Deep convolutional neural networks with multiplane consensus labeling for lung function quantification using UTE proton MRI

Zha, Wei; Fain, Sean B.; Schiebler, Mark L.; Evans, Michael D.; Nagle, Scott K.; Liu, Fang

doi:10.1002/jmri.26734

Cited by 22 publications

(21 citation statements)

References 45 publications

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“…One example of the application of U-Nets to functional modalities is the use of a 2D U-Net to perform volumetric lung segmentation from UTE proton MRI in a multiplane fashion. 11 Despite reduced contrast around the lung boundaries, the lung volume estimates in a set of asthmatic and cystic fibrotic patients closely matched the reference values ( Figure 2 ). One caveat for the application of deep learning is the limited availability of training data.…”

Section: Ai In Functional Quantificationsupporting

confidence: 55%

Artificial intelligence in functional imaging of the lung

Estépar

2022

BJR

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Artificial intelligence (AI) is transforming the way we perform advanced imaging. From high-resolution image reconstruction to predicting functional response from clinically acquired data, AI is promising to revolutionize clinical evaluation of lung performance, pushing the boundary in pulmonary functional imaging for patients suffering from respiratory conditions. In this review, we overview the current developments and expound on some of the encouraging new frontiers. We focus on the recent advances in machine learning and deep learning that enable reconstructing images, quantitating, and predicting functional responses of the lung. Finally, we shed light on the potential opportunities and challenges ahead in adopting AI for functional lung imaging in clinical settings.

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Section: Ai In Functional Quantificationsupporting

confidence: 55%

Artificial intelligence in functional imaging of the lung

Estépar

2022

BJR

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“…However, using the same dataset, AI algorithms could be trained for detection tasks. Further evaluation using alternative strategies such as multiple CNNs with major voting [31], multiplane consensus labeling [32], or 3D AI algorithms [33] would be worth evaluating, albeit with a heavy computational burden. We used 2D-CNN to train the model in a slice-by-slice fashion to account for pleural plaque localization, or shape heterogeneity.…”

Section: Discussionmentioning

confidence: 99%

Deep Learning for the Automatic Quantification of Pleural Plaques in Asbestos-Exposed Subjects

Benlala

Dournes

Menant

et al. 2022

IJERPH

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Objective: This study aimed to develop and validate an automated artificial intelligence (AI)-driven quantification of pleural plaques in a population of retired workers previously occupationally exposed to asbestos. Methods: CT scans of former workers previously occupationally exposed to asbestos who participated in the multicenter APEXS (Asbestos PostExposure Survey) study were collected retrospectively between 2010 and 2017 during the second and the third rounds of the survey. A hundred and forty-one participants with pleural plaques identified by expert radiologists at the 2nd and the 3rd CT screenings were included. Maximum Intensity Projection (MIP) with 5 mm thickness was used to reduce the number of CT slices for manual delineation. A Deep Learning AI algorithm using 2D-convolutional neural networks was trained with 8280 images from 138 CT scans of 69 participants for the semantic labeling of Pleural Plaques (PP). In all, 2160 CT images from 36 CT scans of 18 participants were used for AI testing versus ground-truth labels (GT). The clinical validity of the method was evaluated longitudinally in 54 participants with pleural plaques. Results: The concordance correlation coefficient (CCC) between AI-driven and GT was almost perfect (>0.98) for the volume extent of both PP and calcified PP. The 2D pixel similarity overlap of AI versus GT was good (DICE = 0.63) for PP, whether they were calcified or not, and very good (DICE = 0.82) for calcified PP. A longitudinal comparison of the volumetric extent of PP showed a significant increase in PP volumes (p < 0.001) between the 2nd and the 3rd CT screenings with an average delay of 5 years. Conclusions: AI allows a fully automated volumetric quantification of pleural plaques showing volumetric progression of PP over a five-year period. The reproducible PP volume evaluation may enable further investigations for the comprehension of the unclear relationships between pleural plaques and both respiratory function and occurrence of thoracic malignancy.

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“…Notably, implanted ports and peripherally inserted central catheters within image fields can interfere with the deep learning algorithm, which may make the translation to CF more difficult. Deep convolutional neural networks are under investigation for automating many imaging analyses, for example, identification of expiratory air trapping on CT 146 and 3D lung segmentation of MR images, 147 and their increased application in identification of characteristic CF lung disease in several imaging methodologies is anticipated.…”

Section: Future Directionsmentioning

confidence: 99%

Novel imaging techniques for cystic fibrosis lung disease

Goralski

Stewart

Woods

2021

Pediatric Pulmonology

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With an increasing number of patients with cystic fibrosis (CF) receiving highly effective CFTR (cystic fibrosis transmembrane regulator protein) modulator therapy, particularly at a young age, there is an increasing need to identify imaging tools that can detect and regionally visualize mild CF lung disease and subtle changes in disease state. In this review, we discuss the latest developments in imaging modalities for both structural and functional imaging of the lung available to CF clinicians and researchers, from the widely available, clinically utilized imaging methods for assessing CF lung disease—chest radiography and computed tomography—to newer techniques poised to become the next phase of clinical tools—structural/functional proton and hyperpolarized gas magnetic resonance imaging (MRI). Finally, we provide a brief discussion of several newer lung imaging techniques that are currently available only in selected research settings, including chest tomosynthesis, and fluorinated gas MRI. We provide an update on the clinical and/or research status of each technique, with a focus on sensitivity, early disease detection, and possibilities for monitoring treatment efficacy.

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Deep convolutional neural networks with multiplane consensus labeling for lung function quantification using UTE proton MRI

Cited by 22 publications

References 45 publications

Artificial intelligence in functional imaging of the lung

Artificial intelligence in functional imaging of the lung

Deep Learning for the Automatic Quantification of Pleural Plaques in Asbestos-Exposed Subjects

Novel imaging techniques for cystic fibrosis lung disease

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