Segmentation of lung parenchyma in CT images using CNN trained with the clustering algorithm generated dataset

Xu, Mingyu; Qi, Shouliang; Yue, Yong; Teng, Yueyang; Xu, Lisong; Yao, Yu-Dong; Qian, Wei

doi:10.1186/s12938-018-0619-9

Cited by 91 publications

(51 citation statements)

References 42 publications

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“…However, a real diagnosis model should be able to distinguish COPD from other airway diseases (e.g., asthma) and differentiate the severity of COPD (e.g., Global Initiative for Chronic Obstructive Lung Disease (GOLD) stage 2-4). Fourth, we only utilize the information of airway, but the lung parenchyma, patterns of LAA, air trapping, pulmonary blood vessels and medical record (e.g., demographic information, biomarkers, and some known medical diseases) are not included in the deep CNN model [4], [64]. Inclusion of the above information will likely improve the prediction performance.…”

Section: F Limitations and Future Workmentioning

confidence: 99%

Identification of COPD From Multi-View Snapshots of 3D Lung Airway Tree via Deep CNN

Feng³

et al. 2020

IEEE Access

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Chronic obstructive pulmonary disease (COPD) is associated with morphologic abnormalities of airways with various patterns and severities. However, the way of effectively representing these abnormalities is lacking and whether these abnormalities enable to distinguish COPD from healthy controls is unknown. We propose to use deep convolutional neural network (CNN) to assess 3D lung airway tree from the perspective of computer vision, thereby constructing models of identifying COPD. After extracting airway trees from CT images, snapshots of their 3D visualizations are obtained from ventral, dorsal and isometric views. Using snapshots of each view, one deep CNN model is constructed and further optimized by Bayesian optimization algorithm to indentify COPD. The majority voting of three views presents the final prediction. Finally, the class-discriminative localization maps have been drawn to visually explain the CNNs' decisions. The models trained with single view (ventral, dorsal and isometric) of colorful snapshots present the similar accuracy (ACC) (86.8%, 87.5% and 86.7%) and the model after voting achieves the ACC of 88.2%. The ACC of the final voting model using gray and binary snapshots achieves 88.6% and 86.4%, respectively. Our specially designed CNNs outperform the typical off-the-shelf CNNs and the pre-trained CNNs with fine tuning. The class-discriminative regions of COPD are mainly located at central airways; however, regions in HC are scattering and located at peripheral airways. It is feasible to identify COPD using snapshots of 3D lung airway tree extracted from CT images via deep CNN. The CNNs can represent the abnormalities of airway tree in COPD and make accurate CT-based diagnosis of COPD. INDEX TERMS Chronic obstructive pulmonary disease (COPD), deep learning, convolutional neural networks, computed tomography (CT), airway, image classification.

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Section: F Limitations and Future Workmentioning

confidence: 99%

Identification of COPD From Multi-View Snapshots of 3D Lung Airway Tree via Deep CNN

Feng³

et al. 2020

IEEE Access

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“…As well as, the third hyperparameter, the maximum number of depths of an individual tree is selected by finding the highest accuracy using a range from 2 to 20. As we can see in Figure 10c, the FR reached the highest accuracy (0.9285) at the depths (18); thus, we selected that number as the third hypermeter.…”

Section: Resultsmentioning

confidence: 99%

“…With the recent emergence of machine learning techniques, segmentation using machine-learning-algorithms became famous for lung cancer diagnosis. Multi-class pixel-wise segmentation using deep neural networks, such as SegNet [17] and CNN [18], are examples of deep-learning-based segmentation schemes. Due to the use of multiple network layers, these segmentations are in favor of unique feature learning [19].…”

Section: Introductionmentioning

confidence: 99%

Automatic Detection of Pulmonary Nodules using Three-dimensional Chain Coding and Optimized Random Forest

et al. 2020

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The detection of pulmonary nodules on computed tomography scans provides a clue for the early diagnosis of lung cancer. Manual detection mandates a heavy radiological workload as it identifies nodules slice-by-slice. This paper presents a fully automated nodule detection with three significant contributions. First, an automated seeded region growing is designed to segment the lung regions from the tomography scans. Second, a three-dimensional chain code algorithm is implemented to refine the border of the segmented lungs. Lastly, nodules inside the lungs are detected using an optimized random forest classifier. The experiments for our proposed detection are conducted using 888 scans from a public dataset, and achieves a favorable result of 93.11% accuracy, 94.86% sensitivity, and 91.37% specificity, with only 0.0863 false positives per exam.

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“…Moreover, since CT represents an important imaging biomarker and is pivotal to guide pharmacological management and improve ventilation strategies, further implementation of semi-automatic and/or fully automatic (AI-based) algorithms for image processing (12,13) might be beneficial in order to rapidly and systematically provide accurate data about the extent of lung disease in these patients.…”

Section: Discussionmentioning

confidence: 99%

Quantitative Assessment of Parenchymal Involvement Using 3D Lung Model in Adolescent With Covid-19 Interstitial Pneumonia

et al. 2020

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Background: Amount of parenchymal involvement in patients with interstitial pneumonia Covid-19 related, seems to be associated with a worse prognosis. Nowadays 3D reconstruction imaging is expanding its role in clinical medical practice. We aimed to use 3D lung reconstruction of a young lady affected by Sars-CoV2 infection and interstitial pneumonia, to better visualize, and quantitatively assess the parenchymal involvement. Methods: Volumetric Chest CT scan was performed in a 15 years old girl with interstitial lung pneumonia, Sars-CoV2 infection related. 3D modeling of the lungs, with differentiation of healthy and affected parenchymal area were obtained by using multiple software. Results: 3D reconstruction imaging allowed us to quantify the lung parenchyma involved, Self-explaining 3D images, useful for the understanding, and discussion of the clinical case were also obtained. Conclusions: Quantitative Assessment of Parenchymal Involvement Using 3D Lung Model in Covid-19 Infection is feasible and it provides information which could play a role in the management and risk stratification of these patients.

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Segmentation of lung parenchyma in CT images using CNN trained with the clustering algorithm generated dataset

Cited by 91 publications

References 42 publications

Identification of COPD From Multi-View Snapshots of 3D Lung Airway Tree via Deep CNN

Identification of COPD From Multi-View Snapshots of 3D Lung Airway Tree via Deep CNN

Automatic Detection of Pulmonary Nodules using Three-dimensional Chain Coding and Optimized Random Forest

Quantitative Assessment of Parenchymal Involvement Using 3D Lung Model in Adolescent With Covid-19 Interstitial Pneumonia

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