Evaluation of automated airway morphological quantification for assessing fibrosing lung disease

A. Pakzad; W. K. Cheung; C. H.M. Van Moorsel; K. Quan; N. Mogulkoc; Brian Jack Bartholmai; H. W. Van Es; A. Ezircan; F. Van Beek; M. Veltkamp; R. Karwoski; T. Peikert; R. D. Clay; F. Foley; C. Braun; R. Savas; C. Sudre; T. Doel; D. C. Alexander; P. Wijeratne; D. Hawkes; Y. Hu; J. R. Hurst; J. Jacob

doi:10.1080/21681163.2024.2325361

Evaluation of automated airway morphological quantification for assessing fibrosing lung disease

A. Pakzad, W. K. Cheung, C. H.M. Van Moorsel, K. Quan, N. Mogulkoc, Brian Jack Bartholmai, H. W. Van Es, A. Ezircan, F. Van Beek, M. Veltkamp, R. Karwoski, T. Peikert, R. D. Clay, F. Foley, C. Braun, R. Savas, C. Sudre, T. Doel, D. C. Alexander, P. WijeratneD. Hawkes, Y. Hu, J. R. Hurst, J. Jacob

Research output: Contribution to journal › Article › peer-review

Abstract

Abnormal airway dilatation, termed traction bronchiectasis, is a typical feature of idiopathic pulmonary fibrosis (IPF). Volumetric computed tomography (CT) imaging captures the loss of normal airway tapering in IPF. We postulated that automated quantification of airway abnormalities could provide estimates of IPF disease extent and severity. We propose AirQuant, an automated computational pipeline that takes an airway segmentation and CT image as input and systematically parcellates the airway tree into its lobes and generational branches, deriving airway structural measures from chest CT. Importantly, AirQuant prevents the occurrence of spurious airway branches by thick wave propagation and removes loops in the airway-tree by graph search, overcoming limitations of existing airway skeletonisation algorithms. Tapering between airway segments (intertapering) and airway tortuosity computed by AirQuant were compared between 14 healthy participants and 14 IPF patients. Airway intertapering was significantly reduced in IPF patients, and airway tortuosity was significantly increased when compared to healthy controls. Differences were most marked in the lower lobes, conforming to the typical distribution of IPF-related damage. AirQuant is an open-source pipeline that avoids limitations of existing airway quantification algorithms and has clinical interpretability. Automated airway measurements may have potential as novel imaging biomarkers of IPF severity and disease extent.

Original language	English (US)
Article number	2325361
Journal	Computer Methods in Biomechanics and Biomedical Engineering: Imaging and Visualization
Volume	12
Issue number	1
DOIs	https://doi.org/10.1080/21681163.2024.2325361
State	Published - 2024

Keywords

Airway morphology
Bronchiectasis
Computed tomography

ASJC Scopus subject areas

Computational Mechanics
Biomedical Engineering
Radiology Nuclear Medicine and imaging
Computer Science Applications

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10.1080/21681163.2024.2325361

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Pakzad, A., Cheung, W. K., Van Moorsel, C. H. M., Quan, K., Mogulkoc, N., Bartholmai, B. J., Van Es, H. W., Ezircan, A., Van Beek, F., Veltkamp, M., Karwoski, R., Peikert, T., Clay, R. D., Foley, F., Braun, C., Savas, R., Sudre, C., Doel, T., Alexander, D. C., ... Jacob, J. (2024). Evaluation of automated airway morphological quantification for assessing fibrosing lung disease. Computer Methods in Biomechanics and Biomedical Engineering: Imaging and Visualization, 12(1), Article 2325361. https://doi.org/10.1080/21681163.2024.2325361

Pakzad, A, Cheung, WK, Van Moorsel, CHM, Quan, K, Mogulkoc, N, Bartholmai, BJ, Van Es, HW, Ezircan, A, Van Beek, F, Veltkamp, M, Karwoski, R, Peikert, T, Clay, RD, Foley, F, Braun, C, Savas, R, Sudre, C, Doel, T, Alexander, DC, Wijeratne, P, Hawkes, D, Hu, Y, Hurst, JR & Jacob, J 2024, 'Evaluation of automated airway morphological quantification for assessing fibrosing lung disease', Computer Methods in Biomechanics and Biomedical Engineering: Imaging and Visualization, vol. 12, no. 1, 2325361. https://doi.org/10.1080/21681163.2024.2325361

