View to the current developments into the field of nanosafety and risk assessment
Authors:
B. Schüllerová 1; V. Adamec 1; V. Bencko 2
Authors‘ workplace:
Ústav soudního inženýrství, Vysoké učení technické v Brně, vedoucí pracoviště doc. Ing. Aleš Vémola, Ph. D.
1; Ústav hygieny a epidemiologie, 1. lékařská fakulta UK a VFN v Praze, vedoucí pracoviště prof. MUDr. Milan Tuček, Csc.
2
Published in:
Pracov. Lék., 71, 2019, No. 3-4, s. 77-82.
Category:
Review Article
Overview
The current development of nanotechnologies requires increased attention, especially in the area of safety. Therefore, the paper deals with the current situation in the area of tools and techniques for reducing potential risks to human health and the environment. At the same time, it offers an overview of developments and existing regulations in the area of nanosafety incl. pitfalls with which it is necessary to deal. The aim is to acquaint with the current situation and to draw attention to the necessity of harmonizing procedures for risk assessment and ensure the safety of nanomaterials throughout their life cycle.
Keywords:
legislation – Safety – Nanomaterials – design – health risk
Sources
1. Doporučení Komise 2011/696/EU o definici nanomateriálů.
2. Kraegeloh, A., Suarez-Merino, B. et al. Implementation of Safe-by-Design for Nanomaterial Development and Safe Innovation: Why We Need a Comprehensive Approach. Nanomaterials (Basel), 2018, 8, 4. ISSN 2079-4991.
3. Micheletti, CH. et al. NANoREG’s Safe by Design Concept for Nanomaterials [online]. Susnano, 2018 [cit. 2019-01-06]. Dostupné na www: http://www.susnano.org/images/SNO-SUN15/5A.2_Micheletti%20C%20_%20NANoREG‘s%20Safe-by-Desing%20concept.pdf.
4. Schwarz-Plaschg, C. et al. Making Nanomaterials Safer by Design? NanoEthics, 2017, 11, 3, pp. 277–281. ISSN 1871-4757.
5. NANOREG2. Safe by Design [online]. EU, 2018 [cit. 2019-01-10]. Dostupné na www: https://www.nanoreg2.eu/safe-design.
6. Yan, L., Zhao, F. et al. A Safe-By-Design Strategy towards Safer Nanomaterials in Nanomedicines. Advanced Materials, 2019, 1805391. ISSN 0935-9648.
7. Adamec, V., Schüllerová, B., Bencko, V., Hrabová, K., Bulejko, P. Možné přístupy k hodnocení rizik nanočástic z pohledu znalce. Soudní inženýrství, 2018, 29, 1, s. 41–48. ISSN 1211-443X.
8. Fojtík, A., Kálal, M., Prnka, T., Šperlink, K. et al. NANO, fascinující fenomén současnosti. Comtes FHT, 2014, 228 s. ISBN 978-80-260-7135-8.
9. Fojtík, A., Piksová, K., Weiserová, M., Bencko, V. Nanočástice a nanostruktury v biomedicínských aplikacích. Prakt. Lék, 2012, 92, 8, s. 440–443.
10. European Chemical Agency. Hodnocení látky – CoRAP [online]. European Chemical Agency, 2019 [cit. 2019-06-20]. Dostupné na www: https://echa.europa.eu/cs/information-on-chemicals/evaluation/community-rolling-action-plan/corap-table/-/dislist/details/0b0236e1807ebca5.
11. BAUA. Technical Rules for Hazardous Substances [online]. Federal Institute for Occupational Safety and Health [cit. 2019-06-28]. Dostupné na www: https://www.baua.de/EN/Service/Legislative-texts-and-technical-rules/Rules/TRGS/TRGS.html.
12. Nařízení Evropského parlamentu a Rady (ES) č. 1907/2006 o registraci, hodnocení, povolování a omezování chemických látek.
13. REACHnano. Guidance on available methods for risk assessment of nanomaterials [online]. Technical Guidances series 2015 [cit. 2018-12-19]. Dostupné na www: http://www.invassat.gva.es/documents/161660384/162311778/01+Guidance+on+available+methods+for+risk+assesment+of+nanomaterials/8cae41ad-d38a-42f7-90f3-9549a9c13fa0.
14. Physical-Chemical decision framework to inform decision for risk assessment of manufactured nanomaterials. Series on the Safety of Manufactured Nanomaterials No. 90. OECD, Environmenta Directorate, 27. 5. 2019, 41 p. ENV/JM/MONO(2019)13.
15. Guiding Principles for measurements and reporting for nanomaterials: physical chemical parameters. Series on the Safety of Manufactured Nanomaterials No. 91. OECD, Environmenta Directorate, 27. 5. 2019, 41 p. ENV/JM/MONO(2019)13.
16. Schüllerová, Adamec, V., Bencko, V. Současné trendy v oblasti zajištění nanobezpečnosti. In XXVIII. mezinárodní vědecká konference soudního inženýrství, ExFoS, Brno, 2019, s. 614–620. ISBN 978-80-214-5708-9.
Labels
Hygiene and epidemiology Hyperbaric medicine Occupational medicineArticle was published in
Occupational Medicine
2019 Issue 3-4
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