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Abstract

Background:

Degradation of magnetic resonance imaging (MRI) remains a challenging issue, with noise being a key damaging component introduced due to a variety of environmental and mechanical factors.

Objective:

The aim of this research work is to addresses the issue of noise reduction and to predict Alzheimer's disease detection efficiently.

Methods:

First, we present a genetic programming (GP) technique for reducing Rician noise in MRI images to pre-process the dataset. To effectively reduce Rician noise, this GP approach combines a Feature Extraction component, GP Optimal Expression, and an Optimum Removal Estimation component. In the second phase, we design and develop an explainable Deep Learning framework. This framework uses a local data-driven interpretation technique based on SHAP values to investigate the relationship between the neural network's estimated AD diagnosis and the input MRI images. In addition, we handle class distribution by combining an oversampling strategy with a minority approach. Several assessment metrics are used to analyze the performance of our proposed model.

Results:

The proposed method is tested on a variety of medical samples, and the results are compared to those obtained using other comparable approaches. We also test and compare our model to three cutting-edge models: DenseNet169, VGGNet15, and Inceptionv3.

Conclusions:

The empirical results show that our proposed model outperforms others, particularly in handling basic structures with limited spectral features, lower computational complexity, and less overfitting. This research worked addressed Rician noise issue in MRI images and predict AD severity prediction using explainable deep learning framework.

Keywords

Alzheimer's disease classification explainable deep learning genetic programming transfer learning

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References

Khan

Ullah

Ahmed

, et al. MRI Images enhancement using genetic programming-based hybrid noise removal filter approach. Curr Med Imaging 2018; 14: 867–873.

Khan

Ullah

Ahmed

, et al. MRI Imaging, comparison of MRI with other modalities, noise in MRI images and machine learning techniques for noise removal: a review. Curr Med Imaging 2019; 15: 243–254.

Tajbakhsh

Shin

Gurudu

, et al.

Convolutional neural networks for medical image analysis: full training or fine tuning?

IEEE Trans Med Imaging 2016; 35: 1299–1312.

Khan

Ullah

Wang

. A novel algorithm for poisson noise removal from medical x-ray images. Int J Comput Sci Inf Security 2016; 14: 103–109.

Khan

Wang

Chai

, et al. X-ray image enhancement using boundary division wiener filters and wavelet-based image fusion approach. J Inf Processing Systems 2016; 12: 35–45.

Khan

Ullah

, et al. Multimodal medical image fusion in NSST domain with structural and spectral features enhancement. Heliyon 2023; 9: e17334.

Khan

Ullah

, et al. A novel CT image de-noising and fusion based deep learning network to screen for disease (COVID-19). Sci Rep 2023; 13: 6601.

Shashank

. A guide to an efficient way to build neural network architectures- Part II: Hyper-parameter selection and tuning for Convolutional Neural Networks using Hyperas on Fashion-MNIST, https://towardsdatascience.com/a-guide-to-an-efficient-way-to-build-neural-network-architectures-part-ii-hyper-parameter-42efca01e5d7 (2018, accessed 12 August 2023).

AlNasim

AlMunem

Islam

, et al. Brain tumor segmentation using enhanced u-net model with empirical analysis. In 2022 25th International Conference on Computer and Information Technology (ICCIT), 2022, pp.1027-1032).

10.

Cybenko

. Approximation by superpositions of a sigmoidal function. Math Control Signal Syst 1989; 2: 303–314.

11.

Wookey

. The real-world-weight cross-entropy loss function: modeling the costs of mislabeling. IEEE Access 2020; 8: 4806–4813.

12.

Song

Sun

, et al. A novel brain tumor segmentation from multi-modality MRI via a level-set-based model. J Signal Process Syst 2017; 87: 249–257.

13.

Bilal

Barani

Sabir

, et al. Nanomaterials for the treatment and diagnosis of Alzheimer's disease: an overview. Nanoimpact 2020; 20: 100251.

14.

Al-Khuzaie

Bayat

Duru

. Diagnosis of Alzheimer disease using 2D MRI slices by convolutional neural network. Appl Bionics Biomech 2021; 2021: 6690539. [retracted in: Appl Bionics Biomech 2023;2023: 9762945].

15.

Al-Adhaileh

. Diagnosis and classification of Alzheimer's disease by using a convolution neural network algorithm. Soft Comput 2022; 26: 7751–7762.

16.

Liu

Luo

, et al. Alzheimer's disease detection using depthwise separable convolutional neural networks. Comput Methods Programs Biomed 2021; 203: 106032.

17.

Savaş

. Detecting the stages of Alzheimer’s disease with pre-trained deep learning architectures. Arab J Sci Eng 2022; 47: 2201–2218.

18.

Lee

Ellahi

Choi

. Using deep CNN with data permutation scheme for classification of Alzheimer's disease in structural magnetic resonance imaging (sMRI). IEICE Trans Inf Syst 2019; 102: 1384–1395.

19.

Helaly

Mahmoud

Amira

. Deep learning approach for early detection of Alzheimer’s disease. Cogn Comput 2022; 14: 1711–1727.

20.

Zanzoni

Montecchi-Palazzi

Quondam

, et al. MINT: a molecular INTeraction database. FEBS Lett 2002; 513: 135–140.

21.

Swingler

. Applying neural networks: a practical guide. Burlington: Morgan Kaufmann, 1996.

22.

Chawla

Bowyer

Hall

, et al. SMOTE: synthetic minority over-sampling technique. J Artif Intell Res 2002; 16: 321–357.

23.

Amin

Sharif

Raza

, et al. Brain tumor detection using statistical and machine learning method. Comput Methods Programs Biomed 2019; 177: 69–79.

24.

Jain

Aggarwal

, et al. Convolutional neural network based Alzheimer’s disease classification from magnetic resonance brain images. Cogn Syst Res 2019; 57: 147–159.

A genetic programming Rician noise reduction and explainable deep learning model for Alzheimer's diseases severity prediction

Abstract

Background:

Objective:

Methods:

Results:

Conclusions:

Keywords

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References