A deep learning framework with an embedded-based feature selection approach for the early detection of the Alzheimer's disease

A deep learning framework with an embedded-based feature selection approach for the early detection of the Alzheimer's disease

Ageing is associated with various ailments including Alzheimer ’s disease (AD), which is a progressive form of dementia. AD symptoms develop over a period of years and, unfortunately, there is no cure. Existing AD treatments can only slow down the progression of symptoms and thus it is critical to d...

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Veröffentlicht in:Computers in biology and medicine 2022-02, Vol.141, p.105056-105056, Article 105056
Hauptverfasser: Mahendran, Nivedhitha, P M, Durai Raj Vincent
Format: Artikel
Sprache:eng
Schlagworte:
Aging
Alzheimer Disease - diagnosis
Alzheimer's disease
Artificial intelligence
Artificial neural networks
Biomarkers
Classification
CpG islands
Datasets
Deep Learning
Dementia disorders
DNA Methylation
Early Diagnosis
Embedded feature selection
Gene expression
Humans
Machine learning
Magnetic Resonance Imaging - methods
Neural networks
Neural Networks, Computer
Neurodegenerative diseases
Quality control
Recurrent neural networks
Signs and symptoms
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P M, Durai Raj Vincent
description Ageing is associated with various ailments including Alzheimer ’s disease (AD), which is a progressive form of dementia. AD symptoms develop over a period of years and, unfortunately, there is no cure. Existing AD treatments can only slow down the progression of symptoms and thus it is critical to diagnose the disease at an early stage. To help improve the early diagnosis of AD, a deep learning-based classification model with an embedded feature selection approach was used to classify AD patients. An AD DNA methylation data set (64 records with 34 cases and 34 controls) from the GEO omnibus database was used for the analysis. Before selecting the relevant features, the data were preprocessed by performing quality control, normalization and downstream analysis. As the number of associated CpG sites was huge, four embedded-based feature selection models were compared and the best method was used for the proposed classification model. An Enhanced Deep Recurrent Neural Network (EDRNN) was implemented and compared to other existing classification models, including a Convolutional Neural Network (CNN), a Recurrent Neural Network (RNN), and a Deep Recurrent Neural Network (DRNN). The results showed a significant improvement in the classification accuracy of the proposed model as compared to the other methods. •DRNN based model for detecting Alzheimer’s disease by selecting the gene subset from DNA Methylation dataset.•The dataset is preprocessed through quality control, normalization and downstream analysis.•Implemented two tree based and regression based embedded feature selection to find the best feature set.•We present the DRNN with an improvement for fast convergence with Bayesian Optimization to tune hyperparameters.
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AD symptoms develop over a period of years and, unfortunately, there is no cure. Existing AD treatments can only slow down the progression of symptoms and thus it is critical to diagnose the disease at an early stage. To help improve the early diagnosis of AD, a deep learning-based classification model with an embedded feature selection approach was used to classify AD patients. An AD DNA methylation data set (64 records with 34 cases and 34 controls) from the GEO omnibus database was used for the analysis. Before selecting the relevant features, the data were preprocessed by performing quality control, normalization and downstream analysis. As the number of associated CpG sites was huge, four embedded-based feature selection models were compared and the best method was used for the proposed classification model. An Enhanced Deep Recurrent Neural Network (EDRNN) was implemented and compared to other existing classification models, including a Convolutional Neural Network (CNN), a Recurrent Neural Network (RNN), and a Deep Recurrent Neural Network (DRNN). 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subjects Aging
Alzheimer Disease - diagnosis
Alzheimer's disease
Artificial intelligence
Artificial neural networks
Biomarkers
Classification
CpG islands
Datasets
Deep Learning
Dementia disorders
DNA Methylation
Early Diagnosis
Embedded feature selection
Gene expression
Humans
Machine learning
Magnetic Resonance Imaging - methods
Neural networks
Neural Networks, Computer
Neurodegenerative diseases
Quality control
Recurrent neural networks
Signs and symptoms
title A deep learning framework with an embedded-based feature selection approach for the early detection of the Alzheimer's disease
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