Geodesic Atlas-Based Labeling of Anatomical Trees: Application and Evaluation on Airways Extracted From CT

We present a fast and robust atlas-based algorithm for labeling airway trees, using geodesic distances in a geometric tree-space. Possible branch label configurations for an unlabeled airway tree are evaluated using distances to a training set of labeled airway trees. In tree-space, airway tree topology and geometry change continuously, giving a natural automatic handling of anatomical differences and noise. A hierarchical approach makes the algorithm efficient, assigning labels from the trachea and downwards. Only the airway centerline tree is used, which is relatively unaffected by pathology. The algorithm is evaluated on 80 segmented airway trees from 40 subjects at two time points, labeled by three medical experts each, testing accuracy, reproducibility and robustness in patients with chronic obstructive pulmonary disease (COPD). The accuracy of the algorithm is statistically similar to that of the experts and not significantly correlated with COPD severity. The reproducibility of the algorithm is significantly better than that of the experts, and negatively correlated with COPD severity. Evaluation of the algorithm on a longitudinal set of 8724 trees from a lung cancer screening trial shows that the algorithm can be used in large scale studies with high reproducibility, and that the negative correlation of reproducibility with COPD severity can be explained by missing branches, for instance due to segmentation problems in COPD patients. We conclude that the algorithm is robust to COPD severity given equally complete airway trees, and comparable in performance to that of experts in pulmonary medicine, emphasizing the suitability of the labeling algorithm for clinical use.

[1]  Marleen de Bruijne,et al.  An Airway Tree-shape Model for Geodesic Airway Branch Labeling , 2011 .

[2]  D. Robinson,et al.  Comparison of weighted labelled trees , 1979 .

[3]  M. Hasegawa,et al.  Airflow limitation and airway dimensions in chronic obstructive pulmonary disease. , 2006, American journal of respiratory and critical care medicine.

[4]  Louis J. Billera,et al.  Geometry of the Space of Phylogenetic Trees , 2001, Adv. Appl. Math..

[5]  Mads Nielsen,et al.  Effect of inspiration on airway dimensions measured in maximal inspiration CT images of subjects without airflow limitation , 2014, European Radiology.

[6]  Paul Suetens,et al.  Robust matching of 3D lung vessel trees , 2010 .

[7]  Bram van Ginneken,et al.  Robust Segmentation and Anatomical Labeling of the Airway Tree from Thoracic CT Scans , 2008, MICCAI.

[8]  Marleen de Bruijne,et al.  A Hierarchical Scheme for Geodesic Anatomical Labeling of Airway Trees , 2012, MICCAI.

[9]  J. Im,et al.  Tuberculosis of the central airways: CT findings of active and fibrotic disease. , 1997, AJR. American journal of roentgenology.

[10]  Mads Nielsen,et al.  Longitudinal Analysis of Airways using Registration , 2011 .

[11]  J. Scott Provan,et al.  A Fast Algorithm for Computing Geodesic Distances in Tree Space , 2009, IEEE/ACM Transactions on Computational Biology and Bioinformatics.

[12]  William E. Higgins,et al.  Optimal graph-theoretic approach to 3D anatomical tree matching , 2006, 3rd IEEE International Symposium on Biomedical Imaging: Nano to Macro, 2006..

[13]  Marleen de Bruijne,et al.  Tree-Space Statistics and Approximations for Large-Scale Analysis of Anatomical Trees , 2013, IPMI.

[14]  Lawrence B. Wolff,et al.  Tracking 3-D pulmonary tree structures , 1996, Proceedings of the Workshop on Mathematical Methods in Biomedical Image Analysis.

[15]  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.

[16]  Kensaku Mori,et al.  Automated Labeling of Bronchial Branches in Virtual Bronchoscopy System , 1998, MICCAI.

[17]  Cristian Lorenz,et al.  Point based methods for automatic bronchial tree matching and labeling , 2006, SPIE Medical Imaging.

