Sensitive Screening of New Psychoactive Substances in Serum Using Liquid Chromatography-Quadrupole Time-of-Flight Mass Spectrometry.

Analysis of new psychoactive substances (NPS) still poses a challenge for many institutions due to the number of available substances and the constantly changing drug market. Both new and well-known substances keep appearing and disappearing on the market, making it hard to adapt analytical methods in a timely manner. In this study we developed a qualitative screening approach for serum samples by means of liquid chromatography--quadrupole time-of-flight mass spectrometry. Samples were measured in data-dependent auto tandem mass spectrometry mode and identified by fragment spectra comparison, retention time and accurate mass. Approximately 500 NPS, including 195 synthetic cannabinoids, 180 stimulants, 86 hallucinogens, 26 benzodiazepines and 7 others were investigated. Serum samples were fortified to 1 ng/mL and 10 ng/mL concentrations to estimate approximate limits of identification (LOIs). Samples were extracted using solid-phase extraction with non-endcapped C18 material and elution in two consecutive steps. Benzodiazepines were eluted in the first step, while substances of other NPS subclasses were distributed among both extracts. To determine LOIs, both extracts were combined. Ninety-six percent (470/492) of investigated NPS were detected in 10 ng/mL samples and 88% (432/492) were detected in 1 ng/mL samples. Stimulants stood out with higher LOIs, possibly due to instability of certain methcathinone derivatives. However, considering relevant blood concentrations, the method provided sufficient sensitivity for stimulants as well as other NPS subclasses. Data-dependent acquisition was proven to provide high sensitivity and reliability when combined with an information-dependent preferred list, without losing its untargeted operation principle. Summarizing, the developed method fulfilled its purpose as a sensitive untargeted screening for serum samples and allows uncomplicated expansion of the spectral library to include thousands of targets.

Enantioselective Quantification of Amphetamine and Metabolites in Serum Samples: Forensic Evaluation and Estimation of Consumption Time.

In forensic toxicology, amphetamine intoxications represent one of the most common case groups and present difficult questions for toxicologists. Estimating the time of consumption and the current influence of the stimulant is particularly difficult when only total amphetamine concentrations are considered. Stereoselective analysis and the consideration of metabolites can provide valuable information to facilitate interpretation. An enantioselective liquid chromatography-tandem mass spectrometry (LC-MS/MS) method for detection of amphetamine, norephedrine and 4-hydroxyamphetamine was developed. Validation showed satisfactory selectivity, sensitivity, linearity (0.5-250 ng/mL), precision and accuracy for all enantiomers. The method was applied to a collective of 425 forensic serum samples and 30 serum samples from psychiatric inpatients stating their last time of amphetamine consumption. Norephedrine and 4-hydroxyamphetamine were detected more frequently at higher amphetamine concentrations and at lower amphetamine (R)/(S) concentration ratios, possibly indicating recent consumption. Mean (R)/(S) ratio of amphetamine was 1.14, whereas higher ratios (mean 1.36) were found for amphetamine concentrations below 100 ng/mL. The (R)/(S) ratios of psychiatric inpatients significantly correlated with the reported time intervals to last consumption. The use of amphetamine (R)/(S) ratios and the simultaneous detection of metabolites are promising factors that can facilitate estimation of consumption time and current impairment.

Enantioselective determination of plasma protein binding of common amphetamine-type stimulants.

Amphetamine-type stimulants (ATS) like amphetamine ('speed'), methamphetamine ('crystal meth') and 3,4-methylenedioxy-N-methylamphetamine (MDMA, 'ecstasy') represent some of the most frequently abused drugs worldwide. Another less frequently abused ATS is 4-fluoroamphetamine (4-FA). The enantiomers of these four compounds exhibit different pharmacokinetic and pharmacodynamic properties. According to the free drug theory, the pharmacological properties of a substance are dependent on its plasma protein binding (PPB). However, data on PPB of stimulant enantiomers in humans are rare or non-existent. Human plasma samples were spiked with racemic mixtures of the stimulants and subjected to ultrafiltration to extract the unbound fraction. Enantioselective liquid chromatography - tandem mass spectrometry (LC-MS/MS) methods were applied using a chiral Phenomenex® Lux3 µm AMP column. Method validation showed satisfactory selectivity, linearity (0.5 250 ng/mL), accuracy and precision. Enantiomers were quantified before and after ultracentrifugation to determine PPB. For all analytes, low to medium plasma protein binding was found. For (R)-amphetamine a slightly but significantly higher PPB was found compared to the (S)-enantiomer (31.7 % vs 29.0 %). (R)-MDMA also showed only slightly but significantly significantly higher PPB than (S)-MDMA, although the mean difference was negligible (21.6 % vs 21.3 %). For the enantiomers of methamphetamine and 4-FA, no significant differences in PPB were found. In summary, there were no or only minor differences in PBB for the enantiomers of all investigated compounds. The different pharmacological properties of the stimulant enantiomers can therefore not be explained by differences in PPB.

