Pathological lung segmentation based on random forest combined with deep model and multi-scale superpixels

Liu, Caixia; Zhao, Ran; Xie, Wangli; Pang, Mingyong

doi:10.1007/s11063-020-10330-8

Cited by 13 publications

(13 citation statements)

References 38 publications

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“…In this way, the number of interactions performed by the network decreased, and a DSC of 96.60% was obtained with a segmentation time of 11 s (GPU hardware) for each CT study with an unknown number of slices but certainly much less than 600 slices of an HRCT study. In [ 41 ], an algorithm based on random forest, deep convolutional network, and multi-scale super-pixels was proposed for segmenting lungs with interstitial lung disease (IDL) using the ILDs database [ 42 ] with an average DSC of 96.45%. Khanna et al [ 43 ] implemented the residual U-Net with a false-positive removal algorithm using a training set of 173 images from three publicly available benchmark datasets, namely LUNA, VESSEL12, and HUG-ILD.…”

Section: Discussionmentioning

confidence: 99%

Lung Segmentation on High-Resolution Computerized Tomography Images Using Deep Learning: A Preliminary Step for Radiomics Studies

et al. 2020

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Background: The aim of this work is to identify an automatic, accurate, and fast deep learning segmentation approach, applied to the parenchyma, using a very small dataset of high-resolution computed tomography images of patients with idiopathic pulmonary fibrosis. In this way, we aim to enhance the methodology performed by healthcare operators in radiomics studies where operator-independent segmentation methods must be used to correctly identify the target and, consequently, the texture-based prediction model. Methods: Two deep learning models were investigated: (i) U-Net, already used in many biomedical image segmentation tasks, and (ii) E-Net, used for image segmentation tasks in self-driving cars, where hardware availability is limited and accurate segmentation is critical for user safety. Our small image dataset is composed of 42 studies of patients with idiopathic pulmonary fibrosis, of which only 32 were used for the training phase. We compared the performance of the two models in terms of the similarity of their segmentation outcome with the gold standard and in terms of their resources’ requirements. Results: E-Net can be used to obtain accurate (dice similarity coefficient = 95.90%), fast (20.32 s), and clinically acceptable segmentation of the lung region. Conclusions: We demonstrated that deep learning models can be efficiently applied to rapidly segment and quantify the parenchyma of patients with pulmonary fibrosis, without any radiologist supervision, in order to produce user-independent results.

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Section: Discussionmentioning

confidence: 99%

Lung Segmentation on High-Resolution Computerized Tomography Images Using Deep Learning: A Preliminary Step for Radiomics Studies

et al. 2020

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“…(2) The Gini coefficient is used to calculate the optimal separation method of each feature for each node in the classification tree. The more the Gini value decreases, the more important the feature becomes [ 13 ]. Finally, the diagnostic efficiency of the random forest model is calculated by confusion matrix.…”

Section: Methodsmentioning

confidence: 99%

Construction of Pulmonary Nodule CT Radiomics Random Forest Model Based on Artificial Intelligence Software for STAS Evaluation of Stage IA Lung Adenocarcinoma

Liu

et al. 2022

Computational and Mathematical Methods in Medicine

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Objective. Spread through air space (STAS) is an invasive characterization of lung adenocarcinoma and is regarded as a risk factor for poor prognosis. The aim of this study is to develop a random forest model for preoperative prediction of spread through air spaces (STAS) in stage IA lung adenocarcinoma. Methods. 92 patients with stage IA lung adenocarcinoma, who underwent computed tomography (CT) scan and surgical resection, were retrospectively reviewed. Each pulmonary nodule was automatically segmented by artificial intelligence (AI) software, and its CT-based radiomics were extracted. All patients were pathologically classified into STAS-negative and STAS-positive cohorts; then, clinical pathological and CT-based radiomics were compared between the two cohorts. Finally, a prediction model for evaluating STAS status in stage IA lung adenocarcinoma was established by a random forest model. Results. Among 92 patients with stage IA lung adenocarcinoma, STAS positive was identified in 19 patients. The random forest classification model identified predictive features, including CT maximum value, consolidation to tumor ratio (CTR), 3D diameter, CT mean value, entropy, and CT minimum value. The misclassification rate of the random forest model is only 7.69%. Conclusion. The risk factors of STAS in stage IA lung adenocarcinoma can be effectively identified based on the random forest model, and the hierarchical management of characteristic risk can be effectively realized. A random forest model for predicting STAS in IA lung adenocarcinoma is simple and practical.

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“…More meaningful features can also be extracted by aggregating an auxiliary classification branch, enriching the information used for backpropagation [ 160 , 170 ]. Liu et al [ 171 ] integrated different feature extraction branches by combining deep, textured, and intensity features, to be classified as part of the lung mask or background.…”

Section: Computer-aided Decision Systemsmentioning

confidence: 99%

Towards Machine Learning-Aided Lung Cancer Clinical Routines: Approaches and Open Challenges

Silva

Pereira

Neves

et al. 2022

JPM

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Advancements in the development of computer-aided decision (CAD) systems for clinical routines provide unquestionable benefits in connecting human medical expertise with machine intelligence, to achieve better quality healthcare. Considering the large number of incidences and mortality numbers associated with lung cancer, there is a need for the most accurate clinical procedures; thus, the possibility of using artificial intelligence (AI) tools for decision support is becoming a closer reality. At any stage of the lung cancer clinical pathway, specific obstacles are identified and “motivate” the application of innovative AI solutions. This work provides a comprehensive review of the most recent research dedicated toward the development of CAD tools using computed tomography images for lung cancer-related tasks. We discuss the major challenges and provide critical perspectives on future directions. Although we focus on lung cancer in this review, we also provide a more clear definition of the path used to integrate AI in healthcare, emphasizing fundamental research points that are crucial for overcoming current barriers.

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Pathological lung segmentation based on random forest combined with deep model and multi-scale superpixels

Cited by 13 publications

References 38 publications

Lung Segmentation on High-Resolution Computerized Tomography Images Using Deep Learning: A Preliminary Step for Radiomics Studies

Lung Segmentation on High-Resolution Computerized Tomography Images Using Deep Learning: A Preliminary Step for Radiomics Studies

Construction of Pulmonary Nodule CT Radiomics Random Forest Model Based on Artificial Intelligence Software for STAS Evaluation of Stage IA Lung Adenocarcinoma

Towards Machine Learning-Aided Lung Cancer Clinical Routines: Approaches and Open Challenges

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