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title = "Evaluation of automated airway morphological quantification for assessing fibrosing lung disease",

abstract = "Abnormal airway dilatation, termed traction bronchiectasis, is a typical feature of idiopathic pulmonary fibrosis (IPF). Volumetric computed tomography (CT) imaging captures the loss of normal airway tapering in IPF. We postulated that automated quantification of airway abnormalities could provide estimates of IPF disease extent and severity. We propose AirQuant, an automated computational pipeline that takes an airway segmentation and CT image as input and systematically parcellates the airway tree into its lobes and generational branches, deriving airway structural measures from chest CT. Importantly, AirQuant prevents the occurrence of spurious airway branches by thick wave propagation and removes loops in the airway-tree by graph search, overcoming limitations of existing airway skeletonisation algorithms. Tapering between airway segments (intertapering) and airway tortuosity computed by AirQuant were compared between 14 healthy participants and 14 IPF patients. Airway intertapering was significantly reduced in IPF patients, and airway tortuosity was significantly increased when compared to healthy controls. Differences were most marked in the lower lobes, conforming to the typical distribution of IPF-related damage. AirQuant is an open-source pipeline that avoids limitations of existing airway quantification algorithms and has clinical interpretability. Automated airway measurements may have potential as novel imaging biomarkers of IPF severity and disease extent.",

keywords = "Airway morphology, Bronchiectasis, Computed tomography",

author = "A. Pakzad and Cheung, {W. K.} and {Van Moorsel}, {C. H.M.} and K. Quan and N. Mogulkoc and Bartholmai, {Brian Jack} and {Van Es}, {H. W.} and A. Ezircan and {Van Beek}, F. and M. Veltkamp and R. Karwoski and T. Peikert and Clay, {R. D.} and F. Foley and C. Braun and R. Savas and C. Sudre and T. Doel and Alexander, {D. C.} and P. Wijeratne and D. Hawkes and Y. Hu and Hurst, {J. R.} and J. Jacob",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.",

year = "2024",

doi = "10.1080/21681163.2024.2325361",

language = "English (US)",

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T1 - Evaluation of automated airway morphological quantification for assessing fibrosing lung disease

AU - Pakzad, A.

AU - Cheung, W. K.

AU - Van Moorsel, C. H.M.

AU - Quan, K.

AU - Mogulkoc, N.

AU - Bartholmai, Brian Jack

AU - Van Es, H. W.

AU - Ezircan, A.

AU - Van Beek, F.

AU - Veltkamp, M.

AU - Karwoski, R.

AU - Peikert, T.

AU - Clay, R. D.

AU - Foley, F.

AU - Braun, C.

AU - Savas, R.

AU - Sudre, C.

AU - Doel, T.

AU - Alexander, D. C.

AU - Wijeratne, P.

AU - Hawkes, D.

AU - Hu, Y.

AU - Hurst, J. R.

AU - Jacob, J.

PY - 2024

Y1 - 2024

N2 - Abnormal airway dilatation, termed traction bronchiectasis, is a typical feature of idiopathic pulmonary fibrosis (IPF). Volumetric computed tomography (CT) imaging captures the loss of normal airway tapering in IPF. We postulated that automated quantification of airway abnormalities could provide estimates of IPF disease extent and severity. We propose AirQuant, an automated computational pipeline that takes an airway segmentation and CT image as input and systematically parcellates the airway tree into its lobes and generational branches, deriving airway structural measures from chest CT. Importantly, AirQuant prevents the occurrence of spurious airway branches by thick wave propagation and removes loops in the airway-tree by graph search, overcoming limitations of existing airway skeletonisation algorithms. Tapering between airway segments (intertapering) and airway tortuosity computed by AirQuant were compared between 14 healthy participants and 14 IPF patients. Airway intertapering was significantly reduced in IPF patients, and airway tortuosity was significantly increased when compared to healthy controls. Differences were most marked in the lower lobes, conforming to the typical distribution of IPF-related damage. AirQuant is an open-source pipeline that avoids limitations of existing airway quantification algorithms and has clinical interpretability. Automated airway measurements may have potential as novel imaging biomarkers of IPF severity and disease extent.

AB - Abnormal airway dilatation, termed traction bronchiectasis, is a typical feature of idiopathic pulmonary fibrosis (IPF). Volumetric computed tomography (CT) imaging captures the loss of normal airway tapering in IPF. We postulated that automated quantification of airway abnormalities could provide estimates of IPF disease extent and severity. We propose AirQuant, an automated computational pipeline that takes an airway segmentation and CT image as input and systematically parcellates the airway tree into its lobes and generational branches, deriving airway structural measures from chest CT. Importantly, AirQuant prevents the occurrence of spurious airway branches by thick wave propagation and removes loops in the airway-tree by graph search, overcoming limitations of existing airway skeletonisation algorithms. Tapering between airway segments (intertapering) and airway tortuosity computed by AirQuant were compared between 14 healthy participants and 14 IPF patients. Airway intertapering was significantly reduced in IPF patients, and airway tortuosity was significantly increased when compared to healthy controls. Differences were most marked in the lower lobes, conforming to the typical distribution of IPF-related damage. AirQuant is an open-source pipeline that avoids limitations of existing airway quantification algorithms and has clinical interpretability. Automated airway measurements may have potential as novel imaging biomarkers of IPF severity and disease extent.

KW - Airway morphology

KW - Bronchiectasis

KW - Computed tomography

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Evaluation of automated airway morphological quantification for assessing fibrosing lung disease

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