In vitro metabolic studies and machine learning analysis of mass spectrometry data: A dual strategy for differentiating alpha-pyrrolidinohexiophenone (α-PHP) and alpha-pyrrolidinoisohexanophenone (α-PiHP) in urine analysis

Synthetic cathinones are some of the most prevalent new psychoactive substances (NPSs) globally, with alpha-pyrrolidinoisohexanophenone (α-PiHP) being particularly noted for its widespread use in the United States, Europe, and Taiwan. However, the analysis of isomeric NPSs such as α-PiHP and alpha-p...

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Bibliographic Details
Published in:Forensic science international 2024-08, Vol.361, p.112134, Article 112134
Main Authors: Yeh, Ya-Ling, Wen, Che-Yen, Hsieh, Chin-lin, Chang, Yu-Hsiang, Wang, Sheng-Meng
Format: Article
Language:English
Subjects:
Accuracy
Alkaloids - metabolism
Alkaloids - urine
Chromatography
Chromatography, Liquid
Classification
Europe
Feature selection
forensic sciences
Humans
Hydroxylation
in vitro metabolic study
In vitro methods and tests
In Vitro Techniques
Incubation
Isomer
Isomerism
Isomers
Ketones
Learning algorithms
Liquid chromatography
liver microsomes
Low concentrations
Machine Learning
Machine learning analysis
Mass spectra
Mass spectrometry
Mass Spectrometry - methods
Mass spectroscopy
Metabolism
Metabolites
Microsomes
Microsomes, Liver - metabolism
New psychoactive substance
principal component analysis
Principal components analysis
Psychotropic drugs
Psychotropic Drugs - metabolism
Psychotropic Drugs - urine
Pyrrolidines - urine
Quadrupoles
Regression analysis
Retention
Scientific imaging
Sodium
Synthetic cathinone
Taiwan
Tandem Mass Spectrometry
urinalysis
Urine
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Summary:Synthetic cathinones are some of the most prevalent new psychoactive substances (NPSs) globally, with alpha-pyrrolidinoisohexanophenone (α-PiHP) being particularly noted for its widespread use in the United States, Europe, and Taiwan. However, the analysis of isomeric NPSs such as α-PiHP and alpha-pyrrolidinohexiophenone (α-PHP) is challenging owing to similarities in their retention times and mass spectra. This study proposes a dual strategy based on in vitro metabolic experiments and machine learning-based classification modelling for differentiating α-PHP and α-PiHP in urine samples: (1) in vitro metabolic experiments using pooled human liver microsomes and liquid chromatography tandem quadrupole time-of-flight mass spectrometry (LC-QTOF-MS) were conducted to identify the key metabolites of α-PHP and α-PiHP from the high-resolution MS/MS spectra. After 5 h incubation, 71.4 % of α-PHP and 64.7 % of α-PiHP remained unmetabolised. Nine phase I metabolites were identified for each compound, including primary β-ketone reduction (M1) metabolites. Comparing the metabolites and retention times confirmed the efficacy of in vitro metabolic experiments for differentiating NPS isomers. Subsequently, analysis of seven real urine samples revealed the presence for various metabolites, including M1, that could be used as suitable detection markers at low concentrations. The aliphatic hydroxylation (M2) metabolite peak counts and metabolite retention times were used to determine α-PiHP use. (2) Classification models for the parent compounds and M1 metabolites were developed using principal component analysis for feature extraction and logistic regression for classification. The training and test sets were devised from the spectra of standard samples or supernatants from in vitro metabolism experiments with different incubation times. Both models had classification accuracies of 100 % and accurately identified α-PiHP and its M1 metabolite in seven real urine samples. The proposed methodology effectively distinguished between such isomers and confirmed their presence at low concentrations. Overall, this study introduces a novel concept that addresses the complexities in analysing isomeric NPSs and suggests a path towards enhancing the accuracy and reliability of NPS detection. [Display omitted] •Challenges in analyzing isomeric NPS samples.•Duel strategies are proposed for identifying α-PHP and α-PiHP in urine samples.•Key metabolites were identified using LC-QTOF-MS spec
ISSN:0379-0738
1872-6283
1872-6283
DOI:10.1016/j.forsciint.2024.112134