Sage Journals: Discover world-class research

Abstract

BACKGROUND:

The noise in magnetic resonance (MR) images causes severe issues for medical diagnosis purposes.

OBJECTIVE:

In this paper, we propose a discriminative learning based convolutional neural network denoiser to denoise the MR image data contaminated with noise.

METHODS:

The proposed method incorporates the use of depthwise separable convolution along with local response normalization with modified hyperparameters and internal skip connections to denoise the contaminated MR images. Moreover, the addition of parametric RELU instead of normal conventional RELU in our proposed architecture gives more stable and fine results. The denoised images were further segmented to test the appropriateness of the results. The network is trained on one dataset and tested on other dataset produces remarkably good results.

RESULTS:

Our proposed network was used to denoise the images of different noise levels, and it yields better performance as compared with various networks. The SSIM and PSNR showed an average improvement of (7.2 $\pm$ 0.002) % and (8.5 $\pm$ 0.25) % respectively when tested on different datasets without retaining the network. An improvement of 5% and 6% was achieved in the values of mean intersection over union (mIoU) and BF score when the denoised images were segmented for testing the relevancy in biomedical imaging applications. The statistical test suggests that the obtained results are statistically significant as $p<$ 0.05.

CONCLUSION:

The denoised images obtained are more clinically suitable for medical image diagnosis purposes, as depicted by the evaluation parameters. Further, external clinical validation was performed by an experienced radiologist for testing the validation of the resulting images.

Keywords

Deep learning image denoising depthwise separable convolution local response normalization skip connections convolutional neural network

Get full access to this article

View all access options for this article.

References

Kaur

Singh

Kaur

. A review of denoising medical images using machine learning approaches. CMIR. 2018; 14: 675-85.

Gondara

. Medical image denoising using convolutional denoising autoencoders. 2016 IEEE 16th International Conference on Data Mining Workshops (ICDMW). 2016; 241-6.

Zhang

Zuo

Zhang

. Learning Deep CNN Denoiser Prior for Image Restoration. arXiv: 170403264 [cs] [Internet]. 2017 [cited 2020 Nov 5]; Available from: http://arxiv.org/abs/1704.03264.

Gudbjartsson

Patz

. The rician distribution of noisy mri data. Magn Reson Med. 1995; 34: 910-4.

Pereza

Concib

Belen Morenoc

Andaluza

Hernandezd

. Estimating the Rician noise level in brain MR image. 2014 IEEE ANDESCON [Internet]. Cochabamba, Bolivia: IEEE; 2014 [cited 2019 Oct 18]. 1-1. Available from: http://ieeexplore.ieee.org/document/7098539/.

Maximov

Farrher

Grinberg

JonShah

. Spatially variable Rician noise in magnetic resonance imaging. Medical Image Analysis. 2012; 16: 536-48.

Buades

Coll

Morel

J-M

. A Non-Local Algorithm for Image Denoising. 2005 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (CVPR’05) [Internet]. San Diego, CA, USA: IEEE; 2005 [cited 2019 Sep 24]. pp. 60-5. Available from: http://ieeexploreieee.org/document/1467423/.

Manjón

Coupé

Martí-Bonmatí

Collins

Robles

. Adaptive non-local means denoising of MR images with spatially varying noise levels: Spatially Adaptive Nonlocal Denoising. J Magn Reson Imaging. 2010; 31: 192-203.

Golshan

Hasanzadeh

RPR

. An optimized LMMSE based method for 3D MRI denoising. IEEE/ACM Trans Comput Biol and Bioinf. 2015; 12: 861-70.

10.

Baselice

Ferraioli

Pascazio

. A 3D MRI denoising algorithm based on Bayesian theory. BioMed Eng OnLine. 2017; 16: 25.

11.

Chang

Y-N

Chang

H-H

. Automatic brain MR image denoising based on texture feature-based artificial neural networks. Liu F, Lee D-H, Lagoa R, Kumar S, editors. BME. 2015; 26: S1275-82.

12.

Martin-Fernandez

Villullas

. The EM method in a probabilistic wavelet-based MRI denoising. Comput Math Methods Med. 2015; 2015: 182659.

13.

Yang

Sun

. BM3D-net: a convolutional neural network for transform-domain collaborative filtering. IEEE Signal Process Lett. 2018; 25: 55-9.

14.

Zhang

Zuo

Chen

Meng

Zhang

. Beyond a gaussian denoiser: residual learning of deep CNN for image denoising. IEEE Trans on Image Process. 2017; 26: 3142-55.

