TY - GEN
T1 - Comprehensive evaluation of an image segmentation technique for measuring tumor volume from CT images
AU - Deng, Xiang
AU - Huang, Haibin
AU - Zhu, Lei
AU - Du, Guangwei
AU - Xu, Xiaodong
AU - Sun, Yiyong
AU - Xu, Chenyang
AU - Jolly, Marie Pierre
AU - Chen, Jiuhong
AU - Xiao, Jie
AU - Merges, Reto
AU - Suehling, Michael
AU - Rinck, Daniel
AU - Song, Lan
AU - Jin, Zhengyu
AU - Jiang, Zhaoxia
AU - Wu, Bin
AU - Wang, Xiaohong
AU - Zhang, Shuai
AU - Peng, Weijun
PY - 2008
Y1 - 2008
N2 - Comprehensive quantitative evaluation of tumor segmentation technique on large scale clinical data sets is crucial for routine clinical use of CT based tumor volumetry for cancer diagnosis and treatment response evaluation. In this paper, we present a systematic validation study of a semi-automatic image segmentation technique for measuring tumor volume from CT images. The segmentation algorithm was tested using clinical data of 200 tumors in 107 patients with liver, lung, lymphoma and other types of cancer. The performance was evaluated using both accuracy and reproducibility. The accuracy was assessed using 7 commonly used metrics that can provide complementary information regarding the quality of the segmentation results. The reproducibility was measured by the variation of the volume measurements from 10 independent segmentations. The effect of disease type, lesion size and slice thickness of image data on the accuracy measures were also analyzed. Our results demonstrate that the tumor segmentation algorithm showed good correlation with ground truth for all four lesion types (r = 0.97,0.99,0.97,0.98, p < 0.0001 for liver, lung, lymphoma and other respectively). The segmentation algorithm can produce relatively reproducible volume measurements on all lesion types (coefficient of variation in the range of 10 - 20%). Our results show that the algorithm is insensitive to lesion size (coefficient of determination close to 0) and slice thickness of image data(p > 0.90). The validation framework used in this study has the potential to facilitate the development of new tumor segmentation algorithms and assist large scale evaluation of segmentation techniques for other clinical applications.
AB - Comprehensive quantitative evaluation of tumor segmentation technique on large scale clinical data sets is crucial for routine clinical use of CT based tumor volumetry for cancer diagnosis and treatment response evaluation. In this paper, we present a systematic validation study of a semi-automatic image segmentation technique for measuring tumor volume from CT images. The segmentation algorithm was tested using clinical data of 200 tumors in 107 patients with liver, lung, lymphoma and other types of cancer. The performance was evaluated using both accuracy and reproducibility. The accuracy was assessed using 7 commonly used metrics that can provide complementary information regarding the quality of the segmentation results. The reproducibility was measured by the variation of the volume measurements from 10 independent segmentations. The effect of disease type, lesion size and slice thickness of image data on the accuracy measures were also analyzed. Our results demonstrate that the tumor segmentation algorithm showed good correlation with ground truth for all four lesion types (r = 0.97,0.99,0.97,0.98, p < 0.0001 for liver, lung, lymphoma and other respectively). The segmentation algorithm can produce relatively reproducible volume measurements on all lesion types (coefficient of variation in the range of 10 - 20%). Our results show that the algorithm is insensitive to lesion size (coefficient of determination close to 0) and slice thickness of image data(p > 0.90). The validation framework used in this study has the potential to facilitate the development of new tumor segmentation algorithms and assist large scale evaluation of segmentation techniques for other clinical applications.
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U2 - 10.1117/12.769619
DO - 10.1117/12.769619
M3 - Conference contribution
AN - SCOPUS:44949098558
SN - 9780819471017
T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
BT - Medical Imaging 2008 - Image Perception, Observer Performance, and Technology Assessment
T2 - Medical Imaging 2008 - Image Perception, Observer Performance, and Technology Assessment
Y2 - 20 February 2008 through 21 February 2008
ER -