Authors: Abder-Rahman Ali, Antoine Vacavant, Manuel Grand-Brochier, Adélaïde Albouy-Kissi, Jean-Yves Boire

Abstract:

In this paper, we present a new segmentation approach for liver lesions in regions of interest within MRI (Magnetic Resonance Imaging). This approach, based on a two-cluster Fuzzy CMeans methodology, considers the parameter variable compactness to handle uncertainty. Fine boundaries are detected by a local recursive merging of ambiguous pixels with a sequential forward floating selection with Zernike moments. The method has been tested on both synthetic and real images. When applied on synthetic images, the proposed approach provides good performance, segmentations obtained are accurate, their shape is consistent with the ground truth, and the extracted information is reliable. The results obtained on MR images confirm such observations. Our approach allows, even for difficult cases of MR images, to extract a segmentation with good performance in terms of accuracy and shape, which implies that the geometry of the tumor is preserved for further clinical activities (such as automatic extraction of pharmaco-kinetics properties, lesion characterization, etc.).

Keywords: Defuzzification, floating search, fuzzy clustering, Zernike moments.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1107886

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References:

[1] P. Maji and S. Pal. “Maximum Class Separability for Rough-Fuzzy CMeans Based Brain MR Image Segmentation,” T. Rough Sets, Vol.9, pp.114-134, 2008.
[2] “Mathematical Morphology,” (accessed May, 17 2015) http://www.cs.uu.nl/docs/vakken/ibv/reader/chapter6.pdf
[3] R. Crane, “Simplified Approach to Image Processing,” Prentice Hall, 1997.
[4] J. Russ, “Image Analysis of Food Microstructure,” CRC Press, 2004.
[5] J. Kim, “Image Enhancement for Improving Object Recognition,” Algorithm and SoC Design for Automotive Vision Systems, Springer, 2014.
[6] S. Roy, H. K. Agarwal, A. Carass, Y. Bai, D. L. Pham, J. L. Prince, “Fuzzy C-Means with Variable Compactness,” IEEE International Symposium on Biomedical Imaging, pp. 452-455, 2008.
[7] P. Pudil, J. Novovičová, J. Kittler, “Floating Search Methods in Feature Selection,” Pattern Recognition Letters, volume 15, pages 1119-1125, 1994.
[8] A. Khotanzan, Y. H. Hong, “Invariant Image Recognition by Zernike Moments,” IEEE Trans. PAMI, 12:489–497, 1990.
[9] B. Oluleye, A. Leisa, J. Leng, D. Dean, “Zernike Moments and Genetic Algorithm: Tutorial and Application,” British Journal of Mathematics & Computer Science 4(15): 2217-2236, 2014.
[10] A. Ali, A. Albouy-Kissi, A. Vacavant, M. Grand-brochier, J. Boire, “A Novel Fuzzy C-Means Based Defuzzification Approach with an Adapted Minkowski Distance,” 19th Computer Vision Winter Workshop Zuzana Kúkelová and Jan Heller (eds.) Křtiny, Czech Republic, 2014.
[11] R. Fang, R. Zabih, A. Raj, T. Chen, “Segmentation of Liver Tumor Using Efficient Global Optimal Tree Metrics Graph Cuts," In Abdominal Imaging. Computational and Clinical Applications, 2012.
[12] D. Pham, “Robust Fuzzy Segmentation of Magnetic Resonance Images, 14th IEEE Symposium on Computer-Based Medical Systems, p. 127- 131, 2001.
[13] C. Teh and R.T. Chin, “On Image Analysis by the Methods of Moments,” IEEE Trans. on PAMI, 10 (4). 496-513, 1988.
[14] M. Teague, “Image Analysis via the General Theory of Moments,” Journal of the Optical Society of America, 70 (8). 920-930, 1980.
[15] J.S. Lipscomb, “A Trainable Gesture Recognizer,” Pattern Recognition, 24 (9). 895-907, 1991.
[16] H. Hse and A. Newton, “Sketched Symbol Recognition Using Zernike Moments,” In Proceedings of ICPR, 2004.
[17] A. Tahmasbi, F. Saki, and S. B. Shokouhi, "Classification of Benign and Malignant Masses Based on Zernike Moments," J. Computers in Biology and Medicine, vol. 41, no. 8, pp. 726-735, 2011.
[18] A. Tahmasbi, F. Saki, H. Aghapanah, and S. B. Shokouhi, "A Novel Breast Mass Diagnosis System based on Zernike Moments as Shape and Density Descriptors," In Proc. IEEE, 18th Iranian Conf. on Biomedical Engineering (ICBME'2011), Tehran, Iran, pp. 100-104, 2011.
[19] M. Grand-Brochier, A. Vacavant, G. Cerutti, K. Bianchi, and L. Tougne, “Comparative Study of Segmentation Methods for Tree Leaves Extraction,” In ACM ICVS 2013, Workshop: VIGTA, Saint Petersburg, Russia, 2013.