Rapid Determination of Sufentanil in Human Plasma by UHPLC-QqQ-MS-MS

Development of two ultra-sensitive UHPLC-QqQ-MS/MS methods for the simultaneous determination of hydroxyzine and its active metabolite (cetirizine) in human blood: applications to real cases of forensic toxicology

Both postmortem toxicological and medical-forensic examinations are very important in the case of analyzing various types of chemical substances. Hydroxyzine (HZ) is a first-generation antihistamine drug with a sedative effect that disrupts cognitive function and affects the ability to drive motor vehicles. Enzymatic oxidation of the hydroxy-methyl group to the carboxyl group leads to the formation of its main metabolite-cetirizine (CZ). CZ is the active substance of antiallergic drugs. Because it does not cross the BBB (blood-brain barrier) easily, it is less likely to cause drowsiness or affect memory and impair cognitive function. Therefore, in criminal studies, it is often important what medication had been taken by a person involved, e.g., in a car accident, HZ or CZ. The analysis of both antihistamine drugs is challenging, as usually very low concentrations of the compound of interest need to be determined. Thus, an ultra-sensitive UHPLC-QqQ-MS/MS method was developed for simultaneous determination of HZ and CZ in biological fluid samples. The lower limit of quantification (LOQ) for HZ and CZ was calculated as 0.345 and 0.3696 ng/mL, respectively. Together with a reduced sample volume to 200 μL, it makes the developed method suitable for a sensitive multidrug forensic toxicological analysis. Samples were extracted with simple and fast liquid-liquid extraction (ethyl acetate, pH 9). The present method for the determination of HZ and CZ in human blood proved to be simple, fast, selective, and sensitive. The quantification by LC-MS/MS was successfully applied to the samples coming from 28 authentic biological fluids (blood, urine, vitreous humor, bile and stomach content), both antemortem and postmortem. The performed studies confirm that the developed method is characterized by a high extraction efficiency. Its accuracy, reproducibility, simplicity, and selectivity suggest its application in clinical, toxicological, and forensic laboratories.

Opioid Monitoring in Clinical Settings: Strategies and Implications of Tailored Approaches for Therapy

This review emphasises the importance of opioid monitoring in clinical practice and advocates for a personalised approach based on pharmacogenetics. Beyond effectively managing pain, meticulous oversight is required to address concerns about side effects, specially due to opioid-crisis-related abuse and dependence. Various monitoring techniques, along with pharmacogenetic considerations, are critical for personalising treatment and optimising pain relief while reducing misuse and addiction risks. Future perspectives reveal both opportunities and challenges, with advances in analytical technologies holding promise for increasing monitoring efficiency. The integration of pharmacogenetics has the potential to transform pain management by allowing for a precise prediction of drug responses. Nevertheless, challenges such as prominent pharmacogenetic testing and guideline standardisation persist. Collaborative efforts are critical for transforming scientific advances into tangible improvements in patient care. Standardised protocols and interdisciplinary collaboration are required to ensure consistent and evidence-based opioid monitoring. Future research should look into the long-term effects of opioid therapy, as well as the impact of genetic factors on individual responses, to help guide personalised treatment plans and reduce adverse events. Lastly, embracing innovation and collaboration can improve the standard of care in chronic pain management by striking a balance between pain relief and patient safety.

Advances in fentanyl testing

Fentanyl is a synthetic opioid that was approved by the FDA in the late 1960s. In the decades since, non-prescription use of fentanyl, its analogs, and structurally unrelated novel synthetic opioids (NSO) has become a worsening public health crisis. There is a clear need for accessible testing for these substances in biological specimens and in apprehended drugs. Immunoassays for fentanyl in urine are available but their performance is restricted to facilities that hold moderate complexity laboratory licenses. Immunoassays for other matrices such as oral fluid (OF), blood, and meconium have been developed but are not widely available. Point of care tests (POCT), such as lateral flow immunoassays or fentanyl test strips (FTS), are widely available but not approved by the FDA for clinical use. All immunoassays are vulnerable to false positive and false negative results. Immunoassays may or may not be able to detect fentanyl analogs and NSOs. Mass spectrometry (MS) can accurately and reliably measure fentanyl and its major metabolite norfentanyl in urine and oral fluid. MS is available at reference laboratories and large hospitals. Liquid chromatography paired with tandem mass spectrometry (LC-MS/MS) is the most widely used method and has outstanding specificity and sensitivity for fentanyl and norfentanyl. When compared to immunoassays, MS is more expensive, requires more technical skill, and takes longer to result. Newer mass spectrometry methods can measure fentanyl analogs and NSO. Both mass spectrometry assays and immunoassays [in the form of fentanyl test strips (FTS)] have potential use in harm reduction programs.

Novel Applications of Microextraction Techniques Focused on Biological and Forensic Analyses

In recent years, major attention has been focused on microextraction procedures that allow high recovery of target analytes, regardless of the complexity of the sample matrices. The most used techniques included liquid-liquid extraction (LLE), solid-phase extraction (SPE), solid-phase microextraction (SPME), dispersive liquid-liquid microextraction (DLLME), microextraction by packed sorbent (MEPS), and fabric-phase sorptive extraction (FPSE). These techniques manifest a rapid development of sample preparation techniques in different fields, such as biological, environmental, food sciences, natural products, forensic medicine, and toxicology. In the biological and forensic fields, where a wide variety of drugs with different chemical properties are analyzed, the sample preparation is required to make the sample suitable for the instrumental analysis, which often includes gas chromatography (GC) and liquid chromatography (LC) coupled with mass detectors or tandem mass detectors (MS/MS). In this review, we have focused our attention on the biological and forensic application of these innovative procedures, highlighting the major advantages and results that have been accomplished in laboratory and clinical practice.