15.

Lin

. A nonlocal means based adaptive denoising framework for mixed image noise removal. 2013 IEEE International Conference on Image Processing. 2013. pp. 454-8.

16.

Zhang

Zuo

Feng

. Weighted Nuclear Norm Minimization with Application to Image Denoising. 2014 IEEE Conference on Computer Vision and Pattern Recognition [Internet]. Columbus, OH, USA: IEEE; 2014 [cited 2019 Sep 23]. pp. 2862-9. Available from: http://ieeexploreieee.org/lpdocs/epic03/wrapper.htm?arnumber=6909762.

17.

Tran

Jiang

. Automated background segmentation for Rician noise estimation of noisy MR images. 2012 Cairo International Biomedical Engineering Conference (CIBEC) [Internet]. Giza, Egypt: IEEE; 2012 [cited 2019 Sep 24]. pp. 150-3. Available from: http://ieeexploreieee.org/document/6473333/.

18.

Landman

Bazin

P-L

Prince

. Diffusion Tensor Estimation by Maximizing Rician Likelihood. 2007 IEEE 11th International Conference on Computer Vision [Internet]. Rio de Janeiro, Brazil: IEEE; 2007 [cited 2019 Sep 24]. pp. 1-8. Available from: http://ieeexploreieee.org/document/4409140/.

19.

Simonyan

Zisserman

. Very Deep Convolutional Networks for Large-Scale Image Recognition. arXiv: 14091556 [cs] [Internet]. 2014 [cited 2019 Sep 23]; Available from: http://arxiv.org/abs/1409.1556.

20.

Mohajerin

Waslander

. Modular deep Recurrent Neural Network: Application to quadrotors. 2014 IEEE International Conference on Systems, Man, and Cybernetics (SMC) [Internet]. San Diego, CA, USA: IEEE; 2014 [cited 2019 Sep 24]. pp. 1374-9. Available from: http://ieeexploreieee.org/lpdocs/epic03/wrapper.htm?arnumber=6974106.

21.

Szegedy

Liu

Jia

Sermanet

Reed

Anguelov

, et al. Going deeper with convolutions. 2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR) [Internet]. Boston, MA, USA: IEEE; 2015 [cited 2019 Sep 23]. pp. 1-9. Available from: http://ieeexploreieee.org/document/7298594/.

22.

Krizhevsky

Sutskever

Hinton

. ImageNet classification with deep convolutional neural networks. Commun ACM. 2017; 60: 84-90.

23.

Kiros

Hinton

. Layer Normalization. arXiv: 160706450 [cs, stat] [Internet]. 2016 [cited 2019 Sep 23]; Available from: http://arxiv.org/abs/1607.06450.

24.

Vydana

Vuppala

. Investigative study of various activation functions for speech recognition. 2017 Twenty-third National Conference on Communications (NCC) [Internet]. Chennai, India: IEEE; 2017 [cited 2019 Sep 24]. pp. 1-5. Available from: http://ieeexploreieee.org/document/8077043/.

25.

Chang

Xie

Ding

Wen

, et al. Fine-grained vehicle classification with channel max pooling modified CNNs. IEEE Transactions on Vehicular Technology. 2019; 68: 3224-33.

26.

Zhang

Zhu

Liu

. Depth-wise separable convolutions and multi-level pooling for an efficient spatial CNN-based steganalysis. IEEE TransInformForensic Secur. 2020; 15: 1138-50.

27.

Albawi

Mohammed

Al-Zawi

. Understanding of a convolutional neural network. 2017 International Conference on Engineering and Technology (ICET) [Internet]. Antalya: IEEE; 2017 [cited 2021 Feb 6]. pp. 1-6. Available from: https://ieeexploreieee.org/document/8308186/.

28.

Lauer

. Error Bounds for Piecewise Smooth and Switching Regression. arXiv: 170707938 [cs, stat] [Internet]. 2017 [cited 2019 Sep 24]; Available from: http://arxiv.org/abs/1707.07938.

29.

Aqeel Anwar. Difference between Local Response Normalization and Batch Normalization [Internet]. Available from: https://towardsdatascience.com/difference-between-local-response-normalization-and-batch-normalization-272308c034ac.

30.

Vijendra Singh. AlexNet overview [Internet]. Available from: https://medium.com/@vijendra1125/alexnet-overview-75880645b14c.

31.

Aganj

Harisinghani

Weissleder

Fischl

. Unsupervised medical image segmentation based on the local center of mass. Sci Rep. 2018; 8: 13012.

