Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder

Developing new treatments for emerging infectious diseases in infectious and noninfectious diseases has attracted a particular attention. The emergence of viral diseases is expected to accelerate; these data indicate the need for a proactive approach to develop widely active family specific and cros...

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Main Authors: Junejo, A. R., Kaabar, Mohammed K. A., Li, Xiang
Format: Article
Published: Hindawi Ltd 2021
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Online Access:http://eprints.um.edu.my/35272/
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spelling my.um.eprints.352722022-10-18T03:25:00Z http://eprints.um.edu.my/35272/ Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder Junejo, A. R. Kaabar, Mohammed K. A. Li, Xiang QA Mathematics QA75 Electronic computers. Computer science R Medicine Medical technology Developing new treatments for emerging infectious diseases in infectious and noninfectious diseases has attracted a particular attention. The emergence of viral diseases is expected to accelerate; these data indicate the need for a proactive approach to develop widely active family specific and cross family therapies for future disease outbreaks. Viral disease such as pneumonia, severe acute respiratory syndrome type 2, HIV infection, and Hepatitis-C virus can cause directly and indirectly cardiovascular disease (CVD). Emphasis should be placed not only on the development of broad-spectrum molecules and antibodies but also on host factor therapy, including the reutilization of previously approved or developing drugs. Another new class of therapeutics with great antiviral therapeutic potential is molecular communication networks using deep learning autoencoder (DL-AEs). The use of DL-AEs for diagnosis and prognosis prediction of infectious and noninfectious diseases has attracted a particular attention. MCN is map to molecular signaling and communication that are found inside and outside the human body where the goal is to develop a new black box mechanism that can serve the future robust healthcare industry (HCI). MCN has the ability to characterize the signaling process between cells and infectious disease locations at various levels of the human body called point-to-point MCN through DL-AE and provide targeted drug delivery (TDD) environment. Through MCN, and DL-AE healthcare provider can remotely measure biological signals and control certain processes in the required organism for the maintenance of the patient's health state. We use biomicrodevices to promote the real-time monitoring of human health and storage of the gathered data in the cloud. In this paper, we use the DL-based AE approach to design and implement a new drug source and target for the MCN under white Gaussian noise. Simulation results show that transceiver executions for a given medium model that reduces the bit error rate which can be learned. Then, next development of molecular diagnosis such as heart sounds is classified. Furthermore, biohealth interface for the inside and outside human body mechanism is presented, comparative perspective with up-to-date current situation about MCN. Hindawi Ltd 2021-12 Article PeerReviewed Junejo, A. R. and Kaabar, Mohammed K. A. and Li, Xiang (2021) Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder. Computational and Mathematical Methods in Medicine, 2021. ISSN 1748-670X, DOI https://doi.org/10.1155/2021/9949328 <https://doi.org/10.1155/2021/9949328>. 10.1155/2021/9949328
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Research Repository
url_provider http://eprints.um.edu.my/
topic QA Mathematics
QA75 Electronic computers. Computer science
R Medicine
Medical technology
spellingShingle QA Mathematics
QA75 Electronic computers. Computer science
R Medicine
Medical technology
Junejo, A. R.
Kaabar, Mohammed K. A.
Li, Xiang
Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder
description Developing new treatments for emerging infectious diseases in infectious and noninfectious diseases has attracted a particular attention. The emergence of viral diseases is expected to accelerate; these data indicate the need for a proactive approach to develop widely active family specific and cross family therapies for future disease outbreaks. Viral disease such as pneumonia, severe acute respiratory syndrome type 2, HIV infection, and Hepatitis-C virus can cause directly and indirectly cardiovascular disease (CVD). Emphasis should be placed not only on the development of broad-spectrum molecules and antibodies but also on host factor therapy, including the reutilization of previously approved or developing drugs. Another new class of therapeutics with great antiviral therapeutic potential is molecular communication networks using deep learning autoencoder (DL-AEs). The use of DL-AEs for diagnosis and prognosis prediction of infectious and noninfectious diseases has attracted a particular attention. MCN is map to molecular signaling and communication that are found inside and outside the human body where the goal is to develop a new black box mechanism that can serve the future robust healthcare industry (HCI). MCN has the ability to characterize the signaling process between cells and infectious disease locations at various levels of the human body called point-to-point MCN through DL-AE and provide targeted drug delivery (TDD) environment. Through MCN, and DL-AE healthcare provider can remotely measure biological signals and control certain processes in the required organism for the maintenance of the patient's health state. We use biomicrodevices to promote the real-time monitoring of human health and storage of the gathered data in the cloud. In this paper, we use the DL-based AE approach to design and implement a new drug source and target for the MCN under white Gaussian noise. Simulation results show that transceiver executions for a given medium model that reduces the bit error rate which can be learned. Then, next development of molecular diagnosis such as heart sounds is classified. Furthermore, biohealth interface for the inside and outside human body mechanism is presented, comparative perspective with up-to-date current situation about MCN.
format Article
author Junejo, A. R.
Kaabar, Mohammed K. A.
Li, Xiang
author_facet Junejo, A. R.
Kaabar, Mohammed K. A.
Li, Xiang
author_sort Junejo, A. R.
title Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder
title_short Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder
title_full Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder
title_fullStr Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder
title_full_unstemmed Optimization: Molecular communication networks for viral disease analysis using deep leaning autoencoder
title_sort optimization: molecular communication networks for viral disease analysis using deep leaning autoencoder
publisher Hindawi Ltd
publishDate 2021
url http://eprints.um.edu.my/35272/
_version_ 1748181069390151680