Abstract
The antibacterial effects of quaternary ammonium resins (QARs) have been reported for decades, but there are few practical applications because of limited improvements in bactericidal capacity and the absence of an efficient antibacterial-indicating parameter. An in-situ determination method of surficial N+ groups for QARs, defined as surficial N+ charge density, was first established to merely quantify the exposed surficial quaternary ammonium groups (QAs). The mechanism of the new method depends on the tetraphenylboron sodium standard solution (TS), which is a colloidal solution with high steric hindrance, making it difficult to permeate into QARs and further react with the inner QAs. The results showed that the antibacterial efficacy of QARs correlates with the surficial N+ charge density with R2 > 0.95 (R2 of 0.97 for Escherichia coli, R2 of 0.96 for Staphylococcus aureus) but not with the strong-base group exchange capacity or zeta potential. Furthermore, the surficial N+ charge density was demonstrated efficient to indicate the antibacterial capacities against both gram-negative and gram-positive bacteria for commercial QARs, including acrylic, styrene and pyridine resin skeletons, especially for the QARs with similar skeletons and similar QAs. Based on the finding that the bactericidal groups merely involve the surficial QAs of QARs, this study proposes a new direction for improving the antibacterial capacity by enriching the surficial QAs and enhancing the bactericidal property of these surficial QAs, and provides a practicable synthesis with two-step quaternization.
Highlights
It is indispensable to kill bacteria for the production of safe drinking water to protect against waterborne diseases
In terms of method A1, the detection values increase with reaction time, which shows that the method requires a long detection time for quaternary ammonium resins (QARs), which is different from the short detection time for micromolecular quaternary ammonium compounds (QACs) [27, 30]
tetraphenylboron sodium standard solution (TS) with high steric hindrance is difficult to permeate into QARs and react with the inner quaternary ammonium groups (QAs), and most N+ active sites are embedded in the interior of QARs and hindered by the instantly formed surficial precipitates, which results in the established method merely detecting the surficial QAs of QARs
Summary
It is indispensable to kill bacteria for the production of safe drinking water to protect against waterborne diseases. Common chemical disinfectants, such as chlorine, monochloramine and ozone [1, 2], unavoidably generate harmful disinfection byproducts (DBPs) in water disinfection, which closely correlate with cancer, miscarriage or birth defects [3, 4]. Ultraviolet (UV) radiation disinfection application is limited because of bacterial regrowth via photoreactivation or dark repair [5,6,7]. Various tolerant bacteria have emerged to be resistant to these chemical disinfectants or antibiotics [8,9,10], posing threats to conventional water disinfection safety.
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