Abstract
The filtration through machine learning approaches can solves many problems in diagnosis of MRI brain. Various medical image applications are available in usage but they are offering limited solutions at diagnosis process. Therefore disease diagnosis performance is improved by proposed CNN (convolution neural networks)–GB (Gradient Boosting) and adaptive median filter (AMF) mechanism. In this work, brain-related disorders have been identified by using deep learning and machine learning technique. So brain-correlated information purpose real-time MRI medical images and “FIGSHARE”, “OASIS” datasets are collected. These are having more information of disease identification and classification. Various filters like Gaussian filter, median filters unable to remove the noise in medical images, when density of noise is more than 78% so that an advanced filters design is necessary for a fast and accurate brain disease diagnosis. In this research CNN–ML based adaptive median filter is designed for noise exclusion and effective diseases identification. PSNR, MSE, True positive rate and accuracy parameters can describe the application efficiency. MRI brain diseases investigation with CNN–AMF and GBML model has achieved 0.9863-accuracy and 0.9832-True Positive Rate, which is a better improvement. This implemented design and improved results are compete with current medical research applications, also useful for doctors, researchers and Diagnosis centers.
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References
Akar, S. A. (2016). Determination of optimal parameters for bilateral filter in brain MRimage denoising. Applied Soft Computing., 43, 87–96.
Bourne, R. (2010). Image filters. In R. Bourne (Ed.), Fundamentals of digital imaging in medicine. London: Springer.
Danaee, Soroosh, Darakeh, Fatemeh, & Mohammad-Khani, Gholam-Reza. (2018). Applying an ANFIS-based algorithm in comparison with mechanistic modelling in a biofilter treating hexane. Journal of Green Engineering, 8(3), 319–338.
Dey, N., Ashour, A. S., Beagum, S., Sifaki Pistola, D., Gospodinov, M., Gospodinova, E., et al. (2015). Parameter optimization for local polynomial approximation based intersection confidence interval filter using genetic algorithm: An application for brain MRI image denoising. Journal of Imaging., 1(1), 60–84.
Erturk, M. (2013). De-noising MRI using spectral subtraction. IEEE Transaction on Bio-Medical Engineering, 60(6), 1556–1562.
Hancer, E., Ozturk, C., & Karaboga, D. (2013). Extraction of brain tumors from MRI images with artificial bee colony based segmentation methodology. In: 8th International Conference on Electrical Engineering. pp. 516–520.
Isa, I. S., Sulaiman, S. N., Mustapha, M., & Darus, S. (2015). Evaluating de-noising performances of fundamental filters for T2-weighted MRI images. 19th International Conference on Knowledge Based and Intelligent Information and Engineering Systems. Procedia Computer Science., 60, 760–776.
JeanShilpa, V., & Jawahar, P. K. (2019). Advanced optimization by profiling of acoustics software applications for interoperability in HCF systems. Journal of Green Engineering, 9(3), 462–474.
Karthikeyan, T., Sekaran, K., Ranjith, D., & Balajee, J. M. (2019). Personalized content extraction and text classification using effective web scraping techniques. International Journal of Web Portals (IJWP), 11(2), 41–52.
Kouser, R. R., Manikandan, T., & Kumar, V. V. (2018). Heart disease prediction system using artificial neural network, radial basis function and case based reasoning. Journal of Computational and Theoretical Nanoscience, 15, 2810–2817.
Lakshmi Devasena, C., & Hemalatha, M. (2011). Noise removal in magnetic resonance images using hybrid KSL filtering technique. International Journal of Computer Applications, 27(8), 2011.
Liang, D., Cheng, J., Ke, Z., & Ying, L. (2020). Deep magnetic resonance image reconstruction: Inverse problems meet neural networks. IEEE Signal Processing Magazine, 37(1), 141–151. https://doi.org/10.1109/MSP.2019.2950557.
Lijun, B., Liu, W., Zhu, Y., Pu, Z., & Magnin, I.E. (2008). Sparse representation based MRI de-noising with total variation. In: Signal Processing, 2008. ICSP 2008. 9th International Conference on Oct. 2008; 2008. pp. 2154–2157.
Lin, L., Meng, X., & Liang, X. (2013). Reduction of impulse noise in MRI images using block-based adaptive median filter. In: Proceedings of the 2013 IEEE International Conference on Medical Imaging Physics and Engineering (ICMIPE), 19-20 Oct. 2013. pp. 132–134.
Loizou, C. P., Pantziaris, M., Pattichis, C. S., & Seimenis, I. (2012). Brain MR image normalization in texture analysis of multiple sclerosis. Journal of Biomedical Graphics and Computing, 3(1), 20–34.
Luo, S. (2001). Filtering medical image using adaptive filter. Engineering in Medicine and Biology Society, 3, 2727–2729.
Mohan, J., Krishnaveni, V., & Guo, Y. (2013). A new neutrosophic approach of Wiener filtering for MRI denoising. Measurement Science Review, 13(4), 177–186.
Patel, K., & Mewada, H. (2014). A review on different image de-noising methods. International Journal on Recent and Innovation Trends in Computing and Communication, 2(1), 155–159.
Phophalia, A., Rajwade, A., & Mitra, S. K. (2014). Rough set based image de-noising for brain MR images. Signal Processing, 2014(103), 24–35.
Rahmat, R., Malik, A. S., & Kamel, N. (2013). Comparison of LULU and median filter for image denoising. International Journal of Computer and Electrical Engineering, 5(6), 1–13.
Rajeesh, J., Moni, R. S., Palanikumar, S., & Gopalakrishnan, T. (2010). Noise reduction in magnetic resonance images using wave atom shrinkage. International Journal of Image Processing (IJIP), 4(2), 131–141.
Sivasundari, M. K. S., & Siva, Kumar R. (2014). Performance analysis of image filtering algorithms for MRI images. International Journal of Research in Engineering and Technology, 3(5), 438–440.
Ye, J. C., Han, Y., & Cha, E. (2018). Deep convolutional framelets: A general deep learning framework for inverse problems. SIAM Journal on Imaging Sciences (SIIMS), 11(2), 991–1048.
Zhang, M., & Gunturk, B. K. (2008). Multi resolution bilateral filtering for image de-noising. IEEE Transactions on Image Processing, 17(12), 2324–2333.
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Sreelakshmi, D., Inthiyaz, S. Fast and denoise feature extraction based ADMF–CNN with GBML framework for MRI brain image. Int J Speech Technol 24, 529–544 (2021). https://doi.org/10.1007/s10772-020-09793-w
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DOI: https://doi.org/10.1007/s10772-020-09793-w