i-manager Publications

Efficient Detection of Suspected areas in Mammographic Breast Cancer Images

Bhagwati Charan Patel*, G. R. Sinha**

* Research Scholar, Department of Information Technology, Shri Shankaracharya Technical Campus Bhilai, India.

** Professor and Associate Director, Shri Shankaracharya Technical Campus Bhilai, India.

Periodicity:December - February'2015
DOI : https://doi.org/10.26634/jpr.1.4.3305

Abstract

Breast cancer is the most common type of cancers found in women all across the world. Mammography is considered as an effective tool for early detection and diagnosis of breast cancer. The most common breast abnormalities that may indicate breast cancer are masses and micro-calcifications or calcifications. The abnormalities present in breast images are characterized by using a range of features that may be missed or misinterpreted by radiologists while reading large amount of mammographic images during cancer screening process. Computer-aided diagnosis (CAD) systems have been developed to assist radiologists to provide an accurate diagnosis. An attempt has been made to improve the classification performance of CAD system in which shape and texture are used in analyzing region of interest (ROI) of mammographic images of breast. The method detects ROI by combining edge and region criteria and then feature extraction method helps extract few statistical parameters such as sensitivity and specificity to evaluate the performance of the proposed method. The sensitivity of the proposed method is 97.5% and specificity is 91.2% that produced an accuracy of 96.6%. Size of tumor is also computed and classification stage of breast cancer is identified.

Keywords

Breast cancer, Mammography image, CAD, ROI, Feature extraction, Sensitivity, Specificity

How to Cite this Article?

Patel, B. C., and Sinha, G. R. (2015). Efficient Detection of Suspected areas in Mammographic Breast Cancer Images. i-manager’s Journal on Pattern Recognition, 1(4), 1-10. https://doi.org/10.26634/jpr.1.4.3305

References

[1]. http://www.cancermission.com/2011/08/breastcancer- in- india.html

[2]. Sinha G.R. and Patel B. C (2014). Medical Image Processing: concepts and applications, PHI Learning Private Limited.

[3]. Cheng, H.D., Shi, X.J., Min, R., Hu, L.M., Cai, X.P and Du, H.N (2006). “Approaches for Automated Detection and Classification of Masses in Mammograms”, Journal of Pattern Recognition, Vol.39 (4), pp. 646–652.

[4]. Rangayyan, R.M., Ayres, F.J., and Desautels, J.E.L (2007). “A Review of Computer-Aided Diagnosis of Breast Cancer: Toward the Detection of Subtle Signs”, Journal of the Franklin Institute, Vol. 8, pp.312–318.

[5]. Bruce, L. M., & Adhami, R. R (1999). “Classifying Mammographic Mass Shapes Using the Wavelet Transform Modulus-Maxima Method", IEEE Transaction on Medical Imaging, Vol.1, pp. 1170-1177.

[6]. Arnau, O (2007). "Automatic mass segmentation in mammographic images", Department of Electronics, Computer Science and Automatic Control, Girona.

[7]. Mumford D. and Shah J (1989). “Optimal approximation by piecewise smooth functions and associated variation problems”, Journal of Pure Applied Mathematics, Vol.10, pp. 577-585.

[8]. Mumford D., and Shah J (1985). “Boundary Detection by Minimizing Functional”, Proc. of IEEE Conf. on Computer Vision and Pattern Recognition, San Francisco, pp.176-185.

[9]. Shah J (1994). “Piecewise smooth approximations of functions”, Calculus of Variations and Partial Differential Equations, Vol.2, pp. 315-328.

[10]. Chan T. F., and Vese L.A (2001). “Active contours without edges”, IEEE Transaction on Image Processing, Vol.10, pp. 266–277.

[11]. Bresson X., Esedoglu S., Vandergheynst P., Thiran J. P. and Osher S (2005). “Fast global minimization of the active contour/ snake model”, Journal of Mathematical Imaging and Vision, Vol.28 (2), pp. 51-167.

