Deep neural network model for enhancing disease prediction using auto encoder based broad learning

Deep neural network model for enhancing disease prediction using auto encoder based broad learning

Bioinformatics and Healthcare Integration Disease prediction models have been revolutionized by Big Data. These models, which make use of extensive medical data, predict illnesses before symptoms appear. Deep neural networks are well-known for their ability to increase accuracy by extending the netw...

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Bibliographic Details
Published in:SLAS technology Vol. 29; no. 3; p. 100145
Main Authors: Byeon, Haewon, GC, Prashant, Hannan, Shaikh Abdul, Alghayadh, Faisal Yousef, Soomar, Arsalan Muhammad, Soni, Mukesh, Bhatt, Mohammed Wasim
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-06-2024
Elsevier
Subjects:
Computational Biology - methods
Deep Learning
Humans
Neural Networks, Computer
Online Access:Get full text
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Summary:Bioinformatics and Healthcare Integration Disease prediction models have been revolutionized by Big Data. These models, which make use of extensive medical data, predict illnesses before symptoms appear. Deep neural networks are well-known for their ability to increase accuracy by extending the network's depth and modifying weights through gradient descent. Traditional approaches, however, are hindered by issues such as gradient instability and delayed training. As a substitute, the Broad Learning (BL) system is introduced, which avoids gradient descent in favor of quick reconstruction by incremental learning. However, BL has trouble extracting complicated features from medical data, which makes it perform poorly in cases involving complex healthcare. We suggest ABL, which combines the effectiveness of BL with the noise reduction of Denoising Auto Encoder (AE), to address this. Robust feature extraction is an area in which the hybrid model shines, especially in intricate medical environments. Accuracy of up to 98.50 % is achieved by remarkable results from validation using a variety of datasets. The ability of ABL to quickly adapt through incremental learning suggests that it may be used to forecast diseases in complicated healthcare contexts with agility and accuracy.
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ISSN:2472-6303
2472-6311
DOI:10.1016/j.slast.2024.100145