Establishing performance metrics for quantitative non-targeted analysis: a demonstration using per- and polyfluoroalkyl substances

Non-targeted analysis (NTA) is an increasingly popular technique for characterizing undefined chemical analytes. Generating quantitative NTA (qNTA) concentration estimates requires the use of training data from calibration “surrogates,” which can yield diminished predictive performance relative to t...

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Bibliographic Details
Published in:Analytical and bioanalytical chemistry 2024-02, Vol.416 (5), p.1249-1267
Main Authors: Pu, Shirley, McCord, James P., Bangma, Jacqueline, Sobus, Jon R.
Format: Article
Language:English
Subjects:
Accuracy
Analytical Chemistry
Biochemistry
Calibration
Characterization and Evaluation of Materials
chemical species
Chemistry
Chemistry and Materials Science
Confidence intervals
Contaminants
Food Science
Laboratory Medicine
Monitoring/Environmental Analysis
Perfluoroalkyl & polyfluoroalkyl substances
Perfluorochemicals
Performance evaluation
Performance measurement
Performance prediction
Reliability
Research Paper
subclass
Uncertainty
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Summary:Non-targeted analysis (NTA) is an increasingly popular technique for characterizing undefined chemical analytes. Generating quantitative NTA (qNTA) concentration estimates requires the use of training data from calibration “surrogates,” which can yield diminished predictive performance relative to targeted analysis. To evaluate performance differences between targeted and qNTA approaches, we defined new metrics that convey predictive accuracy, uncertainty (using 95% inverse confidence intervals), and reliability (the extent to which confidence intervals contain true values). We calculated and examined these newly defined metrics across five quantitative approaches applied to a mixture of 29 per- and polyfluoroalkyl substances (PFAS). The quantitative approaches spanned a traditional targeted design using chemical-specific calibration curves to a generalizable qNTA design using bootstrap-sampled calibration values from “global” chemical surrogates. As expected, the targeted approaches performed best, with major benefits realized from matched calibration curves and internal standard correction. In comparison to the benchmark targeted approach, the most generalizable qNTA approach (using “global” surrogates) showed a decrease in accuracy by a factor of ~4, an increase in uncertainty by a factor of ~1000, and a decrease in reliability by ~5%, on average. Using “expert-selected” surrogates ( n  = 3) instead of “global” surrogates ( n  = 25) for qNTA yielded improvements in predictive accuracy (by ~1.5×) and uncertainty (by ~70×) but at the cost of further-reduced reliability (by ~5%). Overall, our results illustrate the utility of qNTA approaches for a subclass of emerging contaminants and present a framework on which to develop new approaches for more complex use cases. Graphical Abstract
ISSN:1618-2642
1618-2650
DOI:10.1007/s00216-023-05117-4