Evaluation and prediction of the effectiveness of the protective properties of woven materials of workwear in contact with microorganisms
DOI:
https://doi.org/10.28983/asj.y2023i5pp166-171Keywords:
special clothes, cotton fabric, protective properties, microbial contaminationAbstract
The article deals with the main problems of choosing fabrics in the development of special clothing for workers employed in agriculture in industries associated with increased microbial contamination and indoor air humidity. To determine the number of microorganisms in the material of special clothing, we proposed a method that can significantly reduce the complexity of sampling through the use of non-destructive testing, the use of small-sized equipment and the repeated use of the Peltier element to obtain condensate.
Downloads
References
Klar S., Poether D.-C., et al. Application of impedance measurement to investigate in vitro inhalation toxicity of bacteria // Journal of Occupational Medicine and Toxicology, 16(2021), 32
Rasmussen P.U., Phan H.U.T., Frederiksen M.W., Madsen A.M. A characterization of bioaerosols in biowaste pretreatment plants in relation to occupational health // Waste Management, 2021, 131, с. 237-248
Образование биопленок – пример «социального» поведения бактерий / Ю.М. Романова [и др.] // Микробиология. 2006. Т. 75(4). С. 1-6.
Shkrabak V.S., Gavrikova E.I., Shkrabak R.V. et al. Photocatalytic method of disinfection of indor areas with increased microbial content / International Transaction Journal of Engineering, Management and Applied Sciences and Technologies. 2020. Т. 11. No. 10. С. 11A10J
Чеботарь И.В., Маянский А.Н., Кончакова Е.Д., Лазарева А.В., Чистякова В.П. Антибиотикорезистентность биопленочных бактерий // Клин. микробиол. антимикроб. химиотер. 2012, Т. 14(1). C. 51-58.
Wikuats C.F.H., da Silva I., et al. Health symptoms and inflammatory blood biomarkers from exposure of recyclable waste workers to particulate matter and bioaerosols // Atmospheric Pollution Research, 13(2022), 101323.
M?ller S.A., Rasmussen P.U., Frederiksen M.W., Madsen A.M. Work clothes as a vector for microorganisms: Accumulation, transport, and resuspension of microorganisms as demonstrated for waste collection workers // Environment International. 2022, 161, 107112.
Hoseinzadeh E. A review on nano-antimicrobials: metal nanoparticles, methods and mechanisms / E. Hoseinzadeh, P. Makhdoumi, P. Taha, H. Hossini, J. Stelling, M.A. Kamal, G.M. Ashraf // Curr. Drug. Metab. 2017. Vol. 18. No. 2. P. 120-128.
Raghunath A. Metal oxide nanoparticles as antimicrobial agents: a promise for the future / A. Raghunath, E. Perumal // Int. J. Antimicrob. Agents. 2017. Vol. 49. No. 2. P. 137-152.
Zaidi S. Nano-therapeutics: a revolution in infection control in post antibiotic era / S. Zaidi, L. Misba, A.U. Khan // Nanomedicine. 2017. Vol. 13. No. 7. P. 2281-2301.
Gold K. Antimicrobial activity of metal and metal?oxide based nanoparticles / K. Gold, B. Slay, M. Knackstedt, A.K. Gaharwar // Adv. Therap. 2018. Vol. 1. No. 3. DOI: 10.1002/adtp.201700033.
Гаврикова Е.И. Особенности характеристик защитных свойств тканых материалов / Безопасность жизнедеятельности. 2014. № 8 (164). С. 18-20.
Mosalaei S., Amiri H., Rafiee A., et al. Assessment of fungal bioaerosols and particulate matter characteristics in indoor and outdoor air of veterinary clinics // Journal of Environmental Health Science and Engineering, 19(2021), 1773-1780.
Гаврикова Е.И. Устройство с прерыванием для определения микробной обсемененности спецодежды // пат. РФ № 2730027, 2020.
Downloads
Published
Issue
Section
License
Copyright (c) 2023 The Agrarian Scientific Journal
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
