Primary central nervous system lymphoma and glioblastoma image differentiation based on sparse representation system_Journal of Biomedical Engineering

Authors：

WU Guoqing ¹ , LI Zeju ¹ ,  WANG Yuanyuan ¹ , YU Jinhua ¹ , CHEN Yinsheng ² , CHEN Zhongping ²

1. Department of Electronic Engineering, Fudan University, Shanghai 200433, P.R.China;
2. Department of Neurosurgery, Sun Yat-sen University Cancer Center, Guangzhou 510000, P.R.China;

Corresponding author：

WANG Yuanyuan, Email: yywang@fudan.edu.cn

Keywords：

tumor image differentiation; sparse representation; feature extraction; feature selection

DOI：

10.7507/1001-5515.201705061

Video：

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Abstract Full text Figures/Tables Video References Cited by

It is of great clinical significance in the differential diagnosis of primary central nervous system lymphoma (PCNSL) and glioblastoma (GBM) because there are enormous differences between them in terms of therapeutic regimens. In this paper, we propose a system based on sparse representation for automatic classification of PCNSL and GBM. The proposed system distinguishes the two tumors by using of the different texture detail information of the two tumors on T1 contrast magnetic resonance imaging (MRI) images. First, inspired by the process of radiomics, we designed a dictionary learning and sparse representation-based method to extract texture information, and with this approach, the tumors with different volume and shape were transformed into 968 quantitative texture features. Next, aiming at the problem of the redundancy in the extracted features, feature selection based on iterative sparse representation was set up to select some key texture features with high stability and discrimination. Finally, the selected key features are used for differentiation based on sparse representation classification (SRC) method. By using ten-fold cross-validation method, the differentiation based on the proposed approach presents accuracy of 96.36%, sensitivity 96.30%, and specificity 96.43%. Experimental results show that our approach not only effectively distinguish the two tumors but also has strong robustness in practical application since it avoids the process of parameter extraction on advanced MRI images.

Citation： WU Guoqing, LI Zeju, WANG Yuanyuan, YU Jinhua, CHEN Yinsheng, CHEN Zhongping. Primary central nervous system lymphoma and glioblastoma image differentiation based on sparse representation system. Journal of Biomedical Engineering, 2018, 35(5): 754-760. doi: 10.7507/1001-5515.201705061 Copy

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2.	Toh C H, Castillo M, Wong A M, et al. Primary cerebral lymphoma and glioblastoma multiforme: differences in diffusion characteristics evaluated with diffusion tensor imaging. AJNR Am J Neuroradiol, 2008, 29(3): 471-475.
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5.	Kickingereder P, Wiestler B, Sahm F, et al. Primary central nervous system lymphoma and atypical glioblastoma: multiparametric differentiation by using diffusion-, perfusion-, and susceptibility-weighted MR imaging. Radiology, 2014, 272(3): 843-850.
6.	Ahn S J, Shin H J, Chang J H, et al. Differentiation between primary cerebral lymphoma and glioblastoma using the apparent diffusion coefficient: comparison of three different ROI methods. PLoS One, 2014, 9(11): e112948.
7.	Nakajima S, Okada T, Yamamoto A, et al. Differentiation between primary central nervous system lymphoma and glioblastoma: a comparative study of parameters derived from dynamic susceptibility contrast-enhanced perfusion-weighted MRI. Clin Radiol, 2015, 70(12): 1393-1399.
8.	Gillies R J, Kinahan P E, Hricak H. Radiomics: images are more than pictures, they are data. Radiology, 2016, 278(2): 563-577.
9.	Aerts H J, Velazquez E R, Leijenaar R T, et al. Decoding tumour phenotype by noninvasive imaging using a quantitative radiomics approach. Nat Commun, 2014, 5: 4006.
10.	Yu J, Shi Z, Lian Y, et al. Noninvasive IDH₁ mutation estimation based on a quantitative radiomics approach for grade Ⅱ glioma. Eur Radiol, 2017, 27(8): 3509-3522.
11.	Wu Weimiao, Parmar C, Grossmann P, et al. Exploratory study to identify radiomics classifiers for lung cancer histology. Front Oncol, 2016, 6(Suppl 2): 71.
12.	Elad M, Aharon M. Image denoising via sparse and redundant representations over learned dictionaries. IEEE Trans Image Process, 2006, 15(12): 3736-3745.
13.	Wright J, Yang A Y, Ganesh A, et al. Robust face recognition via sparse representation. IEEE Trans Pattern Anal Mach Intell, 2009, 31(2): 210-227.
14.	Li Yuanqing, Namburi P, Yu Zhuliang, et al. Voxel selection in fMRI data analysis based on sparse representation. IEEE Trans Biomed Eng, 2009, 56(10): 2439-2451.
15.	Pereira S, Pinto A, Alves V, et al. Brain tumor segmentation using convolutional neural networks in MRI images. IEEE Trans Med Imaging, 2016, 35(5): 1240-1251.
16.	Nouretdinov I, Costafreda S G, Gammerman A, et al. Machine learning classification with confidence: application of transductive conformal predictors to MRI-based diagnostic and prognostic markers in depression. Neuroimage, 2011, 56(2): 809-813.
17.	Choi Y S, Lee H J, Ahn S S, et al. Primary central nervous system lymphoma and atypical glioblastoma: differentiation using the initial area under the curve derived from dynamic contrast-enhanced MR and the apparent diffusion coefficient. Eur Radiol, 2017, 27(4): 1344-1351.