[12]. Rousson M., and X (2007). “Convergence approximation to piecewise smooth medical image segmentation”, In Medical Image Computing and Computer Assisted Intervention, Vol. 4, pp. 495-502.

[13]. Cremers D., Schmidt F.R., and Barthel F (2007). “Shape priors in variational image segmentation: Convexity, lipschitz continuity and globally optimal solutions”, In IEEE Conference on Computer Vision and Pattern Recognition, pp. 1-6.

[14]. Leventon M.E., Eric W., Grimson L., and Faugeras O (2008). “Statistical shape in_uence in geodesic active contours”, In International Conference on Computer Vision, Vol.1, pp. 317-323.

[15]. Zheng Li and Andrew K. C (2001). “An Artificial Intelligent Algorithm for Tumor Detection in Screening Mammogram”, IEEE Transactions on Medical Imaging, Vol. 20(7), pp. 45-52.

[16]. Singhand S. and Gupta, P. R (2001). “Breast Cancer detection and Classification using Neural Network”, International Journal of Advanced Engineering Sciences and Technologies, Vol.6 (1), pp. 4-9.

[17]. Pagonis N, Cavouras D, and Sidiropoulos K (2010). “Improving The Classification Accuracy of Computer Aided Diagnosis through Multimodality Breast Imaging”, e-Journal of Science & Technology (e-JST), Vol.2 (5), pp. 33-39.

[18]. Kowal M, Filipczuk P, Obuchowicz A. and Józef Korbicz (2011). “Computer-aided Diagnosis of Breast Cancer Using Gaussian Mixture Cytological Image Segmentation”, Journal of Medical Informatics & Technologies, Vol.17, pp. 257-262.

[19]. http://www.breastcancer.org/symptoms/diagnosis/ staging. jsp

[20]. Jain, A.K., Duin, R.P.W., and Mao, J (2000). “Statistical Pattern Recognition: A Review”, IEEE Transactions on Pattern Analysis and Machine Intelligence, Vol.22 (1), pp. 4–12.

[21]. Patel B. C. and Sinha G. R (2012), “Energy and Region based Detection and Segmentation of Breast Cancer Mammographic Images”, International Journal of Image, Graphics and Signal Processing, Vol. 6, pp. 44- 51.

[22]. Chunming L, Chiu-Y.K., John C. and Zhaohua D (2010), “Minimization of Region-Scalable Fitting Energy for Image Segmentation”, IEEE Transactions on Image Processing, Vol.17, pp.10-18.

[23]. Lankton S. and Tannenbaum A (2008), “Localizing Region-Based Active Contours”, IEEE Transactions on Image Processing, Vol.17, pp. 27-36.

[24]. Kullback, S.; and Leibler, R.A (2011). “On Information and Sufficiency”, Journal of Mathematical Statistics, Vol.22 (1), pp.79–86.

[25]. Blake C. and Isard G (2006), “Model Based multiview Active Contours for Quality Inspection”, Journal of Computer Vision and Graphics, Vol. 32, pp. 565-574.

[26]. Durbin R., Szeliski R., and Yuille A (1999), “An analysis of the elastic net approach to the travelling salesman problem”, Journal of Neural Computation, Vol.1, pp.348- 358.

[27]. Chenga, H.D.; Shana, J.; Jua, W.; Guoa, Y. and Zhangb, L (2010), “Automated breast cancer detection and classification using ultrasoundimages: A survey”, Journal of Pattern Recognition, Elsevier Academic, Press, Vol.43, pp.299– 317.

[28]. Sampat, M., Markey, M., and Bovik, A (2002), “ Computer-Aided Detection and Diagnosis in Mammography”, In A. Bovik, Handbook of Image and Video Processing, pp.1195-1217.

[29]. Patel B.C. and Sinha G.R (2014), “Mammography Feature Analysis and mass Detection in Breast Cancer Images”, International conference on Electronic System, Signal Processing and Computing Technology (ICESC 2014), IEEE Conference, January 9-11, Nagpur, pp.474- 478.

Efficient Detection of Suspected areas in Mammographic Breast Cancer Images

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