Abstract
In the context of healthcare-acquired infections, microbial cross-contamination and the spread of antibiotic resistance, additional passive measures to prevent pathogen carryover are urgently needed. Antimicrobial high-touch surfaces that kill microbes on contact or prevent their adhesion could be considered to mitigate the spread. Here, we demonstrate that photocatalytic nano-ZnO- and nano-ZnO/Ag-based antibacterial surfaces with efficacy of at least a 2.7-log reduction in Escherichia coli and Staphylococcus aureus viability in 2 h can be produced by simple measures using a commercial acrylic topcoat for wood surfaces. We characterize the surfaces taking into account cyclic wear and variable environmental conditions. The light-induced antibacterial and photocatalytic activities of the surfaces are enhanced by short-term cyclic wear, indicating their potential for prolonged effectivity in long-term use. As the produced surfaces are generally more effective at higher relative air humidity and silver-containing surfaces lost their contact-killing properties in dry conditions, it is important to critically evaluate the end-use conditions of materials and surfaces to be tested and select application-appropriate methods for their efficacy assessment.
Highlights
Bacterial infections are exerting a significant impact on public health
We demonstrate the process of embedding antimicrobial ZnO/Ag nanomaterials into an acrylic-based commercial topcoat matrix that can be used in industry without changing the existing technology and causing excess costs
Minimal biocidal concentration (MBC) of ZnSO4, AgNO3 and H2 O2 at 1, 2 and 4 h towards E. coli and S. aureus was determined in 1:500 NB at room temperature to evaluate sensitivity of the bacterial strains used to respective metal ions and reactive oxygen species (ROS) damage
Summary
Bacterial infections are exerting a significant impact on public health. According to Global Health Metrics [1], microbial pathogens cause a higher burden to public health than either cancer or cardiovascular diseases. The efficacy of antimicrobial coatings in reducing the microbial bioburden has been most clearly demonstrated in laboratory conditions but has been studied in real-life situations, e.g., for copper surfaces [9,10,11], and their reducing activity on hospitalacquired infections has been shown [12]. Our previous studies have demonstrated 99.9% antibacterial activity of the surfaces in laboratory conditions under UVA that corresponded spectrally and in terms of intensity to natural solar light [17] These previous experiments concerned a layer of bare nano-ZnO/Ag particles heat-annealed to glass surfaces, where no additional substances (matrix) were used to fix the nanomaterial to the surfaces. In this paper, we aim at demonstrating the antimicrobial activity of nano-ZnO/Ag materials whose antibacterial efficacy has been previously tested, in their application-relevant configuration. Our results are expected to pave the way towards the use of nano-ZnO- and nano-ZnO/Ag-based surface coatings in fit-for-purpose antimicrobial surface applications
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