基于双调和插值的锥束CT金属伪影校正算法

计算机工程与科学 ›› 2024, Vol. 46 ›› Issue (03): 471-478.

基于双调和插值的锥束CT金属伪影校正算法

王中昊,夏竟,李世杰,蔡志平

(国防科技大学计算机学院，湖南长沙 410073)

收稿日期:2023-09-06 修回日期:2023-10-26 接受日期:2024-03-25 出版日期:2024-03-25 发布日期:2024-03-15

A metal artifact correction algorithm for cone beam CT based on biharmonic equation interpolation

WANG Zhong-hao,XIA Jing,LI Shi-jie,CAI Zhi-ping

(College of Computer Science and Technology,National University of Defense Technology,Changsha 410073,China)

Received:2023-09-06 Revised:2023-10-26 Accepted:2024-03-25 Online:2024-03-25 Published:2024-03-15

摘要/Abstract

摘要： 在计算机断层扫描 (CT)中，金属植入物会引入严重的伪影，导致图像质量降低影响诊断价值。为了对锥束CT中的金属伪影进行校正，提出了一种基于双调和方程的金属伪影校正算法。首先，对含金属伪影的重建图像进行双边滤波和金属阈值分割，获得金属和非金属图像；然后，对二者进行正向投影，获得金属投影区域和先验投影图像；接下来，利用先验投影图像对原始投影进行归一化，并对金属区域进行双调和方程插值修复，获得修复的投影数据；最后，对修复的投影数据去归一化,并利用FDK 算法进行重建，再与金属图像融合获得最终的校正图像。为了验证该算法的性能，采用实际拍摄的数据进行金属伪影校正实验。结果表明，与常用的线性插值校正算法和归一化校正算法相比，所提算法ROI区域内图像的均方根误差分别减少了22%和8%，有效地抑制了金属伪影，优于常用的去金属伪影算法。

关键词: 锥束CT, 金属伪影校正, 双调和插值, 修复, 归一化校正

Abstract: In computed tomography (CT), metal implants introduce severe artifacts, leading to degraded image quality and impacting diagnostic value. To correct metal artifacts in cone beam CT, a metal artifact correction algorithm based on the biharmonic equation is proposed. Firstly, the reconstructed image with metal artifacts is filtered using bilateral filtering and segmented using a metal threshold, obtaining metal and non-metal images. Secondly, forward projection is applied to both images, generating metal projection regions and prior projection images. Thirdly, the original projection is normalized using the prior projection image, and the metal regions are repaired using biharmonic equation interpolation, resulting in the repaired projection data. The repaired projection data is then denormalized and reconstructed using the FDK algorithm. Finally, the reconstructed image is fused with the metal image to obtain the final corrected image. To validate the performance of this algorithm, experiments on metal artifact correction were conducted using real acquired data. The results show that compared to commonly used linear interpolation and normalization correction algorithms, the root mean square errors within the region of interest (ROI) are reduced by 22% and 8% respectively. This algorithm effectively suppresses metal artifacts and outperforms commonly used metal artifact removal methods.

Key words: cone beam CT, metal artifact correction, biharmonic equation interpolation, inpaint, normalization correction

王中昊, 夏竟, 李世杰, 蔡志平. 基于双调和插值的锥束CT金属伪影校正算法[J]. 计算机工程与科学, 2024, 46(03): 471-478.

WANG Zhong-hao, XIA Jing, LI Shi-jie, CAI Zhi-ping. A metal artifact correction algorithm for cone beam CT based on biharmonic equation interpolation[J]. Computer Engineering & Science, 2024, 46(03): 471-478.

