Geometric tree kernels: classification of COPD from airway tree geometry

Aasa Feragen; Jens Petersen; Dominik Grimm; Asger Dirksen; Jesper Johannes Holst Pedersen; Karsten Borgwardt; Marleen de Bruijne

doi:10.1007/978-3-642-38868-2_15

Geometric tree kernels: classification of COPD from airway tree geometry

Aasa Feragen, Jens Petersen, Dominik Grimm, Asger Dirksen, Jesper Johannes Holst Pedersen, Karsten Borgwardt, Marleen de Bruijne

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Abstract

Methodological contributions: This paper introduces a family of kernels for analyzing (anatomical) trees endowed with vector valued measurements made along the tree. While state-of-the-art graph and tree kernels use combinatorial tree/graph structure with discrete node and edge labels, the kernels presented in this paper can include geometric information such as branch shape, branch radius or other vector valued properties. In addition to being flexible in their ability to model different types of attributes, the presented kernels are computationally efficient and some of them can easily be computed for large datasets (N ~10.000) of trees with 30 - 600 branches. Combining the kernels with standard machine learning tools enables us to analyze the relation between disease and anatomical tree structure and geometry. Experimental results: The kernels are used to compare airway trees segmented from low-dose CT, endowed with branch shape descriptors and airway wall area percentage measurements made along the tree. Using kernelized hypothesis testing we show that the geometric airway trees are significantly differently distributed in patients with Chronic Obstructive Pulmonary Disease (COPD) than in healthy individuals. The geometric tree kernels also give a significant increase in the classification accuracy of COPD from geometric tree structure endowed with airway wall thickness measurements in comparison with state-of-the-art methods, giving further insight into the relationship between airway wall thickness and COPD. Software: Software for computing kernels and statistical tests is available at http://image.diku.dk/aasa/software.php.

Original language	English
Title of host publication	Information Processing in Medical Imaging : 23rd International Conference, IPMI 2013, Asilomar, CA, USA, June 28–July 3, 2013. Proceedings
Editors	James C. Gee, Sarang Joshi, Kilian M. Pohl, William M. Wells, Lilla Zöllei
Number of pages	13
Publisher	Springer
Publication date	2013
Pages	171-183
ISBN (Print)	978-3-642-38867-5
ISBN (Electronic)	978-3-642-38868-2
DOIs	https://doi.org/10.1007/978-3-642-38868-2_15
Publication status	Published - 2013
Event	23rd International Conference on Information Processing in Medical Imaging - Asilomar, United States Duration: 28 Jun 2013 → 3 Jul 2013 Conference number: 23

Conference

Conference	23rd International Conference on Information Processing in Medical Imaging
Number	23
Country/Territory	United States
City	Asilomar
Period	28/06/2013 → 03/07/2013

Series	Lecture notes in computer science
Volume	7917
ISSN	0302-9743

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Feragen, A., Petersen, J., Grimm, D., Dirksen, A., Pedersen, J. J. H., Borgwardt, K., & de Bruijne, M. (2013). Geometric tree kernels: classification of COPD from airway tree geometry. In J. C. Gee, S. Joshi, K. M. Pohl, W. M. Wells, & L. Zöllei (Eds.), Information Processing in Medical Imaging: 23rd International Conference, IPMI 2013, Asilomar, CA, USA, June 28–July 3, 2013. Proceedings (pp. 171-183). Springer. Lecture notes in computer science Vol. 7917 https://doi.org/10.1007/978-3-642-38868-2_15

Geometric tree kernels : classification of COPD from airway tree geometry. / Feragen, Aasa; Petersen, Jens; Grimm, Dominik et al.

Information Processing in Medical Imaging: 23rd International Conference, IPMI 2013, Asilomar, CA, USA, June 28–July 3, 2013. Proceedings. ed. / James C. Gee; Sarang Joshi; Kilian M. Pohl; William M. Wells; Lilla Zöllei. Springer, 2013. p. 171-183 (Lecture notes in computer science, Vol. 7917).

Research output: Chapter in Book/Report/Conference proceeding › Article in proceedings › Research › peer-review

Feragen, A, Petersen, J, Grimm, D, Dirksen, A, Pedersen, JJH, Borgwardt, K & de Bruijne, M 2013, Geometric tree kernels: classification of COPD from airway tree geometry. in JC Gee, S Joshi, KM Pohl, WM Wells & L Zöllei (eds), Information Processing in Medical Imaging: 23rd International Conference, IPMI 2013, Asilomar, CA, USA, June 28–July 3, 2013. Proceedings. Springer, Lecture notes in computer science, vol. 7917, pp. 171-183, 23rd International Conference on Information Processing in Medical Imaging, Asilomar, United States, 28/06/2013. https://doi.org/10.1007/978-3-642-38868-2_15

Feragen A, Petersen J, Grimm D, Dirksen A, Pedersen JJH, Borgwardt K et al. Geometric tree kernels: classification of COPD from airway tree geometry. In Gee JC, Joshi S, Pohl KM, Wells WM, Zöllei L, editors, Information Processing in Medical Imaging: 23rd International Conference, IPMI 2013, Asilomar, CA, USA, June 28–July 3, 2013. Proceedings. Springer. 2013. p. 171-183. (Lecture notes in computer science, Vol. 7917). doi: 10.1007/978-3-642-38868-2_15

Feragen, Aasa ; Petersen, Jens ; Grimm, Dominik et al. / Geometric tree kernels : classification of COPD from airway tree geometry. Information Processing in Medical Imaging: 23rd International Conference, IPMI 2013, Asilomar, CA, USA, June 28–July 3, 2013. Proceedings. editor / James C. Gee ; Sarang Joshi ; Kilian M. Pohl ; William M. Wells ; Lilla Zöllei. Springer, 2013. pp. 171-183 (Lecture notes in computer science, Vol. 7917).

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AB - Methodological contributions: This paper introduces a family of kernels for analyzing (anatomical) trees endowed with vector valued measurements made along the tree. While state-of-the-art graph and tree kernels use combinatorial tree/graph structure with discrete node and edge labels, the kernels presented in this paper can include geometric information such as branch shape, branch radius or other vector valued properties. In addition to being flexible in their ability to model different types of attributes, the presented kernels are computationally efficient and some of them can easily be computed for large datasets (N ~10.000) of trees with 30 - 600 branches. Combining the kernels with standard machine learning tools enables us to analyze the relation between disease and anatomical tree structure and geometry. Experimental results: The kernels are used to compare airway trees segmented from low-dose CT, endowed with branch shape descriptors and airway wall area percentage measurements made along the tree. Using kernelized hypothesis testing we show that the geometric airway trees are significantly differently distributed in patients with Chronic Obstructive Pulmonary Disease (COPD) than in healthy individuals. The geometric tree kernels also give a significant increase in the classification accuracy of COPD from geometric tree structure endowed with airway wall thickness measurements in comparison with state-of-the-art methods, giving further insight into the relationship between airway wall thickness and COPD. Software: Software for computing kernels and statistical tests is available at http://image.diku.dk/aasa/software.php.

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Geometric tree kernels: classification of COPD from airway tree geometry

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