Rapid Identification of Etomidate and Its Structural Analogues Based on Surface-Enhanced Raman Spectroscopy and Machine Learning

doi:10.12116/j.issn.1004-5619.2025.350703

Abstract

Abstract:

Objective To obtain differential spectral characteristics of etomidate and its structural analogues, and to establish a rapid identification method using surface-enhanced Raman spectroscopy （SERS） combined with machine learning algorithms for distinguishing etomidate and its analogues. Methods Silver nanoparticles （AgNPs） were used as the SERS substrate to collect SERS spectra of etomidate, metomidate, propoxate, and isopropoxate at two concentrations of 1×10^-4 and 1×10^-5 mol/L. SERS spectra were also obtained from blood and urine samples containing 1×10^-5 mol/L of etomidate, metomidate, propoxate, and isopropoxate, as well as from confiscated e-cigarette oil containing etomidate. Uniform manifold approximation and projection （UMAP） was employed for nonlinear dimensiona-lity reduction and visualization, and a classification model based on the XGBoost algorithm was constructed to enable discriminant analysis of these four structurally highly similar compounds. Results Minor characteristic peak shifts （5-3 cm^-1） were identified in the range of 1 398-811 cm^-1. Qualitative identification of the compounds in serum, urine and e-cigarette oil samples was achieved without pretreatment. After UMAP dimensionality reduction, distinct clustering separation among different substances was observed. The XGBoost model achieved 100% classification accuracy on the test set. Feature weight analysis revealed that C-N stretching vibration （841 cm^-1）, C=O stretching vibration （1 367 cm^-1）, and C-O-C asymmetric vibration （1 049 cm^-1） were the key spectral bands for discrimination. Conclusion The combination of SERS and machine learning can effectively amplify subtle differences in molecular structures, enabling rapid and accurate identification of etomidate and its analogues. This approach is suitable for on-site rapid screening in forensic toxicology.

Key words: forensic medicine, toxicological analysis, etomidate, structural analogues, silver nanoparticles （AgNPs）, surface-enhanced Raman spectroscopy （SERS）, machine learning, rapid screening

CLC Number:

Zi-wen GUO, Tian-yu QIU, Yue CAO. Rapid Identification of Etomidate and Its Structural Analogues Based on Surface-Enhanced Raman Spectroscopy and Machine Learning[J]. Journal of Forensic Medicine, 2025, 41(4): 364-370.

Figures/Tables 8

Fig. 1 Molecular structure diagrams of etomidate，metomidate， propoxate and isopropoxate

Fig. 2 Material characterization of AgNPs

Fig. 3 SERS spectra of etomidate and its structuralanalogues at 1×10-4 mol/L and 1×10-5 mol/L

Fig. 4 SERS spectra of etomidate andits structural analogues in serum

Fig. 5 SERS quantitative curves of etomidate and its structural analogues at 1 005 cm-1

Fig. 6 SERS spectra of etomidate and its structural analogues in spiked artificial urine and e-cigarette oil samples

Fig. 7 Dimensionality reduction visualization diagrams of the SERS spectral data for etomidate andits structural analogues at 1×10-4 mol/L and 1×10-5 mol/L

Fig. 8 Machine learning classification results of etomidate and its structural analogues

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