@article{dewey_jones_lucas_hall_sultana_abello_budhathoki-uprety_2023, title={Carbon Nanotubes for Optical Detection of Quaternary Ammonium Compounds in Complex Media}, volume={6}, ISSN={2574-0970 2574-0970}, url={http://dx.doi.org/10.1021/acsanm.3c02219}, DOI={10.1021/acsanm.3c02219}, abstractNote={Quaternary ammonium compounds (QACs) are widely used in disinfectants, cleaners, preservatives, cosmetics, and agriculture. Recently, QACs have been detected in the human bloodstream, breast milk, and neonatal mouse brain, which shows that these compounds can cross biological barriers. In vivo studies showed that chronic low-level exposure to QACs causes developmental, reproductive, and immune dysfunctions, whereas in vitro studies indicate that QACs can affect reproductive systems, disrupt cholesterol biosynthesis, increase inflammatory cytokines, and decrease mitochondrial functions. Effects of QACs on health are gradually emerging, amid increased use of QAC disinfectants during the COVID-19 pandemic. Analysis of biological fluids including blood, urine, sweat, and saliva can provide vital information in determining the biological effects of analytes. Biofluid analysis is convenient yet crucial because of non-invasive/or minimally invasive procedures that can be performed outside hospital settings. Interest in optical detection methods for biofluid analysis has been growing due to recent advances in detection technologies and availability of tunable materials to aid the technologies. Detection in the near-infrared (NIR) spectral range is advantageous over the visible range mainly due to minimal autofluorescence, light-scattering, and absorption from native biological molecules in the NIR range. Photoluminescent single-walled carbon nanotubes (SWCNTs) are promising candidates for the development of NIR optical probes and sensors due to their non-photobleaching NIR fluorescence, tunable surface chemistry, and high sensitivity. Herein, we report optical detection of QACs in protein-rich media and a model biofluid. We functionalized photoluminescent SWCNTs with bile salt derivatives that enabled the detection of QACs in artificial sweat and serum-protein-enriched media. The QAC detection was significant at nanomolar concentrations, which is within the threshold that can affect various physiological processes. Thus, nanotube-based optical detection could be well suited for the analysis of QACs in biological fluids.}, number={17}, journal={ACS Applied Nano Materials}, publisher={American Chemical Society (ACS)}, author={Dewey, Hannah M. and Jones, Jaron and Lucas, Sydney and Hall, Shelby and Sultana, Nigar and Abello, Sofia Mariapaz and Budhathoki-Uprety, Januka}, year={2023}, month={Aug}, pages={15530–15539} }
 @misc{dewey_jones_keating_budhathoki-uprety_2022, title={Increased Use of Disinfectants During the COVID-19 Pandemic and Its Potential Impacts on Health and Safety}, volume={29}, ISSN={["1878-0504"]}, url={https://doi.org/10.1021/acs.chas.1c00026}, DOI={10.1021/acs.chas.1c00026}, abstractNote={The COVID-19 pandemic has called for the increased use of disinfectants worldwide in public facilities, transportation, hospitals, nursing homes, wastewater treatment facilities, and even common households to mitigate virus burden. Active ingredients in common disinfectants recommended for use against COVID-19 viruses include chemicals such as quaternary ammonium compounds (QACs), hydrogen peroxide, bleach (sodium hypochlorite), and alcohols. These disinfecting chemicals differ in their structures, properties, modes of action, environmental behaviors, and effects on human health upon exposure. Humans can be exposed to disinfecting chemicals mainly through dermal absorption, inhalation, and ingestion. The total exposure and relative contribution of each exposure route vary considerably among the disinfectants. QACs have been linked to occupational illnesses such as asthma and an increased risk of chronic obstructive pulmonary disease (COPD), whereas excess use of bleach, hydrogen peroxide, or alcohol-based disinfectants can cause respiratory damage and has been linked to an increased risk of developing and controlling asthma. Recent studies showed that the presence of QACs in human blood has been associated with changes in health biomarkers such as an increase in inflammatory cytokines, decreased mitochondrial function, and disruption of cholesterol homeostasis in a dose-dependent manner. Therefore, repeated human exposure to disinfectants during the pandemic has raised questions on exposure-related long-term health risks and occupational safety. Furthermore, in lieu of a lack of adequate knowledge and public awareness, these chemicals have been frequently used on porous surfaces, including fabrics/textiles and consumer plastics and even for disinfecting cloth facemasks, on which disinfectant chemical residues may persist for longer duration, causing potential degradation of plastic materials, releasing additives, and shedding microplastics. In addition, the increased use of these disinfectant chemicals and the subsequent discharge into wastewater may cause adverse impacts on aquatic ecosystems, accumulation on vegetables, and contamination of the food chain via wastewater irrigation and sludge application. This article provides a well-rounded understanding of the most common disinfectants and reviews modes of action of those disinfectants, their interactions with aquatic and terrestrial environments, the exposure to humans, and potential impacts to human health and safety.}, number={1}, journal={ACS CHEMICAL HEALTH & SAFETY}, publisher={American Chemical Society (ACS)}, author={Dewey, Hannah M. and Jones, Jaron M. and Keating, Mike R. and Budhathoki-Uprety, Januka}, year={2022}, month={Jan}, pages={27–38} }