1. Haldorsen I S, Espeland A, Larsson E M. Central nervous system lymphoma: characteristic findings on traditional and advanced imaging. AJNR Am J Neuroradiol, 2011, 32(6): 984-992.
2. Toh C H, Castillo M, Wong A M, et al. Primary cerebral lymphoma and glioblastoma multiforme: differences in diffusion characteristics evaluated with diffusion tensor imaging. AJNR Am J Neuroradiol, 2008, 29(3): 471-475.
3. Al-Okaili R N, Krejza J, Woo J H, et al. Intraaxial brain masses: MR imaging-based diagnostic strategy--initial experience. Radiology, 2007, 243(2): 539-550.
4. Xing Z, You R X, Li J, et al. Differentiation of primary central nervous system lymphomas from high-grade gliomas by rCBV and percentage of signal intensity recovery derived from dynamic susceptibility-weighted contrast-enhanced perfusion MR imaging. Clin Neuroradiol, 2014, 24(4): 329-336.
5. Kickingereder P, Wiestler B, Sahm F, et al. Primary central nervous system lymphoma and atypical glioblastoma: multiparametric differentiation by using diffusion-, perfusion-, and susceptibility-weighted MR imaging. Radiology, 2014, 272(3): 843-850.
6. Ahn S J, Shin H J, Chang J H, et al. Differentiation between primary cerebral lymphoma and glioblastoma using the apparent diffusion coefficient: comparison of three different ROI methods. PLoS One, 2014, 9(11): e112948.
7. Nakajima S, Okada T, Yamamoto A, et al. Differentiation between primary central nervous system lymphoma and glioblastoma: a comparative study of parameters derived from dynamic susceptibility contrast-enhanced perfusion-weighted MRI. Clin Radiol, 2015, 70(12): 1393-1399.
8. Gillies R J, Kinahan P E, Hricak H. Radiomics: images are more than pictures, they are data. Radiology, 2016, 278(2): 563-577.
9. Aerts H J, Velazquez E R, Leijenaar R T, et al. Decoding tumour phenotype by noninvasive imaging using a quantitative radiomics approach. Nat Commun, 2014, 5: 4006.
10. Yu J, Shi Z, Lian Y, et al. Noninvasive IDH₁ mutation estimation based on a quantitative radiomics approach for grade Ⅱ glioma. Eur Radiol, 2017, 27(8): 3509-3522.
11. Wu Weimiao, Parmar C, Grossmann P, et al. Exploratory study to identify radiomics classifiers for lung cancer histology. Front Oncol, 2016, 6(Suppl 2): 71.
12. Elad M, Aharon M. Image denoising via sparse and redundant representations over learned dictionaries. IEEE Trans Image Process, 2006, 15(12): 3736-3745.
13. Wright J, Yang A Y, Ganesh A, et al. Robust face recognition via sparse representation. IEEE Trans Pattern Anal Mach Intell, 2009, 31(2): 210-227.
14. Li Yuanqing, Namburi P, Yu Zhuliang, et al. Voxel selection in fMRI data analysis based on sparse representation. IEEE Trans Biomed Eng, 2009, 56(10): 2439-2451.
15. Pereira S, Pinto A, Alves V, et al. Brain tumor segmentation using convolutional neural networks in MRI images. IEEE Trans Med Imaging, 2016, 35(5): 1240-1251.
16. Nouretdinov I, Costafreda S G, Gammerman A, et al. Machine learning classification with confidence: application of transductive conformal predictors to MRI-based diagnostic and prognostic markers in depression. Neuroimage, 2011, 56(2): 809-813.
17. Choi Y S, Lee H J, Ahn S S, et al. Primary central nervous system lymphoma and atypical glioblastoma: differentiation using the initial area under the curve derived from dynamic contrast-enhanced MR and the apparent diffusion coefficient. Eur Radiol, 2017, 27(4): 1344-1351.

Journal of Biomedical Engineering

Primary central nervous system lymphoma and glioblastoma image differentiation based on sparse representation system

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