Optical Nanosensors for the Detection of Quaternary Ammonium Compounds

Abstract

Quaternary ammonium compounds (QACs) are common active ingredients in chemical disinfectants, household cleaners, cosmetics, pesticides, etc. Recently QACs have been detected in human blood and breast milk during the COVID-19 pandemic. Humans can be exposed to QACs through dermal adsorption during application, hand-to-mouth ingestion of disinfectant residues, and inhalation of indoor air upon treatment with disinfectant spray. Exposure to these chemicals can cause respiratory illness such as asthma and chronic obstructive pulmonary disease, increase inflammatory cytokines, decrease mitochondrial function, and disrupt cholesterol biosynthesis. However, the complete biological fate of QACs is currently unknown. Therefore, a real-time continuous monitoring system in complex biological environments is crucial to learn the long-term effects of QACs on human health.Photoluminescent single-walled carbon nanotubes (SWCNTs) are great candidates for developing optical probes to monitor biological systems due to their outstanding photophysical properties in the tissue-transparent near-infrared spectral region, high sensitivity, and high stability. Furthermore, nanotube-based sensors exhibit a great potential for an implantable, real-time, wireless optical detection technology. Herein, we developed a carbon nanotube-based optical sensor for the detection of QACs in complex solution. Our findings from this research could provide a basis for engineering an optical detection technology to gain insight on the long-term effects of QACs to human health.