You-Chen Tao, L. Chunmei, Dai Chunhua, Cheng Deyu, Dang Jun
{"title":"Bilateral filtering based sliding motion compensated 4D-CBCT: a simulation study","authors":"You-Chen Tao, L. Chunmei, Dai Chunhua, Cheng Deyu, Dang Jun","doi":"10.13491/J.ISSN.1004-714X.2021.03.005","DOIUrl":null,"url":null,"abstract":"Objective This study reconstructed 4D-CBCT for fully automatic compensated sliding motion by\n incorporating the bilateral filtering into the Deformable Vector Field (DVF).\n Methods First, a motion compensated simultaneous algebraic reconstruction technique (Modified\n Simultaneous Algebra Reconstruction Technique, mSART) was used to generate a high\n quality reference phase by using all phase projection stogether with the initial 4D-DVFs,\n which were generated via Demons registration between 0% phase and each other phaseimage. The 4D-DVF was optimized\n by matching the forward projection of the deformed 0% phase with the measured projection\n of the target phase. The loss function’s DVF smoothing constrain term contained bilateral\n filtering kernel that contained: 1) an spatial domain Guassian kernel; 2) animage\n intensity domain Guassian kernel; and 3) a DVF domain Guassian kernel. By choosing\n suitable kernel variances, the sliding motion can be extracted. A non-linear conjugate\n gradient optimizer wasused. We validated the algorithm on a Non-Uniform Rotational\n B-spline based Cardiac-Torso (NCAT) phantom. Quantification was evaluated by: 1) the\n Root-Mean-Square-Error (RMSE) together with the Maximum-Error (MaxE); 2) the Dice\n coefficient of the extracted lung contour from the final reconstructed images and\n 3) the relative reconstruction error (RE) to evaluate the algorithm’s performance.\n Results The motion trajectory’s RMSE/MaxEare 0.796/1.02 mm for bilateral filtering reconstruction;\n and 2.704/4.08 mm for original reconstruction. Image content such a stherib position,\n the hearted gedefinition, the fibrous structures all had been better corrected with\n bilateral filtering.\n Conclusion We developed a bilateral filtering based fully automatic sliding motion compensated\n 4D-CBCT scheme. Digital phantom study confirmed the improved motion estimation and\n image reconstruction ability. It can be used as a 4D-CBCT image guidance tool for\n lung SBRT treatment.\n 摘要: 目的 将双边滤波引入基于可变形矢量场 (DVF) 的 4D-CBCT 重建, 实现全自动滑动运动补偿 4D-CBCT 重 建。\n 方法 首先利用所有相位投影, 用改良的运动补偿瞬时代数重建技术 (Modified Simultaneous Algebra Reconstruction Technique,\n mSART) 生成高质 量参考相位。初始 4D-DVF 通过 0% 相位和其他相位图像依次配准生成。之后通过 配准目标相位测量投影和参考相位变形到目标相位后的正投来优化求解\n 4D-DVF。优化过程中的损失函数平滑约束 项中引入双边滤波。其包含 3 个子核:空间域 Guassian 核; 图像强度域 Guassian 核; 和 DVF 域\n Guassian 核。选择合适 的子核方差提取滑动运动, 采用非线性共轭梯度算子优化, 用 B 样条心脏躯干体模 (NURBS-based Cardiac-Torso\n phantom, NCAT phantom) 验证算法。采用量化评价指标: Root-Mean-Square-Error (RMSE) 和最大误差 (MaxE);\n 重建图 像提取的肺轮廓 Dice 系数和相对重建误差 (RE) 评价算法性能。\n 结果 NCAT 模体的双边滤波重建运动轨迹的 RMSE/MaxE 为 0.796/1.02 mm; 原始重建方法的相应结果为 2.704/4.08 mm。图像中的特定结构如肋骨位置,\n 心脏边缘 的定义, 纤维结构通过双边过滤都得到了更好的纠正。\n 结论 开发了一种基于双边滤波的全自动滑动运动补偿 4D-CBCT 方案, 数字模体研宄证实了改进的运动估计和图像重建能力, 其可被用作肺 SBRT 治疗的 4D-CBCT\n 图像引 导工具。","PeriodicalId":58844,"journal":{"name":"中国辐射卫生","volume":" ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"中国辐射卫生","FirstCategoryId":"1087","ListUrlMain":"https://doi.org/10.13491/J.ISSN.1004-714X.2021.03.005","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Objective This study reconstructed 4D-CBCT for fully automatic compensated sliding motion by
incorporating the bilateral filtering into the Deformable Vector Field (DVF).
