Evaluation of deformable image registration between external beam radiotherapy and HDR brachytherapy for cervical cancer with a 3D‐printed deformable pelvis phantom

Purpose In this study, we developed a 3D‐printed deformable pelvis phantom for evaluating spatial DIR accuracy. We then evaluated the spatial DIR accuracies of various DIR settings for cervical cancer. Methods A deformable female pelvis phantom was created based on patient CT data using 3D printing....

Full description

Saved in:
Bibliographic Details
Published in:Medical physics (Lancaster) 2017-04, Vol.44 (4), p.1445-1455
Main Authors: Kadoya, Noriyuki, Miyasaka, Yuya, Nakajima, Yujiro, Kuroda, Yoshihiro, Ito, Kengo, Chiba, Mizuki, Sato, Kiyokazu, Dobashi, Suguru, Yamamoto, Takaya, Takahashi, Noriyoshi, Kubozono, Masaki, Takeda, Ken, Jingu, Keiichi
Format: Article
Language:English
Subjects:
3D printer
Brachytherapy
cervical cancer
deformable image registration
dose accumulation
Female
Humans
Image Processing, Computer-Assisted - instrumentation
Pelvis - diagnostic imaging
Phantoms, Imaging
Printing, Three-Dimensional
radiotherapy
Radiotherapy Dosage
Tomography, X-Ray Computed
Uterine Cervical Neoplasms - diagnostic imaging
Uterine Cervical Neoplasms - radiotherapy
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Purpose In this study, we developed a 3D‐printed deformable pelvis phantom for evaluating spatial DIR accuracy. We then evaluated the spatial DIR accuracies of various DIR settings for cervical cancer. Methods A deformable female pelvis phantom was created based on patient CT data using 3D printing. To create the deformable uterus phantom, we first 3D printed both a model of uterus and a model of the internal cavities of the vagina and uterus. We then made a mold using the 3D printed uterus phantom. Finally, urethane was poured into the mold with the model of the internal cavities in place, creating the deformable uterus phantom with a cavity into which an applicator could be inserted. To create the deformable bladder phantom, we first 3D printed models of the bladder and of the same bladder scaled down by 2 mm. We then made a mold using the larger bladder model. Finally, silicone was poured into the mold with the smaller bladder model in place to create the deformable bladder phantom with a wall thickness of 2 mm. To emulate the anatomical bladder, water was poured into the created bladder. We acquired phantom image without applicator for EBRT. Then, we inserted the applicator into the phantom to simulate BT. In this situation, we scanned the phantom again to obtain the phantom image for BT. We performed DIR using the two phantom images in two cases: Case A, with full bladder (170 ml) in both EBRT and BT images; and Case B with full bladder in the BT image and half‐full bladder (100 ml) in the EBRT image. DIR was evaluated using Dice similarity coefficients (DSCs) and 31 landmarks for the uterus and 25 landmarks for the bladder. A hybrid intensity and structure DIR algorithm implemented in RayStation with four DIR settings was evaluated. Results On visual inspection, reasonable agreement in shape of the uterus between the phantom and patient CT images was observed for both EBRT and BT, although some regional disagreements in shape of the bladder and rectum were apparent. The created phantom could reproduce the actual patient's uterus deformation by the applicator. For both Case A and B, large variation was seen in landmark error among the four DIR parameters. In addition, although DSCs were comparable, moderate differences in landmark error existed between the two different DIR parameters selected from the four DIR parameters (i.e., DSC = 0.96, landmark error = 13.2 ± 5.7 mm vs. DSC = 0.97, landmark error = 9.7 ± 4.0 mm). This result suggests that landmar
ISSN:0094-2405
2473-4209
DOI:10.1002/mp.12168