Utilization of Machine Learning for the Differentiation of Positional NPS Isomers with Direct Analysis in Real Time Mass Spectrometry

Bonetti, Jennifer; Samanipour, Saer; Asten, Arian C. van

doi:10.1021/acs.analchem.1c04985

Cited by 19 publications

(9 citation statements)

References 42 publications

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“…A natural extension to this study is to characterize measurement diversity while leveraging replicate measurements per fentanyl analog. Having replicate measurements allow us to use a broader variety of mathematical tools [39][40][41][42], including machine learning [43,44]. However, it is worth noting that replicate measurements with ambient ionization mass spectrometry techniques, like DART-MS, may introduce additional measurement uncertainty that hinder its discriminatory power [42].…”

Section: Re Sults and Discussionmentioning

confidence: 99%

On the challenge of unambiguous identification of fentanyl analogs: Exploring measurement diversity using standard reference mass spectral libraries

Moorthy

Erisman

Kearsley

et al. 2023

Journal of Forensic Sciences

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Fentanyl analogs are a class of designer drugs that are particularly challenging to unambiguously identify due to the mass spectral and retention time similarities of unique compounds. In this paper, we use agglomerative hierarchical clustering to explore the measurement diversity of fentanyl analogs and better understand the challenge of unambiguous identifications using analytical techniques traditionally available to drug chemists. We consider four measurements in particular: gas chromatography retention indices, electron ionization mass spectra, electrospray ionization tandem mass spectra, and direct analysis in real time mass spectra. Our analysis demonstrates how simultaneously considering data from multiple measurement techniques increases the observable measurement diversity of fentanyl analogs, which can reduce identification ambiguity. This paper further supports the use of multiple analytical techniques to identify fentanyl analogs (among other substances), as is recommended by the Scientific Working Group for the Analysis of Seized Drugs (SWGDRUG).

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Section: Re Sults and Discussionmentioning

confidence: 99%

On the challenge of unambiguous identification of fentanyl analogs: Exploring measurement diversity using standard reference mass spectral libraries

Moorthy

Erisman

Kearsley

et al. 2023

Journal of Forensic Sciences

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“…Sigman and Clark examined the two-dimensional cross-correlations in replicate spectra of high explosives, but the cross-correlations were examined as a function of a deliberate perturbation, i.e., differing collision energies, and the cross-correlations were not used to support compound identification, unlike the present work. In mass spectrometry applications, principal component analysis (PCA) has been used in two main ways: (1) to resolve or deconvolute mass spectra of mixtures, ,,, and (2) to relate a spectrum to other classes or structures within a database. ,− The latter approach has also been used in conjunction with discriminant analysis and binary classification algorithms to enable the classification of spectra to known identities. − Finally, machine learning and artificial intelligence methods have existed since the early 1970s, and they continue to be explored as methods to both identify known compounds in a library and to propose structures for compounds that are not in a library. ,,,,− Whereas the predictive power of sophisticated computational techniques is likely to continually advance, very few of the articles described so far tackle the difficult problem of discriminating between spectrally similar compounds collected on different instruments and without reference spectra from those instruments.…”

Section: Multivariate Methodsmentioning

confidence: 99%

Expert Algorithm for Substance Identification Using Mass Spectrometry: Statistical Foundations in Unimolecular Reaction Rate Theory

Jackson

Mehnert

Davidson

et al. 2023

J. Am. Soc. Mass Spectrom.

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This study aims to resolve one of the longest-standing problems in mass spectrometry, which is how to accurately identify an organic substance from its mass spectrum when a spectrum of the suspected substance has not been analyzed contemporaneously on the same instrument. Part one of this two-part report describes how Rice−Ramsperger−Kassel−Marcus (RRKM) theory predicts that many branching ratios in replicate electron−ionization mass spectra will provide approximately linear correlations when analysis conditions change within or between instruments. Here, proof-of-concept general linear modeling is based on the 20 most abundant fragments in a database of 128 training spectra of cocaine collected over 6 months in an operational crime laboratory. The statistical validity of the approach is confirmed through both analysis of variance (ANOVA) of the regression models and assessment of the distributions of the residuals of the models. General linear modeling models typically explain more than 90% of the variance in normalized abundances. When the linear models from the training set are applied to 175 additional known positive cocaine spectra from more than 20 different laboratories, the linear models enabled ion abundances to be predicted with an accuracy of <2% relative to the base peak, even though the measured abundances vary by more than 30%. The same models were also applied to 716 known negative spectra, including the diastereomers of cocaine: allococaine, pseudococaine, and pseudoallococaine, and the residual errors were larger for the known negatives than for known positives. The second part of the manuscript describes how general linear regression modeling can serve as the basis for binary classification and reliable identification of cocaine from its diastereomers and all other known negatives.

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“…to differentiate isomeric novel psychoactive substances, 35 and for the analysis of psychoactive plant materials. 36 Whereas ambient ionization has a clear application in the identification of bulk and trace illicit substances, the ability to rapidly screen biological samples, such as blood and urine, is also of great interest.…”

Section: Forensics and Securitymentioning

confidence: 99%

Applications of ambient ionization mass spectrometry in 2022: An annual review

Rankin‐Turner

Sears

Heaney

2023

Analytical Science Advances

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The development of ambient ionization mass spectrometry (AIMS) has transformed analytical science, providing the means of performing rapid analysis of samples in their native state, both in and out of the laboratory. The capacity to eliminate sample preparation and pre‐MS separation techniques, leading to true real‐time analysis, has led to AIMS naturally gaining a broad interest across the scientific community. Since the introduction of the first AIMS techniques in the mid‐2000s, the field has exploded with dozens of novel ion sources, an array of intriguing applications, and an evident growing interest across diverse areas of study. As the field continues to surge forward each year, ambient ionization techniques are increasingly becoming commonplace in laboratories around the world. This annual review provides an overview of AIMS techniques and applications throughout 2022, with a specific focus on some of the major fields of research, including forensic science, disease diagnostics, pharmaceuticals and food sciences. New techniques and methods are introduced, demonstrating the unwavering drive of the analytical community to further advance this exciting field and push the boundaries of what analytical chemistry can achieve.

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Utilization of Machine Learning for the Differentiation of Positional NPS Isomers with Direct Analysis in Real Time Mass Spectrometry

Cited by 19 publications

References 42 publications

On the challenge of unambiguous identification of fentanyl analogs: Exploring measurement diversity using standard reference mass spectral libraries

On the challenge of unambiguous identification of fentanyl analogs: Exploring measurement diversity using standard reference mass spectral libraries

Expert Algorithm for Substance Identification Using Mass Spectrometry: Statistical Foundations in Unimolecular Reaction Rate Theory

Applications of ambient ionization mass spectrometry in 2022: An annual review

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