Development of a dynamic deformable thorax phantom for the quality management of deformable image registration

•We developed a dynamic deformable thorax phantom for DIR commissioning and QA.•Our phantom can create various deformation patterns with various marker patterns.•DIR results with different marker settings and DIR parameters were obtained using this phantom. The purpose of this study was to develop a...

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Veröffentlicht in:	Physica medica 2020-09, Vol.77, p.100-107
Hauptverfasser:	Sugawara, Yasuharu, Kadoya, Noriyuki, Kotabe, Kazuki, Nakajima, Yujiro, Ikeda, Ryutaro, Tanabe, Shunpei, Ohashi, Haruna, Jingu, Keiichi
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Sprache:	eng
Schlagworte:	Deformable image registration Physical phantom Quality assurance Radiotherapy Target registration error
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creator	Sugawara, Yasuharu Kadoya, Noriyuki Kotabe, Kazuki Nakajima, Yujiro Ikeda, Ryutaro Tanabe, Shunpei Ohashi, Haruna Jingu, Keiichi
description	•We developed a dynamic deformable thorax phantom for DIR commissioning and QA.•Our phantom can create various deformation patterns with various marker patterns.•DIR results with different marker settings and DIR parameters were obtained using this phantom. The purpose of this study was to develop a novel dynamic deformable thorax phantom for deformable image registration (DIR) quality assurance (QA) and to verify as a tool for commissioning and DIR QA. The phantom consists of a base phantom, an inner phantom, and a motor-derived piston. The base phantom is an acrylic cylinder phantom with a diameter of 180 mm. The inner phantom consists of deformable, 20 mm thick disk-shaped sponges. To evaluate the physical characteristics of the phantom, we evaluated its image quality and deformation. DIR accuracies were evaluated using the three types of commercially DIR software (MIM, RayStation, and Velocity AI) to test the feasibility of this phantom. We used different DIR parameters to test the impact of parameters on DIR accuracy in various phantom settings. To evaluate DIR accuracy, a target registration error (TRE) was calculated using the anatomical landmark points. The three locations (i.e., distal, middle, and proximal positions) had different displacement amounts. This result indicated that the inner phantom was not moved but deformed. In cases with different phantom settings and marker settings, the ranges of the average TRE were 0.63–15.60 mm (MIM). In cases with different DIR parameters settings, the ranges of the average TRE were as follows: 0.73–7.10 mm (MIM), 8.25–8.66 mm (RayStation), and 8.26–8.43 mm (Velocity). These results suggest that our phantom could evaluate the detailed DIR behaviors with TRE. Therefore, this is indicative of the potential usefulness of our phantom in DIR commissioning and QA.
doi_str_mv	10.1016/j.ejmp.2020.08.007
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The purpose of this study was to develop a novel dynamic deformable thorax phantom for deformable image registration (DIR) quality assurance (QA) and to verify as a tool for commissioning and DIR QA. The phantom consists of a base phantom, an inner phantom, and a motor-derived piston. The base phantom is an acrylic cylinder phantom with a diameter of 180 mm. The inner phantom consists of deformable, 20 mm thick disk-shaped sponges. To evaluate the physical characteristics of the phantom, we evaluated its image quality and deformation. DIR accuracies were evaluated using the three types of commercially DIR software (MIM, RayStation, and Velocity AI) to test the feasibility of this phantom. We used different DIR parameters to test the impact of parameters on DIR accuracy in various phantom settings. To evaluate DIR accuracy, a target registration error (TRE) was calculated using the anatomical landmark points. The three locations (i.e., distal, middle, and proximal positions) had different displacement amounts. This result indicated that the inner phantom was not moved but deformed. In cases with different phantom settings and marker settings, the ranges of the average TRE were 0.63–15.60 mm (MIM). In cases with different DIR parameters settings, the ranges of the average TRE were as follows: 0.73–7.10 mm (MIM), 8.25–8.66 mm (RayStation), and 8.26–8.43 mm (Velocity). These results suggest that our phantom could evaluate the detailed DIR behaviors with TRE. 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The three locations (i.e., distal, middle, and proximal positions) had different displacement amounts. This result indicated that the inner phantom was not moved but deformed. In cases with different phantom settings and marker settings, the ranges of the average TRE were 0.63–15.60 mm (MIM). In cases with different DIR parameters settings, the ranges of the average TRE were as follows: 0.73–7.10 mm (MIM), 8.25–8.66 mm (RayStation), and 8.26–8.43 mm (Velocity). These results suggest that our phantom could evaluate the detailed DIR behaviors with TRE. Therefore, this is indicative of the potential usefulness of our phantom in DIR commissioning and QA.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.ejmp.2020.08.007</doi><tpages>8</tpages><orcidid>https://orcid.org/0000-0001-5018-3800</orcidid></addata></record>
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subjects	Deformable image registration Physical phantom Quality assurance Radiotherapy Target registration error
title	Development of a dynamic deformable thorax phantom for the quality management of deformable image registration
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