CT Imaging With Machine Learning for Predicting Progression to COPD in Individuals at Risk

Kalysta Makimoto; James C Hogg; Jean Bourbeau; Wan C Tan; Miranda Kirby

doi:10.1016/j.chest.2023.06.008

CT Imaging With Machine Learning for Predicting Progression to COPD in Individuals at Risk

Chest. 2023 Nov;164(5):1139-1149. doi: 10.1016/j.chest.2023.06.008. Epub 2023 Jun 17.

Authors

Kalysta Makimoto¹, James C Hogg², Jean Bourbeau³, Wan C Tan², Miranda Kirby⁴

Affiliations

¹ Toronto Metropolitan University, Toronto, ON, Canada.
² Center for Heart, Lung Innovation, University of British Columbia, Vancouver, BC, Canada.
³ Montreal Chest Institute of the Royal Victoria Hospital, McGill University Health Centre, Montreal, QC, Canada; Respiratory Epidemiology and Clinical Research Unit, Research Institute of McGill University Health Centre, Montreal, QC, Canada.
⁴ Toronto Metropolitan University, Toronto, ON, Canada. Electronic address: miranda.kirby@torontomu.ca.

PMID: 37421974
DOI: 10.1016/j.chest.2023.06.008

Abstract

Background: Identifying individuals at risk of progressing to COPD may allow for initiation of treatment to potentially slow the progression of the disease or the selection of subgroups for discovery of novel interventions.

Research question: Does the addition of CT imaging features, texture-based radiomic features, and established quantitative CT scan to conventional risk factors improve the performance for predicting progression to COPD in individuals who smoke with machine learning?

Study design and methods: Participants at risk (individuals who currently or formerly smoked, without COPD) from the Canadian Cohort Obstructive Lung Disease (CanCOLD) population-based study underwent CT imaging at baseline and spirometry at baseline and follow-up. Various combinations of CT scan features, texture-based CT scan radiomics (n = 95), and established quantitative CT scan (n = 8), as well as demographic (n = 5) and spirometry (n = 3) measurements, with machine learning algorithms were evaluated to predict progression to COPD. Performance metrics included the area under the receiver operating characteristic curve (AUC) to evaluate the models. DeLong test was used to compare the performance of the models.

Results: Among the 294 at-risk participants who were evaluated (mean age, 65.6 ± 9.2 years; 42% female; mean pack-years, 17.9 ± 18.7), 52 participants (23.7%) in the training data set and 17 participants (23.0%) in the testing data set progressed to spirometric COPD at follow-up (2.5 ± 0.9 years from baseline). Compared with machine learning models with demographics alone (AUC, 0.649), the addition of CT imaging features to demographics (AUC, 0.730; P < .05) or CT imaging features and spirometry to demographics (AUC, 0.877; P < .05) significantly improved the performance for predicting progression to COPD.

Interpretation: Heterogeneous structural changes occur in the lungs of individuals at risk that can be quantified using CT imaging features, and evaluation of these features together with conventional risk factors improves performance for predicting progression to COPD.

Keywords: COPD; CT scan; lung; machine learning; quantitative imaging; radiomics.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Aged
Canada / epidemiology
Female
Humans
Lung* / diagnostic imaging
Machine Learning
Male
Middle Aged
Pulmonary Disease, Chronic Obstructive* / diagnostic imaging
Tomography, X-Ray Computed / methods

Grants and funding

CIHR/Canada