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用于控制室内环境生物气溶胶的杀菌纳米材料改性过滤介质的原位评估

In Situ Evaluation of Filter Media Modified by Biocidal Nanomaterials to Control Bioaerosols in Internal Environments.

作者信息

de Freitas Rosa Remiro Paula, de Sousa Cristina Paiva, Alves Henrique Cezar, Bernardo André, Aguiar Mônica Lopes

机构信息

Chemical Engineering Department, Federal University of São Carlos, São Carlos, SP Brazil.

Morphology and Pathology Department, Federal University of São Carlos, São Carlos, SP Brazil.

出版信息

Water Air Soil Pollut. 2021;232(5):176. doi: 10.1007/s11270-021-05105-3. Epub 2021 Apr 19.

DOI:10.1007/s11270-021-05105-3
PMID:33897067
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8055056/
Abstract

Controlling the bioaerosol present in indoor environments has been evidenced to be extremely necessary. An alternative is to develop filter media for air conditioners that have biocidal properties. This study aimed to verify the biocidal effect of a high-efficiency particulate air (HEPA) filter medium modified with the deposition of nanoparticles on its surface. For this purpose, Ag, TiO, and Ag/TiO nanoparticles were used and the antimicrobial activities of these nanomaterials against , , and microorganisms were evaluated, as well as the biocidal efficacy of the modified HEPA filter with these nanomaterials in a real environment. The percentages of elimination obtained for the Ag, TiO, and Ag/TiO nanomaterials, respectively, were 53%, 63%, and 68% (); 67%, 67%, and 69% (); and 68%, 73%, and 75% (). The HEPA filter media had their surfaces modified by aspersion and deposition of Ag, TiO, and Ag/TiO nanomaterials. We could conclude that the nanoparticles adhered to the filter medium do not affect its permeability. The modified filters were arranged in an internal environment (bathroom) for the collection of the bioaerosols, and after the collection, the filter cake was plated and arranged to grow in a liquid medium. The results showed that the filters have 100% of biocidal action in passing air, and 55.6%, 72.2%, and 81% of inhibition to microbial growth in their surface for modification with Ag, TiO, and Ag/TiO, respectively, compared to unmodified filters.

摘要

控制室内环境中存在的生物气溶胶已被证明是极其必要的。一种替代方法是开发具有杀菌特性的空调过滤介质。本研究旨在验证一种表面沉积有纳米颗粒的高效空气过滤器(HEPA)过滤介质的杀菌效果。为此,使用了银、二氧化钛和银/二氧化钛纳米颗粒,并评估了这些纳米材料对 、 和 微生物的抗菌活性,以及用这些纳米材料改性的HEPA过滤器在实际环境中的杀菌效果。银、二氧化钛和银/二氧化钛纳米材料分别获得的消除百分比为53%、63%和68%( );67%、67%和69%( );以及68%、73%和75%( )。通过喷洒和沉积银、二氧化钛和银/二氧化钛纳米材料对HEPA过滤介质的表面进行了改性。我们可以得出结论,附着在过滤介质上的纳米颗粒不会影响其渗透性。将改性过滤器放置在室内环境(浴室)中以收集生物气溶胶,收集后,将滤饼铺板并放置在液体培养基中生长。结果表明,与未改性的过滤器相比,改性过滤器对通过的空气具有100%的杀菌作用,并且其表面用银、二氧化钛和银/二氧化钛改性后,对微生物生长的抑制率分别为55.6%、72.2%和81%。

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