AIMS: To assess the activity of biostatic agents on the microbial colonization of panel filters. METHODS AND RESULTS: Microfibre glass acrylic filters, both used and unused, were examined for the presence of microorganisms. Test strains were used to verify microbial colonization of filter media. Antimicrobial agents were applied to the filter media and tested for their ability to reduce microbial colonization. The integrity of the panel filters and the antimicrobial activity trends of the filter media treated with antimicrobials were verified. A filtration efficiency test was carried out on the treated filters to evaluate filtration performance. Filters treated with antimicrobials demonstrated markedly less microbial colonization (density and varieties of species), higher filtration efficiency and delayed deterioration of the filter. CONCLUSIONS: The most important results of this study are the demonstration of preservation of the integrity of the filters and the lower release of microorganisms from treated filters. SIGNIFICANCE AND IMPACT OF THE STUDY: These results contribute to the resolution of problems concerning the microbial contamination of panel filters in the heating, ventilating and air-conditioning systems commonly used in the electronic industry, pharmaceutical industry, hospitals and other environments where the absence of contaminating particles and microorganisms is required.
AIMS: To assess the activity of biostatic agents on the microbial colonization of panel filters. METHODS AND RESULTS: Microfibre glass acrylic filters, both used and unused, were examined for the presence of microorganisms. Test strains were used to verify microbial colonization of filter media. Antimicrobial agents were applied to the filter media and tested for their ability to reduce microbial colonization. The integrity of the panel filters and the antimicrobial activity trends of the filter media treated with antimicrobials were verified. A filtration efficiency test was carried out on the treated filters to evaluate filtration performance. Filters treated with antimicrobials demonstrated markedly less microbial colonization (density and varieties of species), higher filtration efficiency and delayed deterioration of the filter. CONCLUSIONS: The most important results of this study are the demonstration of preservation of the integrity of the filters and the lower release of microorganisms from treated filters. SIGNIFICANCE AND IMPACT OF THE STUDY: These results contribute to the resolution of problems concerning the microbial contamination of panel filters in the heating, ventilating and air-conditioning systems commonly used in the electronic industry, pharmaceutical industry, hospitals and other environments where the absence of contaminating particles and microorganisms is required.
Authors: Gi Byoung Hwang; Ki Joon Heo; Ji Ho Yun; Jung Eun Lee; Hee Ju Lee; Chu Won Nho; Gwi-Nam Bae; Jae Hee Jung Journal: PLoS One Date: 2015-05-14 Impact factor: 3.240
Authors: Mansour A Alghamdi; Salwa K Hassan; Noura A Alzahrani; Marwan Y Al Sharif; Mamdouh I Khoder Journal: Int J Environ Res Public Health Date: 2020-04-17 Impact factor: 3.390
Authors: Mansour A Alghamdi; Salwa K Hassan; Noura A Alzahrani; Fahd M Almehmadi; Mamdouh I Khoder Journal: Int J Environ Res Public Health Date: 2019-12-10 Impact factor: 3.390