Tumour feature analysis with unsupervised machine learning

Nattkemper TW, Wismüller A (2005)
Medical Image Analysis 9(4): 344-351.

Zeitschriftenaufsatz | Veröffentlicht | Englisch
 
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DOI
Autor*in
Nattkemper, Tim WilhelmUniBi ; Wismüller, Axel
Einrichtung
Technische Fakultät > AG Neuroinformatik
Abstract / Bemerkung
Dynamic contrast enhanced magnetic resonance imaging (DCE MRI) is applied for diagnosis and therapy control of breast cancer. The malignancy of a lesion is expressed in the average signal kinetics of selected regions of interest (ROI) representing the lesion. The technique is reported to characterize malignant tumors with high sensitivity and highly variable specificity. Computer-based diagnosis (CAD) systems have been proposed to analyze and classify signal time curve data, extracted from hand selected ROI in the DCE MRI data. In this paper, we apply the self-organizing map (SOM) to a set of time curve feature vectors of single voxels from seven benign lesions and seven malignant tumors. Applying the SOM we are able to project the time curve values of each voxel on a two-dimensional map. The results show, that the SOM is able to visualize the hidden two-dimensional structure of the six-dimensional signal space. Using the trained SOM, we are able to identify voxels with benign or malignant signal characteristics and to visualize lesion cross-sections with pseudo-colors. A comparison with the established three time points method shows that the SOM has clear potential for deriving visualization parameters in DCE MRI analysis.
Erscheinungsjahr
2005
Zeitschriftentitel
Medical Image Analysis
Band
9
Ausgabe
4
Seite(n)
344-351
Page URI
https://pub.uni-bielefeld.de/record/2714340

Zitieren

Nattkemper TW, Wismüller A. Tumour feature analysis with unsupervised machine learning. Medical Image Analysis. 2005;9(4):344-351.
Nattkemper, T. W., & Wismüller, A. (2005). Tumour feature analysis with unsupervised machine learning. Medical Image Analysis, 9(4), 344-351. doi:10.1016/j.media.2005.01.004
Nattkemper, Tim Wilhelm, and Wismüller, Axel. 2005. “Tumour feature analysis with unsupervised machine learning”. Medical Image Analysis 9 (4): 344-351.
Nattkemper, T. W., and Wismüller, A. (2005). Tumour feature analysis with unsupervised machine learning. Medical Image Analysis 9, 344-351.
Nattkemper, T.W., & Wismüller, A., 2005. Tumour feature analysis with unsupervised machine learning. Medical Image Analysis, 9(4), p 344-351.
T.W. Nattkemper and A. Wismüller, “Tumour feature analysis with unsupervised machine learning”, Medical Image Analysis, vol. 9, 2005, pp. 344-351.
Nattkemper, T.W., Wismüller, A.: Tumour feature analysis with unsupervised machine learning. Medical Image Analysis. 9, 344-351 (2005).
Nattkemper, Tim Wilhelm, and Wismüller, Axel. “Tumour feature analysis with unsupervised machine learning”. Medical Image Analysis 9.4 (2005): 344-351.

9 Zitationen in Europe PMC

Daten bereitgestellt von Europe PubMed Central.

Computer-aided interpretation approach for optical tomographic images.
Klose CD, Klose AD, Netz UJ, Scheel AK, Beuthan J, Hielscher AH., J Biomed Opt 15(6), 2010
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Kelm BM, Menze BH, Nix O, Zechmann CM, Hamprecht FA., IEEE Trans Med Imaging 28(10), 2009
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Classification of dynamic contrast-enhanced magnetic resonance breast lesions by support vector machines.
Levman J, Leung T, Causer P, Plewes D, Martel AL., IEEE Trans Med Imaging 27(5), 2008
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Vijayakumar C, Damayanti G, Pant R, Sreedhar CM., Comput Med Imaging Graph 31(7), 2007
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Interactive visual analysis of perfusion data.
Oeltze S, Doleisch H, Hauser H, Muigg P, Preim B., IEEE Trans Vis Comput Graph 13(6), 2007
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