SU‐GG‐J‐193: Using Small‐Deformation Linear‐Elastic Registration to Quantifying Ventilation‐Competent Lung Imaging From Clinical 4DCT Datasets: Toward Selective Avoidance IMRT for Locally Advanced Non‐Small‐Cell Lung Cancer

W Monroe; Y Kim; G Christensen; X Wu; J Bayouth; S Bhatia; S McGuire; R Siochi; T Waldron

doi:10.1118/1.2961742

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SU‐GG‐J‐193: Using Small‐Deformation Linear‐Elastic Registration to Quantifying Ventilation‐Competent Lung Imaging From Clinical 4DCT Datasets: Toward Selective Avoidance IMRT for Locally Advanced Non‐Small‐Cell Lung Cancer

Abstract

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SU‐GG‐J‐193: Using Small‐Deformation Linear‐Elastic Registration to Quantifying Ventilation‐Competent Lung Imaging From Clinical 4DCT Datasets: Toward Selective Avoidance IMRT for Locally Advanced Non‐Small‐Cell Lung Cancer

W Monroe, Y Kim, G Christensen, X Wu, J Bayouth, S Bhatia, S McGuire, R Siochi and T Waldron

Medical Physics, Vol.35(6), pp.2724-2724

06/2008

DOI: 10.1118/1.2961742

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Abstract

Purpose: To verify the feasibility of a small‐deformation inverse‐consistent linear‐elastic (SICLE) registration algorithm in quantifying ventilation‐competent sublung images from 4D CT datasets. Materials/Method: SICLE, a deformable image registration algorithm developed at the University of Iowa, was utilized to register the 100% inhalation and 100% exhalation phases of the lung which were extracted from clinical 4D CT datasets. The SICLE method performs inverse consistent image registration in which the forward and reverse transformations are estimated jointly while minimizing the inverse consistency error. After deformable registration, ventilation was calculated using the equation Δ V/Vex = 1000 ( HUin − HUex )/( HUex (1000 + HUin )) on voxels of the inhalation and exhalation images, where HU is in Hounsfield Units and ΔV/Vex is the change in regional volume divided by the local volume. Results: SICLE was found to be efficient and consistent in deformable image registering lung CT image datasets with different phases. 3D ventilation images were quantified and given in coronal, transverse, and sagittal view. Quantitative ventilation in a given region of interest was also determined. Ventilation‐competent sublung regions were constructed with different functionality levels of 90, 70, 50, and 30%. Conclusion: Utilizing a small‐deformation inverse‐consistent linear‐elastic registration algorithm, it was feasible to quantify ventilation competent subregions from clinical 4D CT datasets. Given the availability of 4D CT technology, this study opens a pathway to integrate functional lung information into radiotherapy for locally advanced non‐small‐cell lung cancer.

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Title: Subtitle: SU‐GG‐J‐193: Using Small‐Deformation Linear‐Elastic Registration to Quantifying Ventilation‐Competent Lung Imaging From Clinical 4DCT Datasets: Toward Selective Avoidance IMRT for Locally Advanced Non‐Small‐Cell Lung Cancer
Creators: W Monroe - University of Iowa
Y Kim - University of Iowa
G Christensen - University of Iowa
X Wu - University of Iowa
J Bayouth - University of Iowa
S Bhatia - University of Iowa
S McGuire - University of Iowa
R Siochi - 2University of Iowa, Department of Radiation Oncology
T Waldron - University of Iowa
Resource Type: Abstract
Publication Details: Medical Physics, Vol.35(6), pp.2724-2724
DOI: 10.1118/1.2961742
ISSN: 0094-2405
eISSN: 2473-4209
Number of pages: 1
Language: English
Date published: 06/2008
Academic Unit: Iowa Technology Institute; Radiation Oncology; Holden Comprehensive Cancer Center; Radiation Research Laboratory; The Iowa Institute for Biomedical Imaging; Electrical and Computer Engineering; Advanced Pulmonary Physiomic Imaging Laboratory
Record Identifier: 9984197439002771

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