High-precision monitoring of and feedback control over drug concentrations in the brains of freely moving rats

Knowledge of drug concentrations in the brains of behaving subjects remains constrained on a number of dimensions, including poor temporal resolution and lack of real-time data. Here, however, we demonstrate the ability of electrochemical aptamer-based sensors to support seconds-resolved, real-time measurements of drug concentrations in the brains of freely moving rats. Specifically, using such sensors, we achieve <4 μM limits of detection and 10-s resolution in the measurement of procaine in the brains of freely moving rats, permitting the determination of the pharmacokinetics and concentration-behavior relations of the drug with high precision for individual subjects. In parallel, we have used closed-loop feedback-controlled drug delivery to hold intracranial procaine levels constant (±10%) for >1.5 hours. These results demonstrate the utility of such sensors in (i) the determination of the site-specific, seconds-resolved neuropharmacokinetics, (ii) enabling the study of individual subject neuropharmacokinetics and concentration-response relations, and (iii) performing high-precision control over intracranial drug levels.

Formulation of antiretroviral nanocrystals and development into a microneedle delivery system for potential treatment of HIV-associated neurocognitive disorder (HAND)

HIV/AIDS remains a major global public health issue. While antiretroviral therapy is effective at reducing the viral load in the blood, up to 50% of those with HIV suffer from some degree of HIV-associated neurocognitive disorder, due to the presence of the blood-brain barrier restricting drugs from crossing into the central nervous system and treating the viral reservoir there. One way to circumvent this is the nose-to-brain pathway. This pathway can also be accessed via a facial intradermal injection. Certain parameters can increase delivery via this route, including using nanoparticles with a positive zeta potential and an effective diameter of 200 nm or less. Microneedle arrays offer a minimally invasive, pain-free alternative to traditional hypodermic injections. This study shows the formulation of nanocrystals of both rilpivirine (RPV) and cabotegravir, followed by incorporation into separate microneedle delivery systems for application to either side of the face. Following an in vivo study in rats, delivery to the brain was seen for both drugs. For RPV, a C_max was seen at 21 days of 619.17 ± 73.32 ng/g, above that of recognised plasma IC90 levels, and potentially therapeutically relevant levels were maintained for 28 days. For CAB, a C_max was seen at 28 days of 478.31 ± 320.86 ng/g, and while below recognised 4IC90 levels, does indicate that therapeutically relevant levels could be achieved by manipulating final microaaray patch size in humans.

Proliferation of Novel Synthetic Opioids in Postmortem Investigations After Core-Structure Scheduling for Fentanyl-Related Substances

ABSTRACT

New generations of novel synthetic opioids (NSOs) have emerged to fill a void in the illicit drug markets left by the decline in popularity of fentanyl analogs subsequent to core-structure scheduling of fentanyl-related substances in the United States and China. These new opioids include members of the 2-benzyl benzimidazole (eg, isotonitazene, metonitazene, N -pyrrolidino etonitazene, protonitazene, etodesnitazene), benzimidazolone (eg, brorphine), and cinnamylpiperazine (eg, AP-238, 2-methyl AP-237) subclasses. Novel synthetic opioids continue to be detected in opioid-related fatal overdoses, demonstrating the harms associated with exposure to these drugs. Between January 2020 and December 2021, 384 casework blood samples were reported by our laboratory to contain 1 or more of the prior listed 8 NSOs. Isotonitazene (n = 144), metonitazene (n = 122), and brorphine (n = 91) were the 3 most prevalent substances, with positivity for isotonitazene and brorphine peaking just before the announcement of emergency scheduling. These NSOs have been documented as significant drivers of drug mortality, and this case series described here highlights the challenges medical examiners and coroners face in staying current with emerging drugs. Challenges include regional differences, rapid turnover, short lifecycles, variable toxicology testing, and difficulty in assessing individual drug toxicity in polydrug cases.

