Computer-Aided Classification of Visual Ventilation Patterns in Patients with Chronic Obstructive Pulmonary Disease at Two-Phase Xenon-Enhanced CT

Objective To evaluate the technical feasibility, performance, and interobserver agreement of a computer-aided classification (CAC) system for regional ventilation at two-phase xenon-enhanced CT in patients with chronic obstructive pulmonary disease (COPD). Materials and Methods Thirty-eight patients with COPD underwent two-phase xenon ventilation CT with resulting wash-in (WI) and wash-out (WO) xenon images. The regional ventilation in structural abnormalities was visually categorized into four patterns by consensus of two experienced radiologists who compared the xenon attenuation of structural abnormalities with that of adjacent normal parenchyma in the WI and WO images, and it served as the reference. Two series of image datasets of structural abnormalities were randomly extracted for optimization and validation. The proportion of agreement on a per-lesion basis and receiver operating characteristics on a per-pixel basis between CAC and reference were analyzed for optimization. Thereafter, six readers independently categorized the regional ventilation in structural abnormalities in the validation set without and with a CAC map. Interobserver agreement was also compared between assessments without and with CAC maps using multirater κ statistics. Results Computer-aided classification maps were successfully generated in 31 patients (81.5%). The proportion of agreement and the average area under the curve of optimized CAC maps were 94% (75/80) and 0.994, respectively. Multirater κ value was improved from moderate (κ = 0.59; 95% confidence interval [CI], 0.56-0.62) at the initial assessment to excellent (κ = 0.82; 95% CI, 0.79-0.85) with the CAC map. Conclusion Our proposed CAC system demonstrated the potential for regional ventilation pattern analysis and enhanced interobserver agreement on visual classification of regional ventilation.

[1]  N. Hopkinson,et al.  Bronchoscopic lung volume reduction for emphysema: where next? , 2012, European Respiratory Journal.

[2]  Raúl San José Estépar,et al.  Interobserver variability in the determination of upper lobe-predominant emphysema. , 2007, Chest.

[3]  H. Gietema,et al.  Visual versus Automated Evaluation of Chest Computed Tomography for the Presence of Chronic Obstructive Pulmonary Disease , 2012, PloS one.

[4]  Helen Hong,et al.  Correction of segmented lung boundary for inclusion of pleural nodules and pulmonary vessels in chest CT images , 2008, Comput. Biol. Medicine.

[5]  Shin Matsuoka,et al.  Quantitative CT assessment of chronic obstructive pulmonary disease. , 2010, Radiographics : a review publication of the Radiological Society of North America, Inc.

[6]  E. Hoffman,et al.  Computer recognition of regional lung disease patterns. , 1999, American journal of respiratory and critical care medicine.

[7]  Joon Beom Seo,et al.  Xenon ventilation CT with a dual-energy technique of dual-source CT: initial experience. , 2008, Radiology.

[8]  F. Martinez,et al.  Global strategy for the diagnosis, management, and prevention of chronic obstructive pulmonary disease: GOLD executive summary. , 2007, American journal of respiratory and critical care medicine.

[9]  Edwin K Silverman,et al.  Chronic obstructive pulmonary disease phenotypes: the future of COPD. , 2010, American journal of respiratory and critical care medicine.

[10]  Joon Beom Seo,et al.  Feasibility of Automated Quantification of Regional Disease Patterns Depicted on High-Resolution Computed Tomography in Patients with Various Diffuse Lung Diseases , 2009, Korean journal of radiology.

[11]  J. Goo,et al.  Computer-Aided Nodule Detection and Volumetry to Reduce Variability Between Radiologists in the Interpretation of Lung Nodules at Low-Dose Screening Computed Tomography , 2012, Investigative radiology.

[12]  Namkug Kim,et al.  Collateral Ventilation to Congenital Hyperlucent Lung Lesions Assessed on Xenon-Enhanced Dynamic Dual-Energy CT: an Initial Experience , 2011, Korean journal of radiology.

[13]  Helen Hong,et al.  Deformable lung registration between exhale and inhale CT scans using active cells in a combined gradient force approach. , 2010, Medical physics.

[14]  Collateral ventilation and selection of techniques for bronchoscopic lung volume reduction , 2012, Thorax.

[15]  Sang Joon Park,et al.  Chronic obstructive pulmonary disease: quantitative and visual ventilation pattern analysis at xenon ventilation CT performed by using a dual-energy technique. , 2010, Radiology.

[16]  Alan D. Lopez,et al.  Alternative projections of mortality and disability by cause 1990–2020: Global Burden of Disease Study , 1997, The Lancet.

[17]  D. Lynch,et al.  Interobserver variability in the CT assessment of honeycombing in the lungs. , 2013, Radiology.

[18]  J. Seo,et al.  Collateral ventilation in a canine model with bronchial obstruction: assessment with xenon-enhanced dual-energy CT. , 2010, Radiology.

[19]  J. Goo,et al.  Quantitative thoracic CT techniques in adults: can they be applied in the pediatric population? , 2013, Pediatric Radiology.

[20]  Miranda Kirby,et al.  Chronic obstructive pulmonary disease: quantification of bronchodilator effects by using hyperpolarized ³He MR imaging. , 2011, Radiology.

[21]  Sang Joon Park,et al.  Xenon-enhanced dual-energy CT of patients with asthma: dynamic ventilation changes after methacholine and salbutamol inhalation. , 2012, AJR. American journal of roentgenology.

[22]  B. van Ginneken,et al.  Computer-aided diagnosis in high resolution CT of the lungs. , 2003, Medical physics.

[23]  Jan Wolber,et al.  Chronic obstructive pulmonary disease: safety and tolerability of hyperpolarized 129Xe MR imaging in healthy volunteers and patients. , 2012, Radiology.

[24]  Kavita Garg,et al.  Lung cancer: interobserver agreement on interpretation of pulmonary findings at low-dose CT screening. , 2008, Radiology.

[25]  P. E. Crewson,et al.  Reader agreement studies. , 2005, AJR. American journal of roentgenology.