Closing the Organofluorine Mass Balance in Marine Mammals Using Suspect Screening and Machine Learning-Based Quantification.
Melanie Z LauriaHelen SepmanThomas LedbetterMerle M PlassmannAnna M RoosMalene SimonJonathan P BenskinAnneli KruvePublished in: Environmental science & technology (2024)
High-resolution mass spectrometry (HRMS)-based suspect and nontarget screening has identified a growing number of novel per- and polyfluoroalkyl substances (PFASs) in the environment. However, without analytical standards, the fraction of overall PFAS exposure accounted for by these suspects remains ambiguous. Fortunately, recent developments in ionization efficiency ( IE ) prediction using machine learning offer the possibility to quantify suspects lacking analytical standards. In the present work, a gradient boosted tree-based model for predicting log IE in negative mode was trained and then validated using 33 PFAS standards. The root-mean-square errors were 0.79 (for the entire test set) and 0.29 (for the 7 PFASs in the test set) log IE units. Thereafter, the model was applied to samples of liver from pilot whales (n = 5; East Greenland) and white beaked dolphins (n = 5, West Greenland; n = 3, Sweden) which contained a significant fraction (up to 70%) of unidentified organofluorine and 35 unquantified suspect PFASs (confidence level 2-4). IE -based quantification reduced the fraction of unidentified extractable organofluorine to 0-27%, demonstrating the utility of the method for closing the fluorine mass balance in the absence of analytical standards.
Keyphrases
- high resolution mass spectrometry
- liquid chromatography
- machine learning
- mass spectrometry
- ultra high performance liquid chromatography
- gas chromatography
- tandem mass spectrometry
- randomized controlled trial
- study protocol
- emergency department
- clinical trial
- patient safety
- resistance training
- quality improvement