Flualprazolam Blood Concentrations in 197 Forensic Investigation Cases

Flualprazolam is a designer benzodiazepine and novel psychoactive substance that is increasing in prevalence and appearing in forensic investigations. Flualprazolam was quantitatively confirmed in 197 blood samples from medicolegal death investigations and human performance cases reported between August 2019 and February 2020. Drug screening was performed using liquid chromatography-time-of-flight mass spectrometry and quantitative confirmation was performed using liquid chromatography-tandem mass spectrometry. A three-point standard addition protocol was implemented for quantitation in the absence of an available traditionally validated assay. In postmortem cases with quantitative results (n = 167), the mean (±standard deviation [SD]) flualprazolam concentration was 20 (±63) ng/mL, the median concentration was 8.2 ng/mL and the range of concentrations was 2.0-620 ng/mL. Four additional postmortem cases were reported positive (<2.0 ng/mL). In drug impaired driving cases (n = 22), the mean (±SD) flualprazolam concentration was 22 (±18) ng/mL, the median concentration was 14 ng/mL and the range of concentrations was 4.4 to 68 ng/mL. The four remaining cases were of unknown circumstances. This report details the most extensive dataset of flualprazolam intoxication cases reported to date. There was significant overlap in concentrations of flualprazolam between postmortem and DUID cases. Flualprazolam was commonly (83% of the time) found in combination with opioids (e.g. fentanyl). Toxicologists should consider quantitative flualprazolam results in the context of case history, observations, and/or other toxicological findings. Addition of flualprazolam to the scope of drug testing should be considered by all laboratories.

Eutylone Intoxications-An Emerging Synthetic Stimulant in Forensic Investigations

Synthetic stimulants are the largest class of novel psychoactive substances identified each year by forensic laboratories internationally. While hundreds of these drugs appear in drug powders, only a few proliferate in use among forensically relevant populations and eventually emerge in postmortem and clinical investigations. Beta-keto-methylenedioxyamphetamines (i.e., novel psychoactive substances with names ending in "ylone") are currently the most popular subclass of synthetic stimulants. Leading up to its federal scheduling in 2018, N-ethyl pentylone was the most encountered synthetic stimulant. The popularity of N-ethyl pentylone declined once it was scheduled, but it was quickly replaced by eutylone (bk-EBDB), a structurally related analog from the same family. In cases encountered between January 2019 and April 2020, eutylone was quantitatively confirmed in 83 forensic investigations, including postmortem cases and driving under the influence of drugs cases. Matrix types included blood, urine and tissue. Eutylone was identified in cases submitted from 13 states, demonstrating proliferation around the United States; Florida accounted for 60% of the positive cases. The mean concentration of eutylone in postmortem blood was 1,020 ng/mL (standard deviation = ±2,242 ng/mL; median = 110 ng/mL, range = 1.2-11,000 ng/mL, n = 67). The mean concentration of eutylone in blood from driving under the influence of drugs cases was 942 ng/mL (standard deviation = ±1,407 ng/mL; median = 140 ng/mL, range = 17-3,600 ng/mL, n = 7). This report includes cause and manner of death data for 22 postmortem cases. Further analysis of authentic human specimens revealed the presence of three eutylone metabolites, including one unique biomarker and one metabolite in common with butylone. Laboratories should be aware that eutylone may be present in cases of suspected Ecstasy, "Molly" and/or methylenedioxymethamphetamine use, causing or contributing to impairment or death.

Challenges and Strategies for Quantification of Drugs in the Brain: Current Scenario and Future Advancement

The site of action of centrally acting drugs lies inside the brain and therefore, needs to reach the brain to exert their therapeutic efficacy. Discovery and development process of such types of drugs demands their quantification in brain to establish the dose, study pharmacokinetics, pharmacodynamics, and optimize the overall efficacy. Moreover, some drugs of other categories also have potential to cross blood-brain barrier resulting in various adverse events by acting centrally. However, the collection of a matrix to analyze the amount of drugs present in brain is highly challenging. In this review, we have summarized different bioanalytical strategies to quantitate drugs inside the brain. A detailed discussion on various in vivo and in vitro techniques for monitoring drugs inside the brain has been incorporated. In addition, various sampling techniques have been discussed in brief with case studies. Therefore, this review can guide the researcher to choose appropriate bioanalytical techniques for analyzing drugs in brain depending upon the specific need and quantification threshold considering the commonly associated difficulties of the methods.