参考文献［20］

［1］	Govila S,Gundappa M.Cone beam computed tomography an overview［J］.Journal of Conservative Dentistry,2007,10(2):53-58.
［2］	Karimi S,Cosman P,Wald C,et al.Segmentation of artifacts and anatomy in CT metal artifact reduction［J］.Medical Physics,2012,39(10):5857-5868.
［3］	Kim J,Nam H, Lee R.Development of a new metal artifact reduction algorithm by using an edge preserving method for CBCT imaging［J］.Journal of the Korean Physical Society,2015,67(1):180-188.
［4］	Lewitt R M,Bates R H T,Sank V J.Image reconstruction from projections:General theoretical considerations［J］.Journal of Computer Assisted Tomography,1978,2(5):670.
［5］	Kalender W A,Hebel R,Ebersberger J.Reduction of CT artifacts caused by metallic implants［J］.Radiology,1987,164(2):576-577.
［6］	Meyer E,Raupach R,Lell M,et al.Normalized metal artifact reduction (NMAR) in computed tomography［J］. Medical Physics,2010,37(10):5482-5493.
［7］	Liu H Y,Yang T,Huang W M,et al.NMAR3:Normalized metal artifact reduction for cone beam computed tomography［C］∥Proc of the 42nd Annual International Conference of the IEEE Engineering in Medicine & Biology Society,2020:1311-1314.
［8］	Meilinger M,Schmidgunst C,Schütz O,et al.Metal artifact reduction in cone beam computed tomography using forward projected reconstruction information［J］.Zeitschrift Fur Medizinische Physik,2011,21(3):174-182.
［9］	Gordon R,Bender R,Herman G T.Algebraic reconstruction techniques (ART) for three-dimensional electron microscopy and X-ray photography［J］.Journal of Theoretical Biology,1970,29(3):471-481.
［10］	Levakhina Y M,Muller J,Duschka R L,et al.Weighted simultaneous algebraic reconstruction technique for tomosynthesis imaging of objects with high-attenuation features［J］.Medical Physics,2013,40(3):031106.
［11］	Gjesteby L, Shan H M,Yang Q S,et al.A dual-stream deep convolutional network for reducing metal streak artifacts in CT images［J］.Physics in Medicine & Biology,2019,64(23):235003.
［12］	Ghani M U,Karl W C.Fast accurate CT metal artifact reduction using data domain deep learning［J］.IEEE Transactions on Computational Imaging,2019,6:181-193.
［13］	Hong L,Lin L,Chen J,et al.CT image features of the FBP reconstruction algorithm in the evaluation of fasting blood sugar level of diabetic pulmonary tuberculosis patients and early diet nursing［J］.Computational and Mathematical Methods in Medicine,2021,40:1101930.
［14］	Turbell H. Cone-beam reconstruction using filtered backprojection ［D］.Linkping:Linkping University,2001.
［15］	张剑,陈志强.三维锥形束CT成像FDK重建算法发展综述［J］.中国体视学与图像分析,2005,10(2):116-121.
	Zhang Jian,Chen Zhi-qiang.Review of recent development in FDK reconstruction algorithms for 3D cone beam CT［J］.Chinese Journal of Stereology and Image Analysis,2005,10(2):116-121.
［16］	Humphries T, Wang B.Superiorized method for metal artifact reduction［J］.Medical Physics,2020,47(9):3984-3995.
［17］	Han H D, Han J K.Modified bilateral filter for feature enhancement in mesh denoising［J］.IEEE Access,2022,10:56845-56862.
［18］	Damelin S B,Hoang N S.On surface completion and image inpainting by biharmonic functions:Numerical aspects［J］.International Journal of Mathematics and Mathematical Sciences,2018,3:1-8.
［19］	徐晶晶，钟金标.一类双调和方程组边值问题的可解性［J］.安庆师范大学学报（自然科学版）,2023,29（3）:25-29.
	Xu Jing-jing, Zhong Jin-biao. Solvability of boundary value problems of a class of biharmonic equation system［J］.Journal of Anqing Normal University(Natural Science Edition),2023,29(3):25-29.
［20］	Liu Y C,Zhang C S,Li W R,et al.An adaptive multiscale anisotropic diffusion regularized image reconstruction method for digital breast tomosynthesis［J］.Australasian Physical & Engineering Sciences in Medicine,2018,41(4):993-1008.

[1]	孙琪, 翟锐, 左方, 张玉涛, . 基于部分卷积和多尺度特征融合的人脸图像修复模型[J]. 计算机工程与科学, 2023, 45(02): 304-312.
[2]	庞兴龙, 朱国胜, 杨少龙, 李修远. 一种基于聚类与噪声的网络流量分类方法[J]. 计算机工程与科学, 2022, 44(07): 1207-1215.
[3]	杨慧慧, 方贤文, 邵叱风. 基于Petri网的并发事件流程模型修复分析[J]. 计算机工程与科学, 2021, 43(10): 1773-1780.
[4]	段荧, 龙华, 瞿于荃, 邵玉斌, 杜庆治, . 基于部分卷积的文字图像不规则干扰修复算法研究[J]. 计算机工程与科学, 2021, 43(09): 1634-1644.
[5]	刘国华1,2，段建春1. 基于Kinect相机的深度图像空洞修复及超像素分割算法[J]. 计算机工程与科学, 2020, 42(05): 851-858.
[6]	秦盼1，王健2，朱芳1，焦贵忠1. SoC嵌入式存储器内建自修复方法[J]. 计算机工程与科学, 2019, 41(10): 1749-1754.
[7]	冀中，赵硕，王建，刘立. 基于噪声检测的总变分去噪算法[J]. 计算机工程与科学, 2018, 40(03): 507-514.
[8]	任小康，陈培林. 基于广义回归神经网络的壁画修复研究[J]. 计算机工程与科学, 2017, 39(10): 1884-1889.
[9]	张素琪1，顾军华2，尹君2，郭京津2. 求解最大团问题的混合修复遗传算法及其在社会网络中的应用[J]. 计算机工程与科学, 2016, 38(12): 2551-2559.
[10]	任小康，邓琳凯. 基于尺度空间的小波纹理描述算法的壁画修复[J]. J4, 2014, 36(11): 2191-2195.
[11]	袁强，赵振宇，窦强，李鹏，刘海斌. 三维芯片中TSV链式冗余修复电路的设计与实现[J]. J4, 2014, 36(05): 828-835.
[12]	任小康，邓琳凯. 基于颜色聚类分割及改进的FMM算法的壁画修复[J]. J4, 2014, 36(02): 298-302.
[13]	刘志明1,3,沙基昌1，万亚平2,3,阳小华3. 节点在线率和资源热度相关的P2P存储系统副本复制和修复策略[J]. J4, 2011, 33(2): 186-190.
[14]	孙彩霞唐宏伟张民选. 后备栈：一种高效的返回地址栈修复机制[J]. J4, 2006, 28(6): 115-117.