Critical Assessment of the Chemical Space Covered by LC–HRMS Non-Targeted Analysis

Hulleman, Tobias; Turkina, Viktoriia; O’Brien, Jake W.; Chojnacka, Aleksandra; Thomas, Kevin V.; Samanipour, Saer

doi:10.1021/acs.est.3c03606

Cited by 18 publications

(24 citation statements)

References 86 publications

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“…156 The analyst is also cautioned that no single instrumental method is capable of detecting all chemical compounds and that each step of the analysis could remove compounds present in the sample. 157 , 158 This is particularly relevant when a large suspect list consists of compounds with a wide range of properties. For example, an instrumental method suitable for the analysis of anionic PFAS may not be appropriate for emerging brominated flame retardants.…”

Section: Advances In the Detection And Analysis Of Ecsmentioning

confidence: 99%

Emerging contaminants: A One Health perspective

Wang,

Xiang,

Sze-Yin Leung

et al. 2024

The Innovation

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Section: Advances In the Detection And Analysis Of Ecsmentioning

confidence: 99%

Emerging contaminants: A One Health perspective

Wang,

Xiang,

Sze-Yin Leung

et al. 2024

The Innovation

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“…In practical applications of EDA, the bioactive fractions exhibit reduced complexity compared to the unfractionated solution but still retain a large number of compound features. The improvement of detection capabilities, such as the use of HRMS, will further increase the number of chemical features detected, ultimately leading to the identification of key toxicants like a needle in a haystack. , In addition, the core idea of toxicant identification and validation is to elucidate the relationship between potential key toxicants and their effects; however, insufficient evidence and poorly interpreted toxic contributions remain challenging, leading to failure in EDA. Accordingly, efficiently identifying and validating potential key toxicants in the unfractionated solution and active fractions have become critical barriers to a breakthrough in high-throughput and high-efficiency EDA.…”

Section: Streamlined Toxicant Identification and Validationmentioning

confidence: 99%

High-Efficiency Effect-Directed Analysis Leveraging Five High Level Advancements: A Critical Review

Liu,

Xiang,

Song

et al. 2024

Environ. Sci. Technol.

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Organic contaminants are ubiquitous in the environment, with mounting evidence unequivocally connecting them to aquatic toxicity, illness, and increased mortality, underscoring their substantial impacts on ecological security and environmental health. The intricate composition of sample mixtures and uncertain physicochemical features of potential toxic substances pose challenges to identify key toxicants in environmental samples. Effect-directed analysis (EDA), establishing a connection between key toxicants found in environmental samples and associated hazards, enables the identification of toxicants that can streamline research efforts and inform management action. Nevertheless, the advancement of EDA is constrained by the following factors: inadequate extraction and fractionation of environmental samples, limited bioassay endpoints and unknown linkage to higher order impacts, limited coverage of chemical analysis (i.e., high-resolution mass spectrometry, HRMS), and lacking effective linkage between bioassays and chemical analysis. This review proposes five key advancements to enhance the efficiency of EDA in addressing these challenges: (1) multiple adsorbents for comprehensive coverage of chemical extraction, (2) high-resolution microfractionation and multidimensional fractionation for refined fractionation, (3) robust in vivo/vitro bioassays and omics, (4) high-performance configurations for HRMS analysis, and (5) chemical-, data-, and knowledge-driven approaches for streamlined toxicant identification and validation. We envision that future EDA will integrate big data and artificial intelligence based on the development of quantitative omics, cutting-edge multidimensional microfractionation, and ultraperformance MS to identify environmental hazard factors, serving for broader environmental governance.

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“…However, contemporary scientific methods shed light on a more complex reality, leading to awareness that humans are exposed to a diverse mixture of chemicals. Fortunately, the advent of nontarget liquid chromatography high-resolution mass spectrometry (LC/ESI/HRMS) has enabled the simultaneous detection of numerous chemicals within real-world mixtures. − Despite this progress, only a fraction (up to 5%) of chemicals that humans are exposed to are unequivocally identified, − and information regarding the toxicity of identified chemicals is either insufficient or entirely absent . Therefore, significant gaps persist in the evaluation of the toxic effects associated with these detected chemicals.…”

Section: Introductionmentioning

confidence: 99%

Predicting the Activity of Unidentified Chemicals in Complementary Bioassays from the HRMS Data to Pinpoint Potential Endocrine Disruptors

Rahu,

Kull,

Kruve

2024

J. Chem. Inf. Model.

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The majority of chemicals detected via nontarget liquid chromatography high-resolution mass spectrometry (HRMS) in environmental samples remain unidentified, challenging the capability of existing machine learning models to pinpoint potential endocrine disruptors (EDs). Here, we predict the activity of unidentified chemicals across 12 bioassays related to EDs within the Tox21 10K dataset. Single-and multi-output models, utilizing various machine learning algorithms and molecular fingerprint features as an input, were trained for this purpose. To evaluate the models under near real-world conditions, Monte Carlo sampling was implemented for the first time. This technique enables the use of probabilistic fingerprint features derived from the experimental HRMS data with SIRIUS+CSI:FingerID as an input for models trained on true binary fingerprint features. Depending on the bioassay, the lowest false-positive rate at 90% recall ranged from 0.251 (sr.mmp, mitochondrial membrane potential) to 0.824 (nr.ar, androgen receptor), which is consistent with the trends observed in the models' performances submitted for the Tox21 Data Challenge. These findings underscore the informativeness of fingerprint features that can be compiled from HRMS in predicting the endocrine-disrupting activity. Moreover, an in-depth SHapley Additive exPlanations analysis unveiled the models' ability to pinpoint structural patterns linked to the modes of action of active chemicals. Despite the superior performance of the single-output models compared to that of the multi-output models, the latter's potential cannot be disregarded for similar tasks in the field of in silico toxicology. This study presents a significant advancement in identifying potentially toxic chemicals within complex mixtures without unambiguous identification and effectively reducing the workload for postprocessing by up to 75% in nontarget HRMS.

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Critical Assessment of the Chemical Space Covered by LC–HRMS Non-Targeted Analysis

Cited by 18 publications

References 86 publications

Emerging contaminants: A One Health perspective

Emerging contaminants: A One Health perspective

High-Efficiency Effect-Directed Analysis Leveraging Five High Level Advancements: A Critical Review

Predicting the Activity of Unidentified Chemicals in Complementary Bioassays from the HRMS Data to Pinpoint Potential Endocrine Disruptors

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