Abstract
Introduction: Quantitative computed tomography (qCT) is an emergent technique for diagnostics and research in patients with chronic obstructive pulmonary disease (COPD). qCT parameters demonstrate a correlation with pulmonary function tests and symptoms. However, qCT only provides anatomical, not functional, information. We evaluated five distinct, partial-machine learning-based mathematical models to predict lung function parameters from qCT values in comparison with pulmonary function tests. Methods: 75 patients with diagnosed COPD underwent body plethysmography and a dose-optimized qCT examination on a third-generation, dual-source CT with inspiration and expiration. Delta values (inspiration—expiration) were calculated afterwards. Four parameters were quantified: mean lung density, lung volume low-attenuated volume, and full width at half maximum. Five models were evaluated for best prediction: average prediction, median prediction, k-nearest neighbours (kNN), gradient boosting, and multilayer perceptron. Results: The lowest mean relative error (MRE) was calculated for the kNN model with 16%. Similar low MREs were found for polynomial regression as well as gradient boosting-based prediction. Other models led to higher MREs and thereby worse predictive performance. Beyond the sole MRE, distinct differences in prediction performance, dependent on the initial dataset (expiration, inspiration, delta), were found. Conclusion: Different, partially machine learning-based models allow the prediction of lung function values from static qCT parameters within a reasonable margin of error. Therefore, qCT parameters may contain more information than we currently utilize and can potentially augment standard functional lung testing.
Highlights
Quantitative computed tomography is an emergent technique for diagnostics and research in patients with chronic obstructive pulmonary disease (COPD).qCT parameters demonstrate a correlation with pulmonary function tests and symptoms
These values were used in the additional analysis for comparison the are regression, different values demonstrated best mean relative error
These values were used in additional analysis for comparison with the performance parameters of other mathematical models
Summary
Quantitative computed tomography (qCT) is an emergent technique for diagnostics and research in patients with chronic obstructive pulmonary disease (COPD). QCT parameters demonstrate a correlation with pulmonary function tests and symptoms. Partial-machine learning-based mathematical models to predict lung function parameters from qCT values in comparison with pulmonary function tests. Results: The lowest mean relative error (MRE) was calculated for the kNN model with 16%. Similar low MREs were found for polynomial regression as well as gradient boosting-based prediction. Other models led to higher MREs and thereby worse predictive performance. Beyond the sole MRE, distinct differences in prediction performance, dependent on the initial dataset (expiration, inspiration, delta), were found. Therapeutic decisions in patients with COPD have largely relied on spirometry. Quantified computed tomography (qCT) is an emerging technique in the complex field of COPD diagnostics. With advances in scanner technologies and evaluation algorithms, increasing amounts of information can be gathered from non-contrast-enhanced chest
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