Abstract
BACKGROUNDCurrently recommended traditional spirometry outputs do not reflect the relative contributions of emphysema and airway disease to airflow obstruction. We hypothesized that machine-learning algorithms can be trained on spirometry data to identify these structural phenotypes.METHODSParticipants enrolled in a large multicenter study (COPDGene) were included. The data points from expiratory flow-volume curves were trained using a deep-learning model to predict structural phenotypes of chronic obstructive pulmonary disease (COPD) on CT, and results were compared with traditional spirometry metrics and an optimized random forest classifier. Area under the receiver operating characteristic curve (AUC) and weighted F-score were used to measure the discriminative accuracy of a fully convolutional neural network, random forest, and traditional spirometry metrics to phenotype CT as normal, emphysema-predominant (>5% emphysema), airway-predominant (Pi10 > median), and mixed phenotypes. Similar comparisons were made for the detection of functional small airway disease phenotype (>20% on parametric response mapping).RESULTSAmong 8980 individuals, the neural network was more accurate in discriminating predominant emphysema/airway phenotypes (AUC 0.80, 95%CI 0.79-0.81) compared with traditional measures of spirometry, FEV1/FVC (AUC 0.71, 95%CI 0.69-0.71), FEV1% predicted (AUC 0.70, 95%CI 0.68-0.71), and random forest classifier (AUC 0.78, 95%CI 0.77-0.79). The neural network was also more accurate in discriminating predominant emphysema/small airway phenotypes (AUC 0.91, 95%CI 0.90-0.92) compared with FEV1/FVC (AUC 0.80, 95%CI 0.78-0.82), FEV1% predicted (AUC 0.83, 95%CI 0.80-0.84), and with comparable accuracy with random forest classifier (AUC 0.90, 95%CI 0.88-0.91).CONCLUSIONSStructural phenotypes of COPD can be identified from spirometry using deep-learning and machine-learning approaches, demonstrating their potential to identify individuals for targeted therapies.TRIAL REGISTRATIONClinicalTrials.gov NCT00608764.FUNDINGThis study was supported by NIH grants K23 HL133438 and R21EB027891 and an American Thoracic Foundation 2018 Unrestricted Research Grant. The COPDGene study is supported by NIH grants NHLBI U01 HL089897 and U01 HL089856. The COPDGene study (NCT00608764) is also supported by the COPD Foundation through contributions made to an Industry Advisory Committee comprising AstraZeneca, Boehringer-Ingelheim, GlaxoSmithKline, Novartis, and Sunovion.
Highlights
Chronic obstructive pulmonary disease (COPD) is an inflammatory disease of the lungs that is associated with substantial respiratory morbidity and health care costs and is the fourth leading cause of death in the United States [1]
COPD is defined by persistent airflow obstruction on spirometry, the result of a combination of 2 distinct structural processes: emphysema characterized by alveolar destruction and poor elastic recoil of the lungs as well as airway disease characterized by airway narrowing and remodeling [2, 3]
These findings suggest that the existing spirometry criteria for airflow obstruction are not sensitive to the contributory structural changes
Summary
Chronic obstructive pulmonary disease (COPD) is an inflammatory disease of the lungs that is associated with substantial respiratory morbidity and health care costs and is the fourth leading cause of death in the United States [1]. Recent studies demonstrate that approximately half of current and former smokers, with no evidence of spirometric airflow obstruction according to traditional criteria, have evidence of emphysema and/or airway disease [4, 5]. These findings suggest that the existing spirometry criteria for airflow obstruction are not sensitive to the contributory structural changes. The degree of emphysema and airway wall thickening on CT are both independently associated with worse respiratory quality of life, dyspnea, and mortality [7,8,9,10,11,12,13] Despite these associations, CT is often not recommended for diagnosis in clinical practice due to concerns about high costs and risk of radiation. We hypothesized that machine-learning algorithms can be trained on spirometry data to identify these structural phenotypes
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