liao, Wei; He, Yu; Luo, Yongheng; Lu, Shaolei; Zhang, Paul; Peng, Xuebiao; Sebro, Ronnie; Bai, Harrison X.; States, Lisa J.

doi:10.1016/j.ebiom.2021.103402

Cited by 54 publications

(41 citation statements)

References 42 publications

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“…In orthopedics, there are a few studies which use deep learning algorithms for classifying bone lesions. Compared with the method proposed by Feyisope R. Eweje et al [ 1 ] which requires the segmentation of the images before training, the proposed method requires no prior segmentation due to the fact that the classifier used for T1 and T2 images is a pretrained ResNet50, which classifies the entire image as benignant or malign. Even more so, the clinical model is a neural network classifier, with an input layer of six neurons, one hidden layer with three neurons, and one neuron as an output ( Figure 5 ).…”

Section: Discussionmentioning

confidence: 99%

“…The ResNet50 [ 24 ] architecture of the proposed system can be found in Table 2 . Feyisope R. et al [ 1 ] proposed a similar methodology for classifying bone tumors in which they have two models for predicting the output and a logistic regression for the clinical model. In their study, the MRI scans were manually segmented by a radiologist and the resulting images were used for training.…”

Section: Proposed Methodsmentioning

confidence: 99%

“…In their study, the MRI scans were manually segmented by a radiologist and the resulting images were used for training. Also, for the clinical model, Feyisope R. et al [ 1 ] used as input the following information: sex, age, and lesion location. The image classifier used in their study is a pretrained EfficientNet [ 31 ].…”

Section: Proposed Methodsmentioning

confidence: 99%

“…By using pretrained CNNs, the model is converging fast during training, and it can train on a small dataset. While other studies have proposed a manual segmentation of the images [ 1 ], in our study the images are not manually segmented but are sent to the training pipeline as a whole in order to predict the malignancy based on the entire image. In addition, the proposed clinical model has as inputs the values predicted by the two residual CNNs models and the bone location of the tumor.…”

Section: Introductionmentioning

confidence: 99%

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Malignant Bone Tumors Diagnosis Using Magnetic Resonance Imaging Based on Deep Learning Algorithms

et al. 2022

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Background and Objectives: Malignant bone tumors represent a major problem due to their aggressiveness and low survival rate. One of the determining factors for improving vital and functional prognosis is the shortening of the time between the onset of symptoms and the moment when treatment starts. The objective of the study is to predict the malignancy of a bone tumor from magnetic resonance imaging (MRI) using deep learning algorithms. Materials and Methods: The cohort contained 23 patients in the study (14 women and 9 men with ages between 15 and 80). Two pretrained ResNet50 image classifiers are used to classify T1 and T2 weighted MRI scans. To predict the malignancy of a tumor, a clinical model is used. The model is a feed forward neural network whose inputs are patient clinical data and the output values of T1 and T2 classifiers. Results: For the training step, the accuracies of 93.67% for the T1 classifier and 86.67% for the T2 classifier were obtained. In validation, both classifiers obtained 95.00% accuracy. The clinical model had an accuracy of 80.84% for training phase and 80.56% for validation. The receiver operating characteristic curve (ROC) of the clinical model shows that the algorithm can perform class separation. Conclusions: The proposed method is based on pretrained deep learning classifiers which do not require a manual segmentation of the MRI images. These algorithms can be used to predict the malignancy of a tumor and on the other hand can shorten the time of their diagnosis and treatment process. While the proposed method requires minimal intervention from an imagist, it needs to be tested on a larger cohort of patients.

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Section: Discussionmentioning

confidence: 99%

Section: Proposed Methodsmentioning

confidence: 99%

Section: Proposed Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Malignant Bone Tumors Diagnosis Using Magnetic Resonance Imaging Based on Deep Learning Algorithms

et al. 2022

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“…As early as the 1980s, 1 it was understood that AI tools could eventually play a major role as expert consultants to physicians by using insights from data that may not be deemed actionable by human interpretation. From convolutional neural networks for imaging-based solid organ cancer screening 2 , 3 , 4 to natural language processing (NLP) to estimate the probability of diagnoses with data from the electronic health record, 5 , 6 , 7 the breadth of AI-powered technologies affecting our understanding of human health and health care delivery processes has rapidly expanded in recent years. 8 …”

Section: Introductionmentioning

confidence: 99%

Translatability Analysis of National Institutes of Health–Funded Biomedical Research That Applies Artificial Intelligence

et al. 2022

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Key Points Question Which applications of artificial intelligence (AI) in biomedical research could generate the most translational value (ie, ability to lead to development that has measurable value for human health)? Findings In this cohort study using bibliometric analysis, 2 citation-based metrics were used as proxies for translational impact, and 75 unique medical applications of AI were identified from a set of 16 629 National Institutes of Health awards related to AI, using natural language processing. Varied applications were found to have high translatability, but bias against applications in basic biochemical analysis was evident. Meaning These findings suggest that National Institutes of Health award data applications of AI in biomedical research are not equivalent: some demonstrate greater potential for translational impact than others.

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Use of Artificial Intelligence in Imaging for Bone Cancer

2024

Artificial Intelligence for Bone Disorder

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Deep Learning for Classification of Bone Lesions on Routine MRI

Cited by 54 publications

References 42 publications

Malignant Bone Tumors Diagnosis Using Magnetic Resonance Imaging Based on Deep Learning Algorithms

Malignant Bone Tumors Diagnosis Using Magnetic Resonance Imaging Based on Deep Learning Algorithms

Translatability Analysis of National Institutes of Health–Funded Biomedical Research That Applies Artificial Intelligence

Use of Artificial Intelligence in Imaging for Bone Cancer

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