CT and COPD: AI with previously unknown potential

Chronic obstructive pulmonary disease (COPD) is the third most common cause of death around the world. It is generally accepted that CT imaging helps quantify the disease. Until now, lung function analysis has been understood as diagnostic gold standard. Recently, AI demonstrates its full capacity to comprehensively assist in the diagnosis and visualization of the fundamental COPD pathologies in cross sectional imaging.

It is with great pleasure that we present Coreline´s aview COPD, an AI assistant for the detailed visualization of COPD in lung CT studies.

Why aview COPD matters and how it works

The AI assistant classifies and quantitatively analyses two COPD phenotypes, i.e., the airway type and the emphysema type. This automatic segmentation software provides expedite analysis and visualization of the lungs, the lung lobes as well as the pulmonary airways and blood vessels. The results are presented through 2D and 3D images, intuitive charts and detailed graphs. An important key feature is the tracking of disease in follow up CT studies. Hence, aview COPD may serve as an imaging biomarker of diagnosis and lung function. This AI assistant can be used both for individual patients and in large departments for pulmonology.

Who benefits

Patients, clinicians and radiologists by the clear description of major COPD patterns and the follow up tracking of the disease. In particular, the 2D and 3D visualization of the lungs, lobes, airways and blood vessels is a welcome help for interdisciplinary and patient communication.

Our own experience at Radailogy

Coreline reports the AI assistant´s analysis agreement for emphysema, airway and air trapping as 99%, 96% and 99%, respectively. aview COPD offers a variety of MPR images, diagrams and graphs to illustrate the pulmonary anatomy and disease as well as the distribution pattern of COPD. An interesting feature is the analysis and depiction of emphysema clusters using the D-slope value by applying a three-dimensional size-based emphysema clustering technique. For the calculation of D-slope, the diameter of the emphysema cluster is plotted against the cumulative number of lesions on a log–log scale. The slope (D-slope) of these linear relationships is calculated, with a steeper slope (increase in absolute D value) indicating a smaller emphysema size. The airway and lung vessel segmentation, the morphology and pathology of the airway walls and diameter are shown by 3D images and detailed tables. In our opinion, the fissure analysis is of limited help. Overall, the visualized contents enhance the understanding of pulmonary morphology and pathology.  We consider aview COPD capable of shortening the radiologists´ workload while increasing the professional efficiency.

We also evaluated aview COPD together with aview LCS, which was developed to detect and quantify pulmonary nodules in CT studies. Find out more in our AI assistant menu!

The scientific evidence

Hwang HJ, Lee SM, Seo JB, Lee JS, Kim N, Lee SW, Oh YM. New Method for Combined Quantitative Assessment of Air-Trapping and Emphysema on Chest Computed Tomography in Chronic Obstructive Pulmonary Disease: Comparison with Parametric Response Mapping. Korean J Radiol. 2021 Oct;22(10):1719-1729.

Hwang HJ, Seo JB, Lee SM, Kim N, Yi J, Lee JS, Lee SW, Oh YM, Lee SD. Visual and Quantitative Assessments of Regional Xenon-Ventilation Using Dual-Energy CT in Asthma-Chronic Obstructive Pulmonary Disease Overlap Syndrome: A Comparison with Chronic Obstructive Pulmonary Disease. Korean J Radiol. 2020 Sep;21(9):1104-1113.

Data to upload to Radailogy

Non-enhanced low-dose chest CT studies of any CT scanner; axial reformations; slice thickness and interval 1.0 mm each; lung reconstruction kernel