posted on 2024-04-19, 14:33authored byHariharan Sekar, Mahesh Tirumkudulu, Venkat Gundabala
Waterborne coatings with intrinsic antibacterial attributes
have
attracted significant attention due to their potential in mitigating
microbial contamination while simultaneously addressing the environmental
drawbacks of their solvent-based counterparts. Typically, antimicrobial
coatings are designed to resist and eliminate microbial threats, encompassing
challenges such as biofilm formation, fungal contamination, and proliferation
of black mold. Iodine, when solubilized using ethylene glycol and
incorporated as a complex into waterborne latex dispersions, has shown
remarkable antimicrobial activity. Here, we demonstrate the effect
of the film formation process of these iodinated latex dispersions
on their antimicrobial properties. The effect of iodine on the surface
morphology and mechanical, adhesion, and antimicrobial properties
of the generated films was investigated. Complete integration and
uniform distribution of iodine in the films were confirmed through
UV–vis spectrophotometry and a laser Raman imaging system (LRIS).
In terms of properties, iodinated films showed improved mechanical
strength and adhesion compared with blank films. Further, the presence
of iodine rendered the films rougher, making them susceptible to bacterial
adhesion, but interestingly provided enhanced antibiofilm activity.
Moreover, thicker films had a lower surface roughness and reduced
biofilm growth. These observations are elucidated through the complex
interplay among film thickness, surface morphology, and iodine properties.
The insights into the interlink between the film formation process
and antimicrobial properties of iodinated latex dispersions will facilitate
their enhanced application as sustainable alternatives to solvent-based
coatings.