GHB related acids are useful in routine casework of suspected GHB intoxication cases.

GHB related acids (3,4-dihydroxy butyric acid, 2,4-dihydroxy butyric acid and glycolic acid) are produced through oxidative GHB metabolism. These analytes could be potential biomarkers to ensure the diagnosis of a GHB intoxication and even prolong the detection window. Within this study, forensic routine cases were measured to consider the potential of additional gas chromatographic mass spectrometric analysis on these acids. 17 GHB positive real cases (10 serum samples and 7 urine samples) and 40 cases with suspicion of drugging in DFC cases and negative GHB results (21 serum samples and 19 urine samples) were evaluated. Increased GHB related acid concentrations were detected in all serum and most urine samples positive on GHB. In some GHB negative cases, especially in serum samples, concentrations of GHB related acids gave hints that GHB actually was taken. We recommend to use the following cut-offs for a more reliable interpretation of potential GHB intoxication cases: 3,4-OH-BA:>3 mg/L in serum and>50 mg/L in urine; 2,4-OH-BA:>2 mg/L in serum and>25 mg/L in urine; GA:>5 mg/L in serum and>400 mg/L in urine.

Forensic application and evaluation of a commercially available pregabalin immunoassay test in serum on an Olympus AU480.

Misuse of pregabalin and its forensic relevance is steadily increasing. The aim of this study was to evaluate the usability of the commercially available ARKTM Pregabalin II Assay (ARK Diagnostics) for serum analysis of forensic samples. Overall, 156 samples were tested by both the immunoassay and a validated liquid chromatographic-tandem mass spectrometric (LC-MS/MS) method. Sensitivity was 100%, and specificity was 98.7% (n = 79 positive cases confirmed by LC-MS/MS in a range of 380-37,000 ng/mL). A good correlation (R2  = 0.73) could also be shown between quantitative immunoassay and LC-MS/MS results. In conclusion, the assay shows excellent reliability for screening of forensic serum samples.

Chiral Serum Pharmacokinetics of 4-Fluoroamphetamine after Controlled Oral Administration: Can (R)/(S)-Concentration Ratios Help in Interpreting Forensic Cases?

Over the last two decades, misuse of 4-fluoroamphetamine (4-FA) became an emerging issue in many European countries. Stimulating effects last for 4-6 hours and can impact psychomotor performance. The metabolism of amphetamine-type stimulants is stereoselective and quantification of (R)- and (S)-enantiomers has been suggested for assessing time of use. To date, no data on enantioselective pharmacokinetics is available for 4-FA in serum samples. An enantioselective liquid chromatography-tandem mass spectrometry (LC-MS-MS) method was developed using a chiral Phenomenex® Lux 3 µm AMP column. Validation of the method showed satisfactory selectivity, sensitivity, linearity (0.5-250 ng/mL), precision and accuracy. Recreational stimulant users orally ingested two doses (100 mg, n = 12; 150 mg, n = 5) of 4-FA. Blood samples were drawn prior to application and over a period of 12 hours after ingestion and analyzed for 4-FA enantiomers. Peak concentrations and corresponding times did not differ significantly between the enantiomers (mean (R)/(S)-ratio at tmax 1.05, 0.85-1.16). With mean 12.9 (8.3-16.1) hours, apparent elimination half-lives (t1/2) were significantly (P < 0.01) longer for (R)-4-FA than for (S)-4-FA (6.0 hours; range 4.4-10.2 hours) and independent of the dose given. Over time, (R)/(S)-concentration-ratios were linearly increasing in all subjects to maximum ratios of 2.00 (1.08-2.77) in the last samples (after 12 hours). The slopes of the (R)/(S)-ratio exhibited marked interindividual differences (0.023-0.157 h-1, mean 0.095 h-1). Ratios higher than 1.60 only appeared earliest after a minimum of 6 hours and therefore suggest the absence of acute drug effects. Different elimination half-lives of enantiomers lead to constantly increasing (R)/(S)-concentration-ratios. Consequently, ratios of 4-FA enantiomers in serum are a promising indicator for assessment of the time of drug consumption.

