Materials & Design (Feb 2024)
Bioaerosol and fine dust protection with quaternary trimethyl chitosan integration in polypropylene filters
Abstract
Fine dust and bioaerosols are significant public health concerns, showing the importance of protective measures. In this study, natural-based trimethyl chitosan, permanently burdened with a positive charge, was successfully distributed on the surface of melt-blown polypropylene sheets through a metal rod coating process. This surface modification was confirmed through scanning electron microscopy and X-ray photoelectron spectroscopy, indicating the surface adsorption of trimethyl chitosan without chemical bonding. Modifying polypropylene mask filters yielded a positive surface zeta potential for 10–20 g/m2 coat weight, increasing the filtration efficiency to 55–94 % in a standard particle filtration test using paraffin oil as a liquid aerosol. The filtration efficiency remained higher than conventional non-treated mask filters even after the humidification of sheets. In addition, the filtration test against fine dust particles, such as titanium dioxide, was performed with trimethyl chitosan-modified mask filters that captured up to 100–800 µg/m3 titanium oxide particle concentrations, showing better filtration than conventional mask filters in high fine dust events. Trimethyl chitosan-modified mask filters also exhibited potent inhibition, bactericidal, and antiviral effects against HCoV-OC43, reducing the virus infection rate by 93.69 %. Thus, trimethyl chitosan could be applied to several existing filter membranes to protect against particulate matter and dangerous airborne pathogens.
