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Modelling airway geometry as stock market data using Bayesian changepoint detection

Modelling airway geometry as stock market data using Bayesian changepoint detection
Modelling airway geometry as stock market data using Bayesian changepoint detection
Numerous lung diseases, such as idiopathic pulmonary fibrosis (IPF), exhibit dilation of the airways. Accurate measurement of dilatation enables assessment of the progression of disease. Unfortunately the combination of image noise and airway bifurcations causes high variability in the profiles of cross-sectional areas, rendering the identification of affected regions very difficult. Here we introduce a noise-robust method for automatically detecting the location of progressive airway dilatation given two profiles of the same airway acquired at different time points. We propose a probabilistic model of abrupt relative variations between profiles and perform inference via Reversible Jump Markov Chain Monte Carlo sampling. We demonstrate the efficacy of the proposed method on two datasets; (i) images of healthy airways with simulated dilatation; (ii) pairs of real images of IPF-affected airways acquired at 1 year intervals. Our model is able to detect the starting location of airway dilatation with an accuracy of 2.5 mm on simulated data. The experiments on the IPF dataset display reasonable agreement with radiologists. We can compute a relative change in airway volume that may be useful for quantifying IPF disease progression.
345-354
Springer
Quan, Kin
647678a1-1a56-4b7e-8746-ba42aa66eeae
Tanno, Ryutaro
07f33e5a-3a4e-4a9e-8779-0524e51fce65
Duong, Michael
60e48c80-f1b6-447b-8dc2-5d0f158baee9
Nair, Arjun
a9b6cef1-ccdb-48b2-8c93-659854d90bd5
Jones, Mark
a6fd492e-058e-4e84-a486-34c6035429c1
Brereton, Christopher
91519ec5-7d78-47f3-8f96-e223b34c2dd2
Hurst, John
6798076d-b1c5-4a42-95fb-8c48742abf38
Hawkes, David
4ffccac5-33fa-4e33-839b-39fc17b20f6a
Jacob, Joseph
b93a90c4-de81-4001-8f6f-bfd9f54a3d29
Suk, H.I.
Yan, P.
Lian, C.
Quan, Kin
647678a1-1a56-4b7e-8746-ba42aa66eeae
Tanno, Ryutaro
07f33e5a-3a4e-4a9e-8779-0524e51fce65
Duong, Michael
60e48c80-f1b6-447b-8dc2-5d0f158baee9
Nair, Arjun
a9b6cef1-ccdb-48b2-8c93-659854d90bd5
Jones, Mark
a6fd492e-058e-4e84-a486-34c6035429c1
Brereton, Christopher
91519ec5-7d78-47f3-8f96-e223b34c2dd2
Hurst, John
6798076d-b1c5-4a42-95fb-8c48742abf38
Hawkes, David
4ffccac5-33fa-4e33-839b-39fc17b20f6a
Jacob, Joseph
b93a90c4-de81-4001-8f6f-bfd9f54a3d29
Suk, H.I.
Yan, P.
Lian, C.

Quan, Kin, Tanno, Ryutaro, Duong, Michael, Nair, Arjun, Jones, Mark, Brereton, Christopher, Hurst, John, Hawkes, David and Jacob, Joseph (2019) Modelling airway geometry as stock market data using Bayesian changepoint detection. Suk, H.I., Yan, P. and Lian, C. (eds.) In Machine Learning in Medical Imaging: MLMI 2019. vol. 11861, Springer. pp. 345-354 . (doi:10.1007/978-3-030-32692-0_40).

Record type: Conference or Workshop Item (Paper)

Abstract

Numerous lung diseases, such as idiopathic pulmonary fibrosis (IPF), exhibit dilation of the airways. Accurate measurement of dilatation enables assessment of the progression of disease. Unfortunately the combination of image noise and airway bifurcations causes high variability in the profiles of cross-sectional areas, rendering the identification of affected regions very difficult. Here we introduce a noise-robust method for automatically detecting the location of progressive airway dilatation given two profiles of the same airway acquired at different time points. We propose a probabilistic model of abrupt relative variations between profiles and perform inference via Reversible Jump Markov Chain Monte Carlo sampling. We demonstrate the efficacy of the proposed method on two datasets; (i) images of healthy airways with simulated dilatation; (ii) pairs of real images of IPF-affected airways acquired at 1 year intervals. Our model is able to detect the starting location of airway dilatation with an accuracy of 2.5 mm on simulated data. The experiments on the IPF dataset display reasonable agreement with radiologists. We can compute a relative change in airway volume that may be useful for quantifying IPF disease progression.

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Modelling Airway Geometry - Accepted Manuscript
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Accepted/In Press date: 1 October 2019
e-pub ahead of print date: 10 October 2019
Published date: 2019

Identifiers

Local EPrints ID: 436415
URI: http://eprints.soton.ac.uk/id/eprint/436415
PURE UUID: 18177fea-8f22-45b5-ba8e-cd94fbb61dc5
ORCID for Mark Jones: ORCID iD orcid.org/0000-0001-6308-6014

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Date deposited: 10 Dec 2019 17:30
Last modified: 17 Mar 2024 05:07

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Contributors

Author: Kin Quan
Author: Ryutaro Tanno
Author: Michael Duong
Author: Arjun Nair
Author: Mark Jones ORCID iD
Author: Christopher Brereton
Author: John Hurst
Author: David Hawkes
Author: Joseph Jacob
Editor: H.I. Suk
Editor: P. Yan
Editor: C. Lian

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