Methods First, a motion compensated simultaneous algebraic reconstruction technique (Modified
Simultaneous Algebra Reconstruction Technique, mSART) was used to generate a high
quality reference phase by using all phase projection stogether with the initial 4D-DVFs,
which were generated via Demons registration between 0% phase and each other phaseimage. The 4D-DVF was optimized
by matching the forward projection of the deformed 0% phase with the measured projection
of the target phase. The loss function’s DVF smoothing constrain term contained bilateral
filtering kernel that contained: 1) an spatial domain Guassian kernel; 2) animage
intensity domain Guassian kernel; and 3) a DVF domain Guassian kernel. By choosing
suitable kernel variances, the sliding motion can be extracted. A non-linear conjugate
gradient optimizer wasused. We validated the algorithm on a Non-Uniform Rotational
B-spline based Cardiac-Torso (NCAT) phantom. Quantification was evaluated by: 1) the
Root-Mean-Square-Error (RMSE) together with the Maximum-Error (MaxE); 2) the Dice
coefficient of the extracted lung contour from the final reconstructed images and
3) the relative reconstruction error (RE) to evaluate the algorithm’s performance.
Results The motion trajectory’s RMSE/MaxEare 0.796/1.02 mm for bilateral filtering reconstruction;
and 2.704/4.08 mm for original reconstruction. Image content such a stherib position,
the hearted gedefinition, the fibrous structures all had been better corrected with
bilateral filtering.
Conclusion We developed a bilateral filtering based fully automatic sliding motion compensated
4D-CBCT scheme. Digital phantom study confirmed the improved motion estimation and
image reconstruction ability. It can be used as a 4D-CBCT image guidance tool for
lung SBRT treatment.
摘要: 目的 将双边滤波引入基于可变形矢量场 (DVF) 的 4D-CBCT 重建, 实现全自动滑动运动补偿 4D-CBCT 重 建。
方法 首先利用所有相位投影, 用改良的运动补偿瞬时代数重建技术 (Modified Simultaneous Algebra Reconstruction Technique,
mSART) 生成高质 量参考相位。初始 4D-DVF 通过 0% 相位和其他相位图像依次配准生成。之后通过 配准目标相位测量投影和参考相位变形到目标相位后的正投来优化求解
4D-DVF。优化过程中的损失函数平滑约束 项中引入双边滤波。其包含 3 个子核:空间域 Guassian 核; 图像强度域 Guassian 核; 和 DVF 域
Guassian 核。选择合适 的子核方差提取滑动运动, 采用非线性共轭梯度算子优化, 用 B 样条心脏躯干体模 (NURBS-based Cardiac-Torso
phantom, NCAT phantom) 验证算法。采用量化评价指标: Root-Mean-Square-Error (RMSE) 和最大误差 (MaxE);
重建图 像提取的肺轮廓 Dice 系数和相对重建误差 (RE) 评价算法性能。
结果 NCAT 模体的双边滤波重建运动轨迹的 RMSE/MaxE 为 0.796/1.02 mm; 原始重建方法的相应结果为 2.704/4.08 mm。图像中的特定结构如肋骨位置,
心脏边缘 的定义, 纤维结构通过双边过滤都得到了更好的纠正。
结论 开发了一种基于双边滤波的全自动滑动运动补偿 4D-CBCT 方案, 数字模体研宄证实了改进的运动估计和图像重建能力, 其可被用作肺 SBRT 治疗的 4D-CBCT
图像引 导工具。
Objective This study reconstructed 4D-CBCCT for fully automated compensated sliding motion by incorporating the bile filtering into the Deformable Vector Field (DVF) Methods First, a motion compensated simultaneous algebraic reconstruction technique (Modified Simultaneous Algebra Reconstruction Technique, mSART) was used to generate a high quality reference phase by using all phase projections together with the initial 4D-DVF, which were generated via Demons registration between 0% phase and each other phase image The 4D-DVF was optimized by matching the forward project of the deformed 0% phase with the measured project of the target phase The loss function's DVF smoothing constraint term contained bilateral filtering kernel that contained: 1) an spatial domain Gaussian kernel; 2) Image intensity domain Gaussian kernel; And 3) a DVF domain Guassian kernel By choosing suitable kernel variations, the sliding motion can be extracted A non linear conjugate gradient optimizer wasted We validated the algorithm on a Non Uniform Rotational B-spline based Cardiac Torso (NCAT) phantom Quantification was evaluated by: 1) the Root Mean Square Error (RMSE) together with the Maximum Error (MaxE); 2) The Dice coefficient of the extracted lung resource from the final reconstructed images and 3) the relative reconstruction error (RE) to evaluate the algorithm's performance Results The motion trajectory's RMSE/MaxEarth 0.796/1.02 mm for bilateral filtering