Low and high grade glioma segmentation in multispectral brain MRI data-Reference-Cited by-同舟云学术

Low and high grade glioma segmentation in multispectral brain MRI data

Published:2018-08-01 Issue:1 Volume:10 Page:110-132
ISSN:2066-7760
Container-title:Acta Universitatis Sapientiae, Informatica
language:en
Short-container-title:

Author:

Szilágyi László¹,Iclănzan David¹,Kapás Zoltán¹,Szabó Zsófia¹,Győrfi Ágnes¹,Lefkovits László¹

Affiliation:

1. Sapientia University , Târgu Mureş , Romania

Abstract

Abstract Several hundreds of thousand humans are diagnosed with brain cancer every year, and the majority dies within the next two years. The chances of survival could be easiest improved by early diagnosis. This is why there is a strong need for reliable algorithms that can detect the presence of gliomas in their early stage. While an automatic tumor detection algorithm can support a mass screening system, the precise segmentation of the tumor can assist medical staff at therapy planning and patient monitoring. This paper presents a random forest based procedure trained to segment gliomas in multispectral volumetric MRI records. Beside the four observed features, the proposed solution uses 100 further features extracted via morphological operations and Gabor wavelet filtering. A neighborhood-based post-processing was designed to regularize and improve the output of the classifier. The proposed algorithm was trained and tested separately with the 54 low-grade and 220 high-grade tumor volumes of the MICCAI BRATS 2016 training database. For both data sets, the achieved accuracy is characterized by an overall mean Dice score > 83%, sensitivity > 85%, and specificity > 98%. The proposed method is likely to detect all gliomas larger than 10 mL.

Publisher

Walter de Gruyter GmbH

Link

https://www.sciendo.com/pdf/10.2478/ausi-2018-0007

Reference29 articles.

1. [1] S. B. Akers, Binary decision diagrams, IEEE Trans. ComputersC-27, 6 (1978) 509–516. ⇒ 11510.1109/TC.1978.1675141

2. [2] A. J. Asman, B. A. Landman, Out-of-atlas labeling: a multi-atlas approach to cancer segmentation, Proc. IEEE International Symposium on Biomedical Imaging, Barcelona, Catalunya, 2012, pp. 1236–1239. ⇒ 11110.1109/ISBI.2012.6235785

3. [3] L. Breiman, Random forests, Machine Learning45, 1 (2001) 5–32. ⇒ 11710.1023/A:1010933404324

4. [4] J. D. Christensen, Normalization of brain magnetic resonance images using histogram even-order derivative analysis, Magn. Reson. Imaging21, 7 (2003) 817–820. ⇒ 11410.1016/S0730-725X(03)00102-4

5. [5] S. Ghanavati, J. Li, T. Liu, P. S. Babyn, W. Doda, G. Lampropoulos, Automatic brain tumor detection in magnetic resonance images, Proc. IEEE International Symposium on Biomedical Imaging, Barcelona, Catalunya, 2012, pp. 574–577. ⇒ 11110.1109/ISBI.2012.6235613

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