Jeanny Pan scite author profile

Background: Automated segmentation of anatomical structures is a crucial step in image analysis. For lung segmentation in computed tomography, a variety of approaches exists, involving sophisticated pipelines trained and validated on different datasets. However, the clinical applicability of these approaches across diseases remains limited. Methods: We compared four generic deep learning approaches trained on various datasets and two readily available lung segmentation algorithms. We performed evaluation on routine imaging data with more than six different disease patterns and three published data sets. Results: Using different deep learning approaches, mean Dice similarity coefficients (DSCs) on test datasets varied not over 0.02. When trained on a diverse routine dataset (n = 36), a standard approach (U-net) yields a higher DSC (0.97 ± 0.05) compared to training on public datasets such as the Lung Tissue Research Consortium (0.94 ± 0.13, p = 0.024) or Anatomy 3 (0.92 ± 0.15, p = 0.001). Trained on routine data (n = 231) covering multiple diseases, U-net compared to reference methods yields a DSC of 0.98 ± 0.03 versus 0.94 ± 0.12 (p = 0.024). Conclusions: The accuracy and reliability of lung segmentation algorithms on demanding cases primarily relies on the diversity of the training data, highlighting the importance of data diversity compared to model choice. Efforts in developing new datasets and providing trained models to the public are critical. By releasing the trained model under General Public License 3.0, we aim to foster research on lung diseases by providing a readily available tool for segmentation of pathological lungs.

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Variability of computed tomography radiomics features of fibrosing interstitial lung disease: A test-retest study

Prayer

Hofmanninger

Weber

et al. 2021

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Unsupervised machine learning identifies predictive progression markers of IPF

et al. 2022

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Objectives To identify and evaluate predictive lung imaging markers and their pathways of change during progression of idiopathic pulmonary fibrosis (IPF) from sequential data of an IPF cohort. To test if these imaging markers predict outcome. Methods We studied radiological disease progression in 76 patients with IPF, including overall 190 computed tomography (CT) examinations of the chest. An algorithm identified candidates for imaging patterns marking progression by computationally clustering visual CT features. A classification algorithm selected clusters associated with radiological disease progression by testing their value for recognizing the temporal sequence of examinations. This resulted in radiological disease progression signatures, and pathways of lung tissue change accompanying progression observed across the cohort. Finally, we tested if the dynamics of marker patterns predict outcome, and performed an external validation study on a cohort from a different center. Results Progression marker patterns were identified and exhibited high stability in a repeatability experiment with 20 random sub-cohorts of the overall cohort. The 4 top-ranked progression markers were consistently selected as most informative for progression across all random sub-cohorts. After spatial image registration, local tracking of lung pattern transitions revealed a network of tissue transition pathways from healthy to a sequence of disease tissues. The progression markers were predictive for outcome, and the model achieved comparable results on a replication cohort. Conclusions Unsupervised learning can identify radiological disease progression markers that predict outcome. Local tracking of pattern transitions reveals pathways of radiological disease progression from healthy lung tissue through a sequence of diseased tissue types. Key Points • Unsupervised learning can identify radiological disease progression markers that predict outcome in patients with idiopathic pulmonary fibrosis. • Local tracking of pattern transitions reveals pathways of radiological disease progression from healthy lung tissue through a sequence of diseased tissue types. • The progression markers achieved comparable results on a replication cohort.

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Künstliche Intelligenz in der Bildgebung der Lunge

et al. 2019

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Künstliche Intelligenz in der Bildgebung der Lunge Künstliche Intelligenz (KI) stellt seit einigen Jahren einen der Forschungsschwerpunkte in der Thoraxradiologie dar. Mithilfe von Algorithmen sollen in Zukunft Detektion, Quantifizierung, Charakterisierung und Verlaufsprädiktion von Lungenpathologien in der Computertomographie (CT) verbessert werden. In diesem Übersichtsartikel werden die neuesten Entwicklungen im Bereich der künstlichen Intelligenz in der CT der Lunge mit Fokus auf pulmonale Rundherde und interstitielle Lungenerkrankungen beleuchtet.

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Jeanny Pan

Automatic lung segmentation in routine imaging is primarily a data diversity problem, not a methodology problem

Variability of computed tomography radiomics features of fibrosing interstitial lung disease: A test-retest study

Unsupervised machine learning identifies predictive progression markers of IPF

Künstliche Intelligenz in der Bildgebung der Lunge

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