reconstruction; And 2.704/4.08 mm for original reconstruction Image content such as a sterib position, the heated gedefinition, the fibrous structures all had been better corrected with bilateral filtering Conclusion We developed a bilateral filtering based fully automatic sliding motion compensated 4D-CBCCT scheme Digital phantom study confirmed the improved motion estimation and image reconstruction capability It can be used as a 4D-CBCCT image guidance tool for lung SBRT treatment Abstract: The purpose is to introduce bilateral filtering into 4D-CBCCT reconstruction based on Deformable Vector Field (DVF), and achieve fully automatic sliding motion compensation 4D-CBCCT reconstruction. The method first utilizes all phase projections and generates high-quality reference phases using an improved motion compensated instantaneous algebraic reconstruction technique (mSART). The initial 4D-DVF is generated by sequentially registering 0% phase and other phase images. Afterwards, the 4D-DVF is optimized by registering the target phase measurement projection and deforming the reference phase to the forward projection of the target phase. Introducing bilateral filtering in the smoothing constraint of the loss function during the optimization process. It contains three sub kernels: the spatial domain Guassian kernel; Image intensity domain Guassian kernel; And DVF domain Guassian core. Select the appropriate sub kernel variance to extract sliding motion, optimize using nonlinear conjugate gradient operator, and validate the algorithm using B-spline Cardiac Torso phantom (NCAT phantom). Adopting quantitative evaluation indicators: Root Mean Square Error (RMSE) and Maximum Error (MaxE); The Dice coefficient and relative reconstruction error (RE) of lung contour extracted from reconstructed images are used to evaluate the performance of the algorithm. The RMSE/MaxE of the bilateral filtering reconstruction motion trajectory of the NCAT phantom was 0.796/1.02 mm; The corresponding result of the original reconstruction method is 2.704/4.08 mm. Specific structures in the image, such as rib position, definition of heart edge, and fiber structure, have been better corrected through bilateral filtering. Conclusion: A fully automatic sliding motion compensation 4D-CBCCT scheme based on bilateral filtering has been developed, and digital phantom research has confirmed the improved motion estimation and image reconstruction capabilities, which can be used as a 4D-CBCCT image guidance tool for lung SBRT treatment.
期刊介绍:
Chinese Journal of Radiological Health is one of the Source Journals for Chinese Scientific and Technical Papers and Citations and belongs to the series published by Chinese Preventive Medicine Association (CPMA). It is a national academic journal supervised by National Health Commission of the People’s Republic of China and co-sponsored by Institute of Radiation Medicine, Shandong Academy of Medical Sciences and CPMA, and is a professional academic journal publishing research findings and management experience in the field of radiological health, issued to the public in China and abroad. Under the guidance of the Communist Party of China and the national press and publication policies, the Journal actively publicizes the guidelines and policies of the Party and the state on health work, promotes the implementation of relevant laws, regulations and standards, and timely reports new achievements, new information, new methods and new products in the specialty, with the aim of organizing and promoting the academic communication of radiological health in China and improving the academic level of the specialty, and for the purpose of protecting the health of radiation workers and the public while promoting the extensive use of radioisotopes and radiation devices in the national economy. The main columns include Original Articles, Expert Comments, Experience Exchange, Standards and Guidelines, and Review Articles.
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