32.

Aksam Iftikhar

Jalil

Rathore

Hussain

. Robust brain MRI denoising and segmentation using enhanced non-local means algorithm. Int J Imaging Syst Technol. 2014; 24: 52-66.

33.

Thakkar

Tewary

Chakraborty

. Batch Normalization in Convolutional Neural Networks – A comparative study with CIFAR-10 data. 2018 Fifth International Conference on Emerging Applications of Information Technology (EAIT). 2018. pp. 1-5.

34.

Yang

Peng

Zhou

. Global denoising for 3D MRI. BioMed Eng OnLine. 2016; 15: 54.

35.

Zhang

Jia

Yang

Feng

Chen

, et al. Denoising of 3D magnetic resonance images by using higher-order singular value decomposition. Medical Image Analysis. 2015; 19: 75-86.

36.

Manjón

Coupé

Buades

Louis Collins

Robles

. New methods for MRI denoising based on sparseness and self-similarity. Medical Image Analysis. 2012; 16: 18-27.

37.

Everingham

Eslami

SMA

Van Gool

Williams

CKI

Winn

Zisserman

. The pascal visual object classes challenge: a retrospective. Int J Comput Vis. 2015; 111: 98-136.

38.

Martin

Fowlkes

Malik

. Learning to detect natural image boundaries using local brightness, color, and texture cues. IEEE Trans Pattern Anal Machine Intell. 2004; 26: 530-49.

39.

Pereira

Afonso

Medeiros

. Overview of friedman’s test and post-hoc analysis. Communications in Statistics – Simulation and Computation. 2015; 44: 2636-53.

40.

Jurečková

Kalina

. Nonparametric multivariate rank tests and their unbiasedness. Bernoulli. 2012; 18: 229-51.

41.

Leo

. Statistical significance:

p

value, 0.05 threshold, and applications to radiomics – reasons for a conservative approach. 2020; 8.

42.

Tian

Fei

Yan

. Deep Learning for Image Denoising: A Survey. arXiv: 181005052 [cs] [Internet]. 2018 [cited 2021 Feb 6]; Available from: http://arxiv.org/abs/1810.05052.

43.

Bengio

Simard

Frasconi

. Learning long-term dependencies with gradient descent is difficult. IEEE Trans Neural Netw. 1994; 5: 157-66.

44.

Nwankpa

Ijomah

Gachagan

Marshall

. Activation Functions: Comparison of trends in Practice and Research for Deep Learning. arXiv: 181103378 [cs] [Internet]. 2018 [cited 2021 Feb 6]; Available from: http://arxiv.org/abs/1811.03378.

45.

Shin

Karniadakis

. Dying ReLU and initialization: theory and numerical examples. CiCP. 2020; 28: 1671-706.

46.

Tan

Xiao

Lai

Liu

Zhang

. Pixelwise estimation of signal-dependent image noise using deep residual learning. Computational Intelligence and Neuroscience. 2019; 2019: 1-12.

47.

C-H

Chang

H-H

. Superpixel-based image noise variance estimation with local statistical assessment. J Image Video Proc. 2015; 2015: 38.

48.

Sara

Akter

Uddin

. Image quality assessment through FSIM, SSIM, MSE and PSNR – a comparative study. JCC. 2019; 07: 8-18.

49.

Gopal

Sim

. Performance Analysis of Signal-to-Noise Ratio Estimators in AWGN and Fading Channels. 2008 6th National Conference on Telecommunication Technologies and 2008 2nd Malaysia Conference on Photonics [Internet]. Putrajaya, Malaysia: IEEE; 2008 [cited 2021 Feb 6]. pp. 300-4. Available from: http://ieeexploreieee.org/document/4814291/.

50.

Tang

Zhang

. A note on error bars as a graphical representation of the variability of data in biomedical research: choosing between standard deviation and standard error of the mean. Journal of Pancreatology. 2019; 2: 69-71.

51.

Kim

Arsalan

Owais

Park

. ESSN: enhanced semantic segmentation network by residual concatenation of feature maps. IEEE Access. 2020; 8: 21363-79.

52.

Zaitoun

Aqel

. Survey on image segmentation techniques. Procedia Computer Science. 2015; 65: 797-806.

53.

Concato

Hartigan

. P values: from suggestion to superstition. J Investig Med. 2016; 64: 1166-71.

Denoising of magnetic resonance images using discriminative learning-based deep convolutional neural network

Abstract

BACKGROUND:

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSION:

Keywords

Get full access to this article

References