Screening for Bisphenol Chemicals: A Strategy Based on Dansyl Chloride Derivatizatio n Coupled with In-Source Fragmentation by High-Resolution Mass Spectrometry.
Xiaotu LiuQingqing LvXin SongYukun ChenLei ZhaoMeilin YanBin HuDa ChenPublished in: Analytical chemistry (2023)
Bisphenol chemicals (BPs) represent a complexity of halogenated and nonhalogenated substances sharing a common structure of two phenol functionalities, some of which exhibit ubiquitous environmental distributions and endocrine-disrupting activities. However, environmental monitoring of complex BP-like chemicals has faced analytical challenges arising from the lack of commercially available reference standards and efficient screening strategies. In the present study, we developed a strategy based on dansyl chloride (DnsCl) derivatization in combination with in-source fragmentation (D-ISF) during high-resolution mass spectrometry analysis to screen for bisphenol chemicals in complex environmental samples. The strategy contains three steps, including DnsCl derivatization to enhance the detection sensitivity by one to more than four orders of magnitude, in-source fragmentation to produce characteristic loss of 234.0589, 63.9619, and 298.0208 Da for the identification of DnsCl-derivatized compounds, and data processing and annotation. The D-ISF strategy was further validated and then applied to identify BPs in six types of particular matters as representative environmental samples, including settled dust from an electronic waste dismantling site, homes, offices, and vehicles, and airborne particles from indoor and outdoor environments. A total of six halogenated and fourteen nonhalogenated BPs were identified in the particles, including several chemicals that had rarely or never been identified in environmental samples. Our strategy offers a powerful tool for the environmental monitoring of bisphenol chemicals and assessment of human exposure risks.
Keyphrases
- high resolution mass spectrometry
- human health
- liquid chromatography
- life cycle
- gas chromatography
- ultra high performance liquid chromatography
- risk assessment
- mass spectrometry
- tandem mass spectrometry
- particulate matter
- endothelial cells
- liquid chromatography tandem mass spectrometry
- social media
- drinking water
- simultaneous determination
- machine learning
- electronic health record
- health risk
- rna seq
- quantum dots
- municipal solid waste
- health information
- induced pluripotent stem cells