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《南京师大学报（自然科学版）》[ISSN:1001-4616/CN:32-1239/N]

Issue:

2023年04期

Page:

91-102

Research Field:

计算机科学与技术

Publishing date:

Info

Title:

Graph-cut Algorithm for Bone Boundary Enhancement Filtering

Author(s):

Shi Zhiliang¹; Fan Weinan¹; Gan Zibo¹; Yuan Qiong²

(1.School of Mechanical and Electrical Engineering,Wuhan University of Technology,Wuhan 430070,China)
(2.College of Computer,Hubei University of Education,Wuhan 430205,China)

Keywords:

bone tissue;  automatic segmentation;  graph-cuts;  bone boundary enhancement filtering;  Hessian matrix

PACS:

TP391.41

DOI:

10.3969/j.issn.1001-4616.2023.04.013

Abstract:

Accurate bone tissue segmentation is a necessary step to assist orthopedic disease diagnosis and surgical planning. Automatic segmentation of bone tissue has always been a difficult problem in medical image segmentation due to blurred bone boundaries,low contrast,and narrow bone joint interval. The traditional graph-cut algorithm is only based on intensity feature of the image,which not only requires manual setting seed points,but also has some problems such as unclear bone boundary at the joint. Therefore,a new image segmentation algorithm is proposed by combining bone boundary enhancement filtering,morphological theory and graph cut algorithm. Taking the graph-cut algorithm as the framework,bone boundary enhancement filtering is designed based on the Hessian matrix,and the filtering result is converted into a constraint term and added to the energy function of the graph-cut,and the graph-cut model is solved to obtain the preliminary segmentation results. The preliminary result is subjected to a post-processing method of first eroding and then simple graph-cut. The corrosion image is used to replace the manual input to initialize the graph-cut model to realize the automatic separation of adjacent bone tissue. Algorithm validation was performed using an internal femur dataset,the Cancer Image Archive(TCIA)public dataset. The experimental results show that compared with threshold segmentation,region growth,and traditional graph-cut,the algorithm achieves better results in Dice,accuracy,F1 score and other indicators,and can be used as a reliable basis for clinical diagnosis.

References:

[1]ZHAO S W,WANG P J,HEIDARI A A,et al. Multilevel threshold image segmentation with diffusion association slime mould algorithm and Renyi's entropy for chronic obstructive pulmonary disease[J]. Computers in biology and medicine,2021,134:104427.
[2]ZHENG Z A B,ZHANG X,CHANG B,et al. Semi-automatic liver segmentation in CT images through intensity separation and region growing[J]. Procedia computer science,2018,131:220-225.
[3]CHENG Z,WANG J. Improved region growing method for image segmentation of three-phase materials[J]. Powder technology,2020,368:80-89.
[4]张桂梅,周飞飞,储珺. 一种改进的变分水平集的图像分割算法[J]. 图学学报,2015,36(5):740-746.
[5]LE Z,LTSA B,TW D,et al. A survey on regional level set image segmentation models based on the energy functional similarity measure[J]. Neurocomputing,2021,452:606-622.
[6]WU C,KANG Z. Robust entropy-based symmetric regularized picture fuzzy clustering for image segmentation[J]. Digital signal processing,2021,110:102905.
[7]康家银,张文娟. 用于图像分割的非局部空间约束的核FCM算法[J]. 南京师大学报(自然科学版),2019,42(3):122-128.
[8]朱红,何瀚志,方谦昊,等. 面向医学图像分割的蚁群密度峰值聚类[J]. 南京师大学报(自然科学版),2019,42(2):1-8.
[9]CHEN Y K,WU X M,CAI K,et al. CT Image Segmentation based on Clustering and Graph-Cuts[J]. Procedia engineering,2011,15:5179-5184.
[10]BOYKOV Y Y. Interactive graph cuts for optimal boundary & region segmentation of objects in n-d images[C]//Proc Eighth IEEE International Conference on Comput Vis. USA:IEEE Computer Society,2001,7:105-112.
[11]BOYKOV Y,FUNKA-LEA G. Graph cuts and efficient N-D image segmentation[J]. International journal of computer vision,2006,70(2):109-131.
[12]ABABNEH S Y,PRESCOTT J W,GURCAN M N. Automatic graph-cut based segmentation of bones from knee magnetic resonance images for osteoarthritis research[J]. Medical image analysis,2011,15(4):438-448.
[13]NAKAGOMI K,SHIMIZU A,KOBATAKE H,et al. Multi-shape graph cuts with neighbor prior constraints and its application to lung segmentation from a chest CT volume[J]. Medical image analysis,2013,17:62-77.
[14]胡局新,丁宾,邵晓根. 基于图切的交互式图像分割方法[J]. 南京师范大学学报(工程技术版),2014,14(4):62-65,70.
[15]王万耀,段先华,徐丹,等. 基于显著性的Grabcut图像分割方法[J]. 计算机工程,2018,44(7):230-243.
[16]HUANG Q,DING H,WANG X,et al. Fully automatic liver segmentation in CT images using modified graph cuts and feature detection[J]. Computers in biology & medicine,2018,95:198-208.
[17]JEBA J A,DEVI S N. Efficient graph cut optimization using hybrid kernel functions for segmentation of FDG uptakes in fused PET/CT images[J]. Applied soft computing,2019,85:105815.
[18]LIU Z,SONG Y Q,SHENG V S,et al. Liver CT sequence segmentation based with improved U-Net and graph cut[J]. Expert systems with application,2019,126:54-63.
[19]SIRIAPISITH T,KUSAKUNNIRAN W,HADDAWY P. Pyramid graph cut:Integrating intensity and gradient information for grayscale medical image segmentation[J]. Computers in biology and medicine,2020,126:103997.
[20]ZHEN Y,YQZA C,MIAO L,et al. Semi-automatic liver tumor segmentation with adaptive region growing and graph cuts[J]. Biomedical signal processing and control,2021,68:102670.
[21]JCGS A,MMAB C,MSA B,et al. Segmentation of bones in medical dual-energy computed tomography volumes using the 3D U-Net[J]. Physica medica,2020,69:241-247.

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Last Update: 2023-12-15