Evaluation of portable gas chromatography-mass spectrometry (GC-MS) for the analysis of fentanyl, fentanyl analogs, and other synthetic opioids.

Potent synthetic opioids including fentanyl and its analogs are frequently encountered in the field and require detection and identification by first responders to maintain the safety of drug abusers, first responders, health-care providers, and the public at large. Due to the low concentration at which these substances may be encountered and the complicating matrices within which they may be dispersed, the use of portable gas chromatography-mass spectrometry (GC-MS) for their identification in the field offers great potential value. This research established that portable GC-MS is a useful method for the detection and identification of a large number of synthetic opioids, especially fentanyl and its analogs. In this study, 250 synthetic opioids and related substances including 210 fentanyl analogs were analyzed using portable GC-MS. It was concluded that 225 of the 250 (90.0%) opioids analyzed were successfully detected onboard at the time of analysis and identified as either the substance (55.2%) or an analog (34.8%). These outcomes have equivalent benefit for the field analysis of illicit drugs due to both initiating the same subsequent actions by first responders.

Compounds identified in an illicit generic Xanax tablet are the result of a failed synthesis of alprazolam.

Unintended compounds produced by inexperienced clandestine chemists may present a challenge in laboratories tasked with their identification. In March 2020, an anonymously submitted tablet purchased as a generic form of Xanax was analyzed by Erowid's DrugsData.org. The gas chromatography-mass spectrometry (GC-MS) results publicly released online indicated several unidentified compounds due to a lack of database references at that time. Elucidation by our group indicated the presence of several structurally related compounds that were linked to a failed synthesis of alprazolam. For this case study, a published procedure for the synthesis of alprazolam starting with the chloroacetylation of 2-amino-5-chlorobenzophenone was identified as a potential source of this failure. The procedure was reproduced to identify pitfalls of the methodology and examine its possible link to the illicit tablet. Reaction outcomes were analyzed via GC-MS and compared to the tablet submission data. The major compound in this submission, N-(2-benzoyl-4-chlorophenyl)-2-chloroacetamide, along with several related byproducts were successfully reproduced indicating that the tablet contents potentially stem from a failure to synthesize alprazolam.

PEG length and chemical linkage controls polyacridine peptide DNA polyplex pharmacokinetics, biodistribution, metabolic stability and in vivo gene expression.

The pharmacokinetics (PK), biodistribution and metabolism of non-viral gene delivery systems administered systemically are directly related to in vivo efficacy. The magnitude of luciferase expression in the liver of mice following a tail vein dose of a polyplex, composed of 1 µg of pGL3 in complex with a polyethylene glycol (PEG) polyacridine peptide, followed by a delayed hydrodynamic (HD) stimulation (1-9 h), depends on the HD stimulation delay time and the structure of the polyacridine peptide. As demonstrated in the present study, the PEG length and the type of chemical linkage joining PEG to the polyacridine peptide dramatically influence the in vivo gene transfer efficiency. To understand how PEG length, linkage and location influence gene transfer efficiency, detailed PK, biodistribution and HD-stimulated gene expression experiments were performed on polyplexes prepared with an optimized polyacridine peptide modified through a single terminal Cys or Pen (penicillamine) with a PEG chain of average length of 2, 5, 10, 20, or 30 kDa. The chemical linkage was examined by attaching PEG(5 kDa) to the polyacridine peptide through a thiol-thiol (SS), thiol-maleimide (SM), thiol-vinylsulfone (SV), thiol-acetamide (SA), penicillamine-thiol-maleimide (PM) or penicillamine-thiol-thiol (PS). The influence of PEG location was analyzed by attaching PEG(5 kDa) to the polyacridine peptide through a C-terminal, N-terminal, or a middle Cys residue. The results established rapid metabolism of polyplexes containing SV and SA chemical linkages that leads to a decreased polyplex PK half-life and a complete loss of HD-stimulated gene expression at delay times of 5 h. Conversely, polyplexes containing PM, PS, and SM chemical linkages were metabolically stable, allowing robust HD-stimulated expression at delay times up to 5h post-polyplex administration. The location of PEG(5 kDa) within the polyacridine peptide exerted only a minor influence on the gene transfer of polyplexes. However, varying the PEG length from 2, 5, 10, 20, or 30 kDa dramatically altered polyplex biodistribution, with a 30 kDa PEG maximally blocking liver uptake to 13% of dose, while maintaining the ability to mediate HD-stimulated gene expression. The combination of results establishes important relationships between PEGylated polyacridine peptide structure, physical properties, in vivo metabolism, PK and biodistribution resulting in an optimal PEG length and linkage that leads to a robust HD-stimulated gene expression in mice.