[18]  Fereidoun Abtin,et al.  A Bottom-up approach for labeling of human airway trees , 2011 .

[19]  Hans-Ulrich Kauczor,et al.  Automatic Airway Analysis on Multidetector Computed Tomography in Cystic Fibrosis: Correlation With Pulmonary Function Testing , 2013, Journal of thoracic imaging.

[20]  Marleen de Bruijne,et al.  Short-term effect of changes in smoking behaviour on emphysema quantification by CT , 2010, Thorax.

[21]  Marleen de Bruijne,et al.  Mass preserving image registration for lung CT , 2012, Medical Image Anal..

[22]  Raúl San José Estépar,et al.  Airway count and emphysema assessed by chest CT imaging predicts clinical outcome in smokers. , 2010, Chest.

[23]  Heinz-Otto Peitgen,et al.  Matching of anatomical tree structures for registration of medical images , 2009, Image Vis. Comput..

[24]  Milan Sonka,et al.  Matching and anatomical labeling of human airway tree , 2005, IEEE Transactions on Medical Imaging.

[25]  Hubert Cochet,et al.  CT attenuation of the bronchial wall in patients with asthma: comparison with geometric parameters and correlation with function and histologic characteristics. , 2012, AJR. American journal of roentgenology.

[26]  J. Hankinson,et al.  General considerations for lung function testing , 2005, European Respiratory Journal.

[27]  Daisuke Deguchi,et al.  Automated Anatomical Labeling of Bronchial Branches Extracted from CT Datasets Based on Machine Learning and Combination Optimization and Its Application to Bronchoscope Guidance , 2009, MICCAI.

[28]  Eric A. Hoffman,et al.  Extraction of Airways From CT (EXACT'09) , 2012, IEEE Transactions on Medical Imaging.

[29]  A. Dirksen,et al.  The Danish Randomized Lung Cancer CT Screening Trial—Overall Design and Results of the Prevalence Round , 2009, Journal of thoracic oncology : official publication of the International Association for the Study of Lung Cancer.

[30]  Marleen de Bruijne,et al.  Vessel-guided airway tree segmentation: A voxel classification approach , 2010, Medical Image Anal..

[31]  Hiroshi Murase,et al.  Automated Nomenclature of Bronchial Branches Extracted from CT Images and Its Application to Biopsy Path Planning in Virtual Bronchoscopy , 2005, MICCAI.

[32]  David Gur,et al.  Three-dimensional airway tree architecture and pulmonary function. , 2012, Academic radiology.

[33]  Atilla Peter Kiraly,et al.  A novel multipurpose tree and path matching algorithm with application to airway trees , 2006, SPIE Medical Imaging.

[34]  Jennifer G. Dy,et al.  Airway labeling using a Hidden Markov Tree Model , 2014, 2014 IEEE 11th International Symposium on Biomedical Imaging (ISBI).

[35]  F. Netter Atlas of Human Anatomy , 1967 .

[36]  Alejandro F. Frangi,et al.  Anatomical Labeling of the Circle of Willis Using Maximum A Posteriori Probability Estimation , 2013, IEEE Transactions on Medical Imaging.

[37]  Zhimin Wang,et al.  Automated Lobe-Based Airway Labeling , 2012, Int. J. Biomed. Imaging.

[38]  Milan Sonka,et al.  Automated Nomenclature Labeling of the Bronchial Tree in 3D-CT Lung Images , 2002, MICCAI.

[39]  Marleen de Bruijne,et al.  Optimal surface segmentation using flow lines to quantify airway abnormalities in chronic obstructive pulmonary disease , 2014, Medical Image Anal..

[40]  Kensaku Mori,et al.  Automated anatomical labeling of the bronchial branch and its application to the virtual bronchoscopy system , 2000, IEEE Transactions on Medical Imaging.

[41]  Marleen de Bruijne,et al.  Airway Tree Extraction with Locally Optimal Paths , 2009, MICCAI.