Toxicological and hygienic assessment of modern thermo-insulating polymer materials during thermal exposure
- Authors: Tolkach P.G.1, Basharin V.A.1, Shilov Y.V.1, Yazenok A.V.1, Antushevich A.E.1, Zagorodnikov G.G.1
-
Affiliations:
- Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
- Issue: Vol 102, No 7 (2023)
- Pages: 726-731
- Section: PREVENTIVE TOXICOLOGY AND HYGIENIC STANDARTIZATION
- Published: 31.08.2023
- URL: https://rjsocmed.com/0016-9900/article/view/638528
- DOI: https://doi.org/10.47470/0016-9900-2023-102-7-726-731
- EDN: https://elibrary.ru/onarkk
- ID: 638528
Cite item
Full Text
Abstract
Introduction. Polyethylene and synthetic foam caoutchouc are used for thermal insulation of communications, at temperatures not exceeding 90 °C and 105 °C, respectively. Data on how these materials will behave in the appropriate temperature conditions was not be found.
The purpose of the study was to conduct a toxicological and hygienic assessment of products made of polyethylene foam and synthetic foam rubber under thermal exposure.
Materials and methods. The thermal effect on the studied samples was modelled in a climate chamber. The time interval during the mass loss of the samples was determined, a sanitary and chemical study of the gas-air mixture in the climatic chamber was carried out. To conduct a toxicological and hygienic study in animals, a swim-escape conditioned active avoidance response was developed.
Results. Under thermal (90 °C) exposure for 72 hours to polyethylene tube, a loss of 0.77% of the initial mass of the sample occurs. Thermal exposure (105 °C) to synthetic foam caoutchouc resulted in a loss of 15.3% of the initial mass of the sample for 108 hours, while pronounced changes in the appearance of the samples were determined. When conducting a sanitary and chemical study in the climate chamber, an increase in the concentration of carbon monoxide was determined after 12, 24, and 72 hours and hydrogen chloride after 12 and 24 hours following the onset of thermal exposure compared with the values of their average daily maximum permissible concentration. Thermal exposure to the sample and synthetic foam caoutchouc led to an increase in the concentration of ammonia, carbon monoxide and hydrogen chloride 12 and 24 hours after the start of exposure compared with the average daily maximum permissible concentration. During the toxicological and hygienic study, animals exposed to thermal degradation products of the materials under study were revealed to show learning disabilities.
Limitations. They are conditioned by the methodology of the study. A quantitative analysis of some gaseous thermal degradation products released into the climate chamber was performed, without taking into account the aerosols formed.
Conclusion. Thermal insulation materials made of synthetic foam rubber and polyethylene foam lose their structural properties when they are operated in the maximum permissible temperature conditions (105 °C and 90 °C, respectively). When they are used in appropriate temperature conditions, the formation of toxic products occurs, the inhalation effect of which leads to a disturbances of the learning ability in laboratory animals.
Compliance with ethical standards. The Local ethics committee of the Military Medical Academy named after S.M. Kirov. The work was guided by the requirements of regulatory legal acts on the procedure for experimental work using animals, including humane treatment of them.
Contribution:
Tolkach P.G. — the concept and design of the study, collection and processing of material, statistical processing, writing a text;
Basharin V.A. — the concept and design of the study, editing;
Shilov Yu.V. — collection and processing of material;
Yazenok A.V., Antushevich A.E., Zagorodnikov G.G. — editing.
All authors are responsible for the integrity of all parts of the manuscript and approval of the manuscript final version.
Conflict of interest. The authors declare no conflict of interest.
Acknowledgement. The study had no sponsorship.
Received: March 6, 2023 / Accepted: June 7, 2023 / Published: August 30, 2023
About the authors
Pavel G. Tolkach
Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
Author for correspondence.
Email: pgtolkach@gmail.com
ORCID iD: 0000-0001-5013-2923
MD, PhD, DSci, lecturer of the department military toxicology and medical protection of the Military Medical Academy named after S.M. Kirov, Saint-Petersburg, 194044, Russian Federation.
e-mail: pgtolkach@gmail.com
Russian FederationVadim A. Basharin
Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
Email: noemail@neicon.ru
Russian Federation
Yurii V. Shilov
Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
Email: noemail@neicon.ru
Russian Federation
Arkadii V. Yazenok
Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
Email: noemail@neicon.ru
Russian Federation
Alexandr E. Antushevich
Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
Email: noemail@neicon.ru
Russian Federation
Gennadii G. Zagorodnikov
Military Medical Academy named after S.M. Kirov of the Ministry of Defense of the Russian Federation
Email: noemail@neicon.ru
Russian Federation
References
- Koshel’nikova V.V. Analysis of application of modern thermal nsulation materials in heat supply systems. In: Experimental and Theoretical Research in Modern Science. Collection of Articles Based on the Materials of the LVII International Scientific and Practical Conference. Volume 9 [Eksperimental’nye i teoreticheskie issledovaniya v sovremennoy nauke. Sbornik statey po materialam LVII mezhdunarodnoy nauchno-prakticheskoy konferentsii. Tom 9]. Novosibirsk; 2020: 13–9. https://elibrary.ru/zpqanj (in Russian)
- Pavlov M.V., Karpov D.F., Berezina V.P. Modern thermal insulation materials for improving the thermal protection properties of building structures and energy efficiency of engineering systems. Nauchno-tekhnicheskie problemy sovershenstvovaniya i razvitiya sistem gazoenergosnabzheniya. 2020; (1): 81–7. https://elibrary.ru/oktxck (in Russian)
- Chabannyy A.N. Energy-saving technologies. Nauchnye issledovaniya. 2016; (9): 7–11. https://elibrary.ru/wxgxlt (in Russian)
- Tolkach P.G., Basharin V.A., Chepur S.V., Vengerovich N.G., Yudin M.A., Nikiforov A.S., et al. Toxicology of Combustion Products of Polymeric Materials [Toksikologiya produktov goreniya polimernykh materialov]. St. Petersburg: Levsha, Sankt-Peterburg; 2022. https://elibrary.ru/wjxuda (in Russian)
- Madorsky S.L. Thermal Degradation of Organic Polymers. John Wiley & Sons; 1964.
- Bureš J., Burešová O. Techniques and Basic Experiments for the Study of Brain and Behavior. Elsevier; 1983.
- Glantz S.A. Primer of Biostatistics. New-York: McGraw-Hill; 1994.
- Knunyants I.L. Chemical Encyclopedia: Volume 3 [Khimicheskaya entsiklopediya. Tom 3]. Moscow: Bol’shaya Rossiyskaya entsiklopediya; 1992. (in Russian)
- Potapov P.K., Dimitriev Yu.V., Tolkach P.G. Structural and functional disorders of the respiratory system in laboratory animals when intoxicated by pyrolysis products of chlorine-containing polymer materials. Meditsinskiy akademicheskiy zhurnal. 2020; 20(3): 13–22. https://doi.org/10.17816/MAJ35170 https://elibrary.ru/anlhui (in Russian)
- Deutsch J.A. The cholinergic synapse and the site of memory. Science. 1971; 174(4011): 788–94. https://doi.org/10.1126/science.174.4011.788
- Pepe G., Castelli М., Nazerian Р., Vanni I., Panta M., Gambassi F., et al. Delayed neuropsychological sequelae after carbon monoxide poisoning: predictive risk factors in the Emergency Department. A retrospective study. Scand. J. Trauma Resusc. Emerg. Med. 2011; 19: 16. https://doi.org/10.1186/1757-7241-19-16
Supplementary files
