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An integrated health risk assessment with control banding for nanomaterials exposure

Nanomaterials are known to cause biological effects to humans through various routes of exposure such as injection, intravenous, oral, and inhalation. The risk analyses through conventional qualitative or semi-quantitative approaches, such as control banding tools with limited safety data, and infor...

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Main Authors: Halil, N., Rusli, R., Zainal Abidin, M., Jamen, S., Khan, F.
Format: Article
Published: John Wiley and Sons Inc 2021
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85120828931&doi=10.1002%2fprs.12327&partnerID=40&md5=766f69a83e4ba2efc10ecc1be7572522
http://eprints.utp.edu.my/29350/
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spelling my.utp.eprints.293502022-03-25T00:58:05Z An integrated health risk assessment with control banding for nanomaterials exposure Halil, N. Rusli, R. Zainal Abidin, M. Jamen, S. Khan, F. Nanomaterials are known to cause biological effects to humans through various routes of exposure such as injection, intravenous, oral, and inhalation. The risk analyses through conventional qualitative or semi-quantitative approaches, such as control banding tools with limited safety data, and information on the risks posed by nanomaterials, have created uncertainties in decision-making by various stakeholders. Therefore, an integrated Nanomaterial Risk (NanoRisk) framework that incorporates the Bayesian Network (BN) model, control banding, and process parameters focusing on humidity, the mass of nanomaterials, and operating temperatures was developed to assess the hazards of nanomaterials and their potential biological effects to human health as a result of exposure. The proposed risk assessment was applied to nanomaterials used in the paint and coating industry (nano-silica, nano-titanium, and nano-silver), and the nodes of the BN model were constructed from physiochemical properties, biological effects, routes of exposure, and types of studies extracted from published data. The flexible analytic approach of the BN model allows for a valuable prediction of hazard exposure towards nanomaterials, thus facilitating decision-making. Furthermore, the integrated framework proposes suitable control measures to reduce the hazard exposure according to the hazard level at different modes of operation. The distinctive feature of NanoRisk demonstrates comprehensive analysis and results that are comparable with previously developed methods. © 2021 American Institute of Chemical Engineers. John Wiley and Sons Inc 2021 Article NonPeerReviewed https://www.scopus.com/inward/record.uri?eid=2-s2.0-85120828931&doi=10.1002%2fprs.12327&partnerID=40&md5=766f69a83e4ba2efc10ecc1be7572522 Halil, N. and Rusli, R. and Zainal Abidin, M. and Jamen, S. and Khan, F. (2021) An integrated health risk assessment with control banding for nanomaterials exposure. Process Safety Progress . http://eprints.utp.edu.my/29350/
institution Universiti Teknologi Petronas
building UTP Resource Centre
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Petronas
content_source UTP Institutional Repository
url_provider http://eprints.utp.edu.my/
description Nanomaterials are known to cause biological effects to humans through various routes of exposure such as injection, intravenous, oral, and inhalation. The risk analyses through conventional qualitative or semi-quantitative approaches, such as control banding tools with limited safety data, and information on the risks posed by nanomaterials, have created uncertainties in decision-making by various stakeholders. Therefore, an integrated Nanomaterial Risk (NanoRisk) framework that incorporates the Bayesian Network (BN) model, control banding, and process parameters focusing on humidity, the mass of nanomaterials, and operating temperatures was developed to assess the hazards of nanomaterials and their potential biological effects to human health as a result of exposure. The proposed risk assessment was applied to nanomaterials used in the paint and coating industry (nano-silica, nano-titanium, and nano-silver), and the nodes of the BN model were constructed from physiochemical properties, biological effects, routes of exposure, and types of studies extracted from published data. The flexible analytic approach of the BN model allows for a valuable prediction of hazard exposure towards nanomaterials, thus facilitating decision-making. Furthermore, the integrated framework proposes suitable control measures to reduce the hazard exposure according to the hazard level at different modes of operation. The distinctive feature of NanoRisk demonstrates comprehensive analysis and results that are comparable with previously developed methods. © 2021 American Institute of Chemical Engineers.
format Article
author Halil, N.
Rusli, R.
Zainal Abidin, M.
Jamen, S.
Khan, F.
spellingShingle Halil, N.
Rusli, R.
Zainal Abidin, M.
Jamen, S.
Khan, F.
An integrated health risk assessment with control banding for nanomaterials exposure
author_facet Halil, N.
Rusli, R.
Zainal Abidin, M.
Jamen, S.
Khan, F.
author_sort Halil, N.
title An integrated health risk assessment with control banding for nanomaterials exposure
title_short An integrated health risk assessment with control banding for nanomaterials exposure
title_full An integrated health risk assessment with control banding for nanomaterials exposure
title_fullStr An integrated health risk assessment with control banding for nanomaterials exposure
title_full_unstemmed An integrated health risk assessment with control banding for nanomaterials exposure
title_sort integrated health risk assessment with control banding for nanomaterials exposure
publisher John Wiley and Sons Inc
publishDate 2021
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85120828931&doi=10.1002%2fprs.12327&partnerID=40&md5=766f69a83e4ba2efc10ecc1be7572522
http://eprints.utp.edu.my/29350/
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score 13.214268

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