GHB related acids (dihydroxy butyric acids, glycolic acid) can help in the interpretation of post mortem GHB results.

Post mortem gamma hydroxy butyric acid (GHB) concentrations should be interpreted with caution since GHB concentrations can increase after death. Post mortem concentrations after the intake of GHB ante mortem do overlap with concentration ranges in cases without known exposure to GHB and make an interpretation challenging. GHB is known to undergo intensive metabolism to related acids (glycolic acid (GA), succinic acid (SA), 2,4- and 3,4-dihydroxy butyric acid (2,4-OH-BA and 3,4-OH-BA)). GHB and these related acids were analyzed using a validated gas chromatographic mass spectrometric (GC-MS) method after liquid liquid extraction and trimethylsilylation. SA concentrations were not usable post mortem due to instability. Concentrations in cases without known exposure to GHB (urine: n = 80; femoral blood: n = 103) were: for GA 4.6-121 mg/L in urine and 1.6-11.2 mg/L in blood, for 2,4-OH-BA < LoD-25,3 mg/L in urine and < LoD-3.7 mg/L in blood and for 3,4-OH-BA < LoD-54,3 mg/L in urine and < LoD-5.3 mg/L in blood. In death cases involving GHB (n = 11) concentrations of GHB related acids were increased compared to these levels (for GA in 7/10 cases and up to 391 mg/L in urine, in 6/11 cases and up to 34 mg/L in blood; for 2,4-OH-BA in 9/10 cases and up to 144 mg/L in urine, in 11/11 cases and up to 9.1 mg/L in blood; for 3,4-OH-BA in 7/10 cases and up to 665 mg/L in urine, in 11/11 cases and up to 19 mg/L in blood). Therefore, the concentrations of these GHB related acids can aid in a more reliable differentiation of GHB exposure in post mortem toxicology. We recommend to add the analysis of 2,4-OH-BA, 3,4-OH-BA and GA in femoral blood for the diagnosis of a GHB intake post mortem. Post mortem femoral blood concentrations > 4 mg/L for 2,4-OH-BA, > 5 mg/L for 3,4-OH-BA and > 12 mg/L for GA give hints for a GHB intake.

Phase I metabolites (organic acids) of gamma-hydroxybutyric acid-validated quantification using GC-MS and description of endogenous concentration ranges.

Gamma-hydroxybutyric acid (GHB) is a sedative drug used in drug-facilitated crimes. Its detection window is very short. GHB undergoes intensive phase I metabolism to organic acids (glycolic acid, succinic acid, dihydroxybutyric acids). These could be potential analytical targets to broaden the detection window. The aim of the present study was to enable the detection of endogenous levels of these metabolites in biological samples (blood and urine). A gas chromatographic-mass spectrometric method using liquid-liquid extraction and derivatization with N-methyl-N-tri-methylsilyltrifluoracetamide was developed for the quantification. Validation results were consistent with international guidelines, and the method was able to quantify endogenous levels of the substances in both urine and blood. Endogenous concentrations were shown to be <0.03-4.92 mg/L for glycolic acid, <0.03-1.28 mg/L for GHB, <0.28-18.1 mg/L for succinic acid, <0.12-1.38 mg/L for 2,4-dihydroxybutyric acid, and <0.13-2.59 mg/L for 3,4-dihydroxybutyric acid in serum samples of 101 volunteers. Urinary endogenous concentrations were shown to be 1.30-400 mg/L for glycolic acid, <0.03-1.94 mg/L for GHB, 1.17-2.73 mg/L for succinic acid, 0.72-26.2 mg/L for 2,4-dihydroxybutyric acid, and 1.88-122 mg/L for 3,4-dihydroxybutyric acid in urine samples of 132 volunteers. These endogenous concentrations represent a basis to which concentrations after the intake of GHB can be compared to in order to prove the intake of this substance.