Emma Palm scite author profile

Non-targeted screening (NTS) with reversed phase liquid chromatography electrospray ionization high resolution mass spectrometry (LC/ESI/HRMS) is increasingly employed as an alternative to targeted analysis; however, it is not possible to quantify all compounds found in a sample with analytical standards. As an alternative, semi-quantification strategies are, or at least should be, used to estimate the concentrations of the unknown compounds before final decision making. All steps in the analytical chain, from sample preparation to ionization conditions and data processing can influence the signals obtained, and thus the estimated concentrations. Therefore, each step needs to be considered carefully. Generally, less is more when it comes to choosing sample preparation as well as chromatographic and ionization conditions in NTS. By combining the positive and negative ionization mode, the performance of NTS can be improved, since different compounds ionize better in one or the other mode. Furthermore, NTS gives opportunities for retrospective analysis. In this tutorial, strategies for semi-quantification are described, sources potentially decreasing the signals are identified and possibilities to improve NTS are discussed. Additionally, examples of retrospective analysis are presented. Finally, we present a checklist for carrying out semi-quantitative NTS.

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Mandibular tori size is related to obstructive sleep apnea and treatment success with an oral appliance

Palm

Franklin

Marklund

2013

Sleep Breath

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Machine Learning for Absolute Quantification of Unidentified Compounds in Non-Targeted LC/HRMS

Palm

Kruve

2022

Molecules

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LC/ESI/HRMS is increasingly employed for monitoring chemical pollutants in water samples, with non-targeted analysis becoming more common. Unfortunately, due to the lack of analytical standards, non-targeted analysis is mostly qualitative. To remedy this, models have been developed to evaluate the response of compounds from their structure, which can then be used for quantification in non-targeted analysis. Still, these models rely on tentatively known structures while for most detected compounds, a list of structural candidates, or sometimes only exact mass and retention time are identified. In this study, a quantification approach was developed, where LC/ESI/HRMS descriptors are used for quantification of compounds even if the structure is unknown. The approach was developed based on 92 compounds analyzed in parallel in both positive and negative ESI mode with mobile phases at pH 2.7, 8.0, and 10.0. The developed approach was compared with two baseline approaches— one assuming equal response factors for all compounds and one using the response factor of the closest eluting standard. The former gave a mean prediction error of a factor of 29, while the latter gave a mean prediction error of a factor of 1300. In the machine learning-based quantification approach developed here, the corresponding prediction error was a factor of 10. Furthermore, the approach was validated by analyzing two blind samples containing 48 compounds spiked into tap water and ultrapure water. The obtained mean prediction error was lower than a factor of 6.0 for both samples. The errors were found to be comparable to approaches using structural information.

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MultiConditionRT: Predicting liquid chromatography retention time for emerging contaminants for a wide range of eluent compositions and stationary phases

Souihi

Mohai

Palm

et al. 2022

Journal of Chromatography A

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Formation and Properties of Sub-Image and Latent Image Silver Specks. Part IV. The Formation of Silver Specks—A Process of Nucleation and Phase Formation^*

Moisar¹,

Granzer²,

Dautrich³

et al. 1980

The Journal of Photographic Science

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Emma Palm

Guide to Semi-Quantitative Non-Targeted Screening Using LC/ESI/HRMS

Mandibular tori size is related to obstructive sleep apnea and treatment success with an oral appliance

Machine Learning for Absolute Quantification of Unidentified Compounds in Non-Targeted LC/HRMS

MultiConditionRT: Predicting liquid chromatography retention time for emerging contaminants for a wide range of eluent compositions and stationary phases

Formation and Properties of Sub-Image and Latent Image Silver Specks. Part IV. The Formation of Silver Specks—A Process of Nucleation and Phase Formation^*

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Emma Palm

Guide to Semi-Quantitative Non-Targeted Screening Using LC/ESI/HRMS

Mandibular tori size is related to obstructive sleep apnea and treatment success with an oral appliance

Machine Learning for Absolute Quantification of Unidentified Compounds in Non-Targeted LC/HRMS

MultiConditionRT: Predicting liquid chromatography retention time for emerging contaminants for a wide range of eluent compositions and stationary phases

Formation and Properties of Sub-Image and Latent Image Silver Specks. Part IV. The Formation of Silver Specks—A Process of Nucleation and Phase Formation*

Contact Info

Product

Resources

About

Formation and Properties of Sub-Image and Latent Image Silver Specks. Part IV. The Formation of Silver Specks—A Process of Nucleation and Phase Formation^*