CT-derived vessel segmentation for analysis of post-radiation therapy changes in vasculature and perfusion

Antonia E. Wuschner; Mattison J. Flakus; Eric M. Wallat; Joseph M. Reinhardt; Dhanansayan Shanmuganayagam; Gary E. Christensen; Sarah E. Gerard; John E. Bayouth

doi:10.3389/fphys.2022.1008526

CT-derived vessel segmentation for analysis of post-radiation therapy changes in vasculature and perfusion

Antonia E. Wuschner, Mattison J. Flakus, Eric M. Wallat, Joseph M. Reinhardt, Dhanansayan Shanmuganayagam, Gary E. Christensen, Sarah E. Gerard, John E. Bayouth

Radiation Medicine

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

3 Scopus citations

Abstract

Vessel segmentation in the lung is an ongoing challenge. While many methods have been able to successfully identify vessels in normal, healthy, lungs, these methods struggle in the presence of abnormalities. Following radiotherapy, these methods tend to identify regions of radiographic change due to post-radiation therapytoxicities as vasculature falsely. By combining texture analysis and existing vasculature and masking techniques, we have developed a novel vasculature segmentation workflow that improves specificity in irradiated lung while preserving the sensitivity of detection in the rest of the lung. Furthermore, radiation dose has been shown to cause vascular injury as well as reduce pulmonary function post-RT. This work shows the improvements our novel vascular segmentation method provides relative to existing methods. Additionally, we use this workflow to show a dose dependent radiation-induced change in vasculature which is correlated with previously measured perfusion changes (R² = 0.72) in both directly irradiated and indirectly damaged regions of perfusion. These results present an opportunity to extend non-contrast CT-derived models of functional change following radiation therapy.

Original language	English (US)
Article number	1008526
Journal	Frontiers in Physiology
Volume	13
DOIs	https://doi.org/10.3389/fphys.2022.1008526
State	Published - Oct 17 2022

Keywords

ct-derived perfusion
lung perfusion
post-RT vascular change
pulmonary vasculature segmentation
radiation-induced damage

ASJC Scopus subject areas

Physiology
Physiology (medical)

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10.3389/fphys.2022.1008526

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@article{ac415f7d90614605bc4ebe6cb9239394,

title = "CT-derived vessel segmentation for analysis of post-radiation therapy changes in vasculature and perfusion",

abstract = "Vessel segmentation in the lung is an ongoing challenge. While many methods have been able to successfully identify vessels in normal, healthy, lungs, these methods struggle in the presence of abnormalities. Following radiotherapy, these methods tend to identify regions of radiographic change due to post-radiation therapytoxicities as vasculature falsely. By combining texture analysis and existing vasculature and masking techniques, we have developed a novel vasculature segmentation workflow that improves specificity in irradiated lung while preserving the sensitivity of detection in the rest of the lung. Furthermore, radiation dose has been shown to cause vascular injury as well as reduce pulmonary function post-RT. This work shows the improvements our novel vascular segmentation method provides relative to existing methods. Additionally, we use this workflow to show a dose dependent radiation-induced change in vasculature which is correlated with previously measured perfusion changes (R2 = 0.72) in both directly irradiated and indirectly damaged regions of perfusion. These results present an opportunity to extend non-contrast CT-derived models of functional change following radiation therapy.",

keywords = "ct-derived perfusion, lung perfusion, post-RT vascular change, pulmonary vasculature segmentation, radiation-induced damage",

author = "Wuschner, {Antonia E.} and Flakus, {Mattison J.} and Wallat, {Eric M.} and Reinhardt, {Joseph M.} and Dhanansayan Shanmuganayagam and Christensen, {Gary E.} and Gerard, {Sarah E.} and Bayouth, {John E.}",

note = "Publisher Copyright: Copyright {\textcopyright} 2022 Wuschner, Flakus, Wallat, Reinhardt, Shanmuganayagam, Christensen, Gerard and Bayouth.",

year = "2022",

month = oct,

day = "17",

doi = "10.3389/fphys.2022.1008526",

language = "English (US)",

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journal = "Frontiers in Physiology",

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T1 - CT-derived vessel segmentation for analysis of post-radiation therapy changes in vasculature and perfusion

AU - Wuschner, Antonia E.

AU - Flakus, Mattison J.

AU - Wallat, Eric M.

AU - Reinhardt, Joseph M.

AU - Shanmuganayagam, Dhanansayan

AU - Christensen, Gary E.

AU - Gerard, Sarah E.

AU - Bayouth, John E.

PY - 2022/10/17

Y1 - 2022/10/17

N2 - Vessel segmentation in the lung is an ongoing challenge. While many methods have been able to successfully identify vessels in normal, healthy, lungs, these methods struggle in the presence of abnormalities. Following radiotherapy, these methods tend to identify regions of radiographic change due to post-radiation therapytoxicities as vasculature falsely. By combining texture analysis and existing vasculature and masking techniques, we have developed a novel vasculature segmentation workflow that improves specificity in irradiated lung while preserving the sensitivity of detection in the rest of the lung. Furthermore, radiation dose has been shown to cause vascular injury as well as reduce pulmonary function post-RT. This work shows the improvements our novel vascular segmentation method provides relative to existing methods. Additionally, we use this workflow to show a dose dependent radiation-induced change in vasculature which is correlated with previously measured perfusion changes (R2 = 0.72) in both directly irradiated and indirectly damaged regions of perfusion. These results present an opportunity to extend non-contrast CT-derived models of functional change following radiation therapy.

AB - Vessel segmentation in the lung is an ongoing challenge. While many methods have been able to successfully identify vessels in normal, healthy, lungs, these methods struggle in the presence of abnormalities. Following radiotherapy, these methods tend to identify regions of radiographic change due to post-radiation therapytoxicities as vasculature falsely. By combining texture analysis and existing vasculature and masking techniques, we have developed a novel vasculature segmentation workflow that improves specificity in irradiated lung while preserving the sensitivity of detection in the rest of the lung. Furthermore, radiation dose has been shown to cause vascular injury as well as reduce pulmonary function post-RT. This work shows the improvements our novel vascular segmentation method provides relative to existing methods. Additionally, we use this workflow to show a dose dependent radiation-induced change in vasculature which is correlated with previously measured perfusion changes (R2 = 0.72) in both directly irradiated and indirectly damaged regions of perfusion. These results present an opportunity to extend non-contrast CT-derived models of functional change following radiation therapy.

KW - ct-derived perfusion

KW - lung perfusion

KW - post-RT vascular change

KW - pulmonary vasculature segmentation

KW - radiation-induced damage

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CT-derived vessel segmentation for analysis of post-radiation therapy changes in vasculature and perfusion

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Keywords

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