Isotonitazene Quantitation and Metabolite Discovery in Authentic Forensic Casework

The synthetic opioid landscape continues to change as non-fentanyl-related substances appear in forensic toxicology casework. Among the newest synthetic opioids to emerge is isotonitazene, an analogue of a benzimidazole class of analgesic compounds. Isotonitazene is an active and potent synthetic opioid, but the extent to which this compound is causing toxicity among drug users was previously unknown. This report describes the confirmation and quantitation of isotonitazene in blood, urine and vitreous fluid through standard addition, as well as in vivo metabolic profile determination in drug users. Quantitative analysis was performed using liquid chromatography tandem mass spectrometry (LC–MS/MS), and metabolite discovery was performed using liquid chromatography quadrupole time-of-flight mass spectrometry (LC-QTOF-MS). In total, 18 cases were confirmed positive for isotonitazene, nine of which were previously negative for any opioid. The average isotonitazene concentration in blood was 2.2 ± 2.1 ng/mL (median 1.75 ng/mL, range 0.4–9.5 ng/mL), and the average isotonitazene concentration in urine was 2.4 ± 1.4 ng/mL (median 2.7 ng/mL, range 0.6–4.0 ng/mL). The lowest concentration of isotonitazene in blood was 0.4 ng/mL (two cases) with no other opioids present; findings in death investigations. Four metabolites of isotonitazene were detected in vivo. N- and O-dealkylation products were determined to be the most prominent urinary biomarkers, while 5-amino-isotonitazene was identified in most blood samples. The prevalence and popularity of isotonitazene continue to increase in the United States in early 2020. Toxicologists, medical examiners and coroners should be aware of novel opioids outside the standard scope of testing, especially in medicolegal death investigations. Forensic scientists should add isotonitazene to testing procedures, and public health officials should counsel about potent new drugs and the dangers of opioid use.

Fatality Following Ingestion of Tetrahydrofuranylfentanyl, U-49900 and Methoxy-Phencyclidine

Novel psychoactive substances (NPS), and specifically novel opioids, continue to cause adverse events, including death, within drug-using populations. As the number of opioid-related overdoses continues to increase, laboratories have identified the emergence of new fentanyl analogues and other synthetic opioid-related drugs. Tetrahydrofuranylfentanyl (THFF) has been identified in Europe and the United States as an emerging novel opioid, causing death in at least 15 drug-using individuals to date. THFF is structurally similar to furanylfentanyl, a previously characterized novel opioid responsible for numerous adverse events, including death. In this case report, THFF, U-49900 and methoxy-phencyclidine were identified in postmortem blood and urine specimens collected after a suspected overdose. As part of the death investigation, an unknown substance was collected from the scene and analytically confirmed as THFF and U-49900. To further assist laboratories in identifying THFF ingestion, metabolic profiling was conducted using pooled human liver microsomes. Characterized metabolites were then confirmed in the specimens collected during this investigation. In total, seven metabolites were identified for THFF, most notably THF-norfentanyl and hydroxyl-THFF. THF-norfentanyl provides utility as a biomarker because it is a unique metabolite of THFF. 4-Anilino-N-phenethylpiperidine (4-ANPP) and its metabolite, hydroxyl-4-ANPP, were identified in microsomal incubations and collected specimens, but usefulness as biomarkers is limited due to commonality between other fentanyl analogues and co-ingestion as a synthesis precursor. To our knowledge, this case report is the first to document a fatality after ingestion of THFF and U-49900 in the United States.