Abstract
In this work, we present an active contour scheme to simultaneously extract multiple targets from MR and CT medical imagery. A number of previous active contour methods are capable of only extracting one object at a time. Therefore, when multiple objects are required, the segmentation process must be performed sequentially. Not only may this be tedious work, but moreover the relationship between the given objects is not addressed in a uniform framework, making the method prone to leakage and overlap among the individual segmentation results. On the other hand, many of the algorithms providing the capability to perform simultaneous multiple object segmentation, tacitly or explicitly assume that the union of the multiple regions equals the whole image domain. However, this is often invalid for many medical imaging tasks. In the present work, we give a straightforward methodology to alleviate these drawbacks as follows. First, local robust statistics are used to describe the object features, which are learned adaptively from user provided seeds. Second, several active contours evolve simultaneously with their interactions being governed by simple principles derived from mechanics. This not only guarantees mutual exclusiveness among the contours, but also no longer relies upon the assumption that the multiple objects fill the whole image domain. In doing so, the contours interact and converge to equilibrium at the desired positions of the given objects. The method naturally handles the issues of leakage and overlapping. Both qualitative and quantitative results are shown to highlight the algorithm’s capability of extracting several targets as well as robustly preventing the leakage.
This is a preview of subscription content, log in via an institution.
Buying options
Tax calculation will be finalised at checkout
Purchases are for personal use only
Learn about institutional subscriptionsPreview
Unable to display preview. Download preview PDF.
References
Sonka, M., Hlavac, V., Boyle, R.: Image Processing, Analysis, and Machine Vision, 2nd edn. International Thomson (1999)
Pichon, E., Tannenbaum, A., Kikinis, R.: A statistically based flow for image segmentation. Medical Image Analysis 8(3), 267–274 (2004)
Kass, M., Witkin, A., Terzopoulos, D.: Snakes: Active contour models. IJCV 1(4), 321–331 (1988)
Malladi, R., Sethian, J., Vemuri, B., et al.: Shape modeling with front propagation: A level set approach. IEEE TPAMI 17(2), 158–175 (1995)
Kichenassamy, S., Kumar, A., Olver, P., Tannenbaum, A., Yezzi, A.: Gradient flows and geometric active contour models. In: IEEE ICCV, p. 810 (1995)
Caselles, V., Kimmel, R., Sapiro, G.: Geodesic active contours. IJCV 22(1), 61–79
Yezzi, A., Kichenassamy, S., Kumar, A., Olver, P., Tannenbaum, A.: A geometric snake model for segmentation of medical imagery. IEEE TMI 16(2), 199–209 (1997)
Yezzi Jr, A., Tsai, A., Willsky, A.: A statistical approach to snakes for bimodal and trimodal imagery. In: IEEE ICCV, vol. 2 (1999)
Chan, T., Vese, L.: Active contours without edges. IEEE TIP 10(2), 266–277 (2001)
Michailovich, O., Rathi, Y., Tannenbaum, A.: Image segmentation using active contours driven by the bhattacharyya gradient flow. IEEE TIP 16(11), 2787
Lankton, S., Tannenbaum, A.: Localizing Region-Based Active Contours. IEEE TIP 17(11), 2029–2039 (2008)
Zhu, S., Yuille, A.: Region competition: Unifying snakes, region growing, and bayes/MDL for multiband image segmentation. IEEE TPAMI 18(9), 884 (1996)
Brox, T., Weickert, J.: Level set segmentation with multiple regions. IEEE TIP 15(10), 3213 (2006)
Vese, L., Chan, T.: A multiphase level set framework for image segmentation using the Mumford and Shah model. IJCV 50(3), 271–293 (2002)
Grady, L.: Random walks for image segmentation. IEEE TPAMI 28(11), 17–68
Zhao, H., Chan, T., Merriman, B., Osher, S.: A Variational Level Set Approach To Multiphase Motion. Journal of computational physics 127(1), 179–195 (1996)
Shi, J., Malik, J.: Normalized cuts and image segmentation. IEEE TPAMI 22(8), 888–905 (2000)
Yan, P., Shen, W., Kassim, A., Shah, M.: Segmentation of neighboring organs in medical image with model competition. In: Duncan, J.S., Gerig, G. (eds.) MICCAI 2005. LNCS, vol. 3749, pp. 270–277. Springer, Heidelberg (2005)
Yang, J., Staib, L., Duncan, J.: Neighbor-constrained segmentation with level set based 3-D deformable models. IEEE TMI 23(8), 940 (2004)
Palmer, S.: Vision science: Photons to phenomenology. MIT Press, Cambridge (1999)
Huber, P., Ronchetti, E.: Robust statistics. Wiley-Blackwell (2009)
Yang, Y., Tannenbaum, A., Giddens, D., Coulter, W.: Knowledge-based 3D segmentation and reconstruction of coronary arteries using CT images. In: IEEE EMBS, pp. 1664–1666 (2004)
Whitaker, R.: A level-set approach to 3D reconstruction from range data. IJCV 29(3), 231 (1998)
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2011 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Gao, Y., Tannenbaum, A., Kikinis, R. (2011). Simultaneous Multi-object Segmentation Using Local Robust Statistics and Contour Interaction. In: Menze, B., Langs, G., Tu, Z., Criminisi, A. (eds) Medical Computer Vision. Recognition Techniques and Applications in Medical Imaging. MCV 2010. Lecture Notes in Computer Science, vol 6533. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-18421-5_19
Download citation
DOI: https://doi.org/10.1007/978-3-642-18421-5_19
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-18420-8
Online ISBN: 978-3-642-18421-5
eBook Packages: Computer ScienceComputer Science (R0)