The Harris County Institute of Forensic Sciences recently added brain to its fentanyl analog testing method for 14 analogs (fluoroisobutyryl fentanyl, acetyl fentanyl, acryl fentanyl, alfentanil, butyryl fentanyl, carfentanil, fentanyl, para-fluorofentanyl, furanyl fentanyl, methoxyacetyl fentanyl, norcarfentanil, norfentanyl, sufentanil, and valeryl fentanyl) and 3 U-series drugs (U-47700, U-48800, and U-49900). Brain is a protected and isolated organ with lower metabolic activity than other tissues, which can assist in interpreting results and preserving parent drug. Limited publications testing brain samples for fentanyl and fentanyl analogs exist and none describe homogenate stability for these analytes. Validation of the solid phase extraction and liquid chromatography tandem mass spectrometry method followed the ASB 036 Standard Practices for Method Validation in Forensic Toxicology and included limit of detection, limit of quantification, calibration model, bias and precision, ionization suppression/enhancement, interferences, carryover, processed sample stability, and dilution integrity. Carfentanil, fentanyl, furanyl fentanyl and methoxyacetyl fentanyl met quantitative bias and precision acceptance criteria in brain. To assess homogenate stability, brain homogenates (both unpreserved and preserved with 1% sodium fluoride) were fortified with 50 ng/mL of analyte, stored at room temperature (∼20°C), refrigerated (2–8°C), or frozen (∼−20°C), and analyzed in triplicate over a 90-day period. Analytes were considered stable if analyte/internal standard response ratio was within ± 20% of Day 0 and chromatographic peaks met qualitative acceptance criteria. Frozen brain homogenates could be stored for up to 90 days and withstood three freeze/thaw cycles for acetyl fentanyl, alfentanil, fentanyl, para-fluorofentanyl, FIBF, methoxyacetyl fentanyl, and norfentanyl. Brain homogenate stability was improved when frozen and was not impacted by the addition of 1% sodium fluoride. The study herein provides insight into the feasibility of testing brain for fentanyl analogs and their stability under various storage conditions, contributing valuable data to the limited literature on brain toxicology testing.

01 Jul 2025·Forensic Chemistry

Application of the expert algorithm for substance identification (EASI) to the electron ionization (EI) mass spectra of fentanyl isomers and analogs

Author: Jackson, Glen P. ; Adeoye, Alexandra I.

Fentanyl analogs (fentalogs) share many structural and mass spectral similarities that make them difficult to differentiate and accurately identify without chromatog. data.In such situations, the expert algorithm for substance identification (EASI) provides superior classification relative to conventional approaches.Using a database of >57,000 replicate electron-ionization mass spectra of 76 fentalogs from ten laboratories, three challenging sets of isomers were studied in detail.To maximize limits of detection, only the 20 most abundant ions were considered.In each case, 50 % of the data from one laboratory served as the training set.On average, the mean absolute residuals between measured and modeled abundances of known positives were five times smaller using EASI than the consensus approach, which used the means of training sets as the exemplar spectra to which all query spectra were compared.With a conservative threshold of zero false positives, EASI identified isovalerylfentanyl from its two closest isomers with an accuracy of 96.7 %, which was ∼10 % better than the consensus approach.The associated pos. likelihood ratios increased from 366 for the consensus approach to more than 4,200 for EASI.When discriminating isovalerylfentanyl spectra from the other 72 fentalogs, EASI provided errorless results with a pos. likelihood ratio exceeding 50,000.For all 9 fentalogs, EASI outperformed the consensus approach and the use of Mahalanobis distance as a metric for identifying outliers.In the absence of retention time information, EASI improves confidence in drug identifications, enables inter-laboratory identifications, and reduces the need for acquiring concomitant spectra of standards

01 May 2024·Analytica chimica acta

Target and suspect screening of psychoactive substances in seizures and oral fluid exploiting retention time prediction and LC-MS/MS analysis

Article

Author: Sabino Napoletano ; Flaminia Vincenti ; Ilenia Bracaglia ; Camilla Montesano ; Martina Croce ; Antonietta Lombardozzi ; Gaia Di Francesco ; Manuel Sergi

BACKGROUND:

Novel psychoactive substances (NPS) are a group of substances, mainly of synthetic origin, characterized by toxicological properties extremely dangerous. The main difficulty in recognizing NPS in seizures and biological samples lies in their dynamic nature, related to the continuous synthesis and introduction on the market of new drugs, often with very similar structures to existing ones. The aim of this study was the creation of a robust and versatile method for the analysis of traditional drugs and NPS in different matrices.

RESULTS:

Both target analysis and suspect screening methodologies were developed. The strategy used for suspect screening allowed to collect data through a scheduled multi reaction monitoring (sMRM) survey which triggered the collection of enhanced product ion (EPI) spectra when a compound met information dependent acquisition (IDA) criteria. The retention time of the different drugs, which was crucial to define the sMRM survey scan parameters, was predicted with a Quantitative Structure Retention (Chromatographic) Relationship (QSRR) model by Multiple Linear Regression. The model was validated through the evaluation of training set predictions, an external validation set and a leave-one out strategy; the results showed that the method fit for its purpose. The target method was validated in oral fluid as a testing matrix, with excellent results in term of recovery, accuracy, precision and matrix effect. Finally, the performances of the suspect method were evaluated by analysing a mixture containing 8 reference standards not included in the initial dataset, as well as seizures and real oral fluid samples. Four NPS were putatively identified in the analysed samples.

SIGNIFICANCE:

The advantage of the proposed approach is the possibility of quantifying 65 classical drugs of abuse and NPS and, at the same time, detect and putatively identify 146 additional drugs in one single LC-MS/MS run. This is an innovative strategy for multi analyte detection and enables detection of low concentrations of drugs in complex biological matrices such as oral fluid. Considering the highly dynamic drug market, a strength of this strategy is that the analytical method can be kept up to date through the addition of new compounds based on the last drug monitoring bodies alerts without the need of authentic standards.

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Indication	Highest Phase	Country/Location	Organization	Date
Analgesia	Preclinical	United States	National Institutes of Health	23 Nov 2020

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