Literature DB >> 20175482

Object-constrained meshless deformable algorithm for high speed 3D nonrigid registration between CT and CBCT.

Ting Chen1, Sung Kim, Sharad Goyal, Salma Jabbour, Jinghao Zhou, Gunaretnum Rajagopal, Bruce Haffty, Ning Yue.   

Abstract

PURPOSE: High-speed nonrigid registration between the planning CT and the treatment CBCT data is critical for real time image guided radiotherapy (IGRT) to improve the dose distribution and to reduce the toxicity to adjacent organs. The authors propose a new fully automatic 3D registration framework that integrates object-based global and seed constraints with the grayscale-based "demons" algorithm.
METHODS: Clinical objects were segmented on the planning CT images and were utilized as meshless deformable models during the nonrigid registration process. The meshless models reinforced a global constraint in addition to the grayscale difference between CT and CBCT in order to maintain the shape and the volume of geometrically complex 3D objects during the registration. To expedite the registration process, the framework was stratified into hierarchies, and the authors used a frequency domain formulation to diffuse the displacement between the reference and the target in each hierarchy. Also during the registration of pelvis images, they replaced the air region inside the rectum with estimated pixel values from the surrounding rectal wall and introduced an additional seed constraint to robustly track and match the seeds implanted into the prostate. The proposed registration framework and algorithm were evaluated on 15 real prostate cancer patients. For each patient, prostate gland, seminal vesicle, bladder, and rectum were first segmented by a radiation oncologist on planning CT images for radiotherapy planning purpose. The same radiation oncologist also manually delineated the tumor volumes and critical anatomical structures in the corresponding CBCT images acquired at treatment. These delineated structures on the CBCT were only used as the ground truth for the quantitative validation, while structures on the planning CT were used both as the input to the registration method and the ground truth in validation. By registering the planning CT to the CBCT, a displacement map was generated. Segmented volumes in the CT images deformed using the displacement field were compared against the manual segmentations in the CBCT images to quantitatively measure the convergence of the shape and the volume. Other image features were also used to evaluate the overall performance of the registration.
RESULTS: The algorithm was able to complete the segmentation and registration process within 1 min, and the superimposed clinical objects achieved a volumetric similarity measure of over 90% between the reference and the registered data. Validation results also showed that the proposed registration could accurately trace the deformation inside the target volume with average errors of less than 1 mm. The method had a solid performance in registering the simulated images with up to 20 Hounsfield unit white noise added. Also, the side by side comparison with the original demons algorithm demonstrated its improved registration performance over the local pixel-based registration approaches.
CONCLUSIONS: Given the strength and efficiency of the algorithm, the proposed method has significant clinical potential to accelerate and to improve the CBCT delineation and targets tracking in online IGRT applications.

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Year:  2010        PMID: 20175482     DOI: 10.1118/1.3271389

Source DB:  PubMed          Journal:  Med Phys        ISSN: 0094-2405            Impact factor:   4.071


  8 in total

1.  A magnetic resonance spectroscopy driven initialization scheme for active shape model based prostate segmentation.

Authors:  Robert Toth; Pallavi Tiwari; Mark Rosen; Galen Reed; John Kurhanewicz; Arjun Kalyanpur; Sona Pungavkar; Anant Madabhushi
Journal:  Med Image Anal       Date:  2010-10-28       Impact factor: 8.545

2.  Demons deformable registration of CT and cone-beam CT using an iterative intensity matching approach.

Authors:  Sajendra Nithiananthan; Sebastian Schafer; Ali Uneri; Daniel J Mirota; J Webster Stayman; Wojciech Zbijewski; Kristy K Brock; Michael J Daly; Harley Chan; Jonathan C Irish; Jeffrey H Siewerdsen
Journal:  Med Phys       Date:  2011-04       Impact factor: 4.071

3.  Evaluation of Deformable Image Registration-Based Contour Propagation From Planning CT to Cone-Beam CT.

Authors:  Andrew J Woerner; Mehee Choi; Matthew M Harkenrider; John C Roeske; Murat Surucu
Journal:  Technol Cancer Res Treat       Date:  2017-03-10

4.  Deformable registration using edge-preserving scale space for adaptive image-guided radiation therapy.

Authors:  Dengwang Li; Hongjun Wang; Yong Yin; Xiuying Wang
Journal:  J Appl Clin Med Phys       Date:  2011-11-15       Impact factor: 2.102

5.  A protocol to extend the longitudinal coverage of on-board cone-beam CT.

Authors:  Dandan Zheng; Jun Lu; Ariel Jefferson; Cheng Zhang; Jian Wu; William Sleeman; Elisabeth Weiss; Nesrin Dogan; Shiyu Song; Jeffrey Williamson
Journal:  J Appl Clin Med Phys       Date:  2012-07-05       Impact factor: 2.102

6.  Evaluation of the accuracy and clinical practicality of a calculation system for patient positional displacement in carbon ion radiotherapy at five sites.

Authors:  Yoshiki Kubota; Hayato Hayashi; Satoshi Abe; Saki Souda; Ryosuke Okada; Takayoshi Ishii; Mutsumi Tashiro; Masami Torikoshi; Tatsuaki Kanai; Tatsuya Ohno; Takashi Nakano
Journal:  J Appl Clin Med Phys       Date:  2018-01-25       Impact factor: 2.102

7.  Development of an automatic evaluation method for patient positioning error.

Authors:  Yoshiki Kubota; Mutsumi Tashiro; Ayaka Shinohara; Satoshi Abe; Saki Souda; Ryosuke Okada; Takayoshi Ishii; Tatsuaki Kanai; Tatsuya Ohno; Takashi Nakano
Journal:  J Appl Clin Med Phys       Date:  2015-07-08       Impact factor: 2.102

8.  Autosegmentation of the rectum on megavoltage image guidance scans.

Authors:  L E A Shelley; M P F Sutcliffe; K Harrison; J E Scaife; M A Parker; M Romanchikova; S J Thomas; R Jena; N G Burnet
Journal:  Biomed Phys Eng Express       Date:  2019-01-10
  8 in total

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