Postmortem findings of pipamperone after fatal intoxications and its distribution in body fluids and tissues

Phenibut screening and quantification with liquid chromatography-tandem mass spectrometry and its application to driving cases

An analytical strategy for identification by an LC-MS/MS multitarget screening method and a suitable LC-MS/MS based quantification were developed for the psychotropic drug phenibut. The samples analyzed were collected during traffic control and were associated with driving under the influence of drugs. A positive sample for phenibut was identified in a single case of driving under the influence. The quantification revealed a drug concentration of 1.9 μg/mL. An interaction with blood alcohol (BAC = 0.10%) was discussed as the explanation of the way of driving and deficit manifestations observed (swaying, nystagmus, quivering of the eyelid, and reddened eyes). According to the available information, the quantified phenibut concentration could be explained by an intake of four tablets (self-reported) during the day containing 250 mg of the drug. Chromatography was performed with a Luna 5 μm C18 (2) 100 A, 150 mm × 2 mm analytical column, and a buffer system consisted of 10 mM ammonium acetate and 0.1% acetic acid (v/v) included in mobile phases marked as A (H2 O/methanol = 95/5, v/v) and B (H2 O/methanol = 3/97, v/v). An effective limit of detection (LOD = 0.002 μg/mL) could be achieved for the multitarget screening method. The quantification of phenibut was performed on a second LC-MS/MS system with LOD/LOQ values of 0.22/0.40 μg/mL. Since phenibut quantification data are rare, the presented information can be used with caution for evaluation of positive cases in the future.

Antemortem and postmortem rodenticide analysis in forensic toxicology as a part of an LC-MS/MS-based multi-target screening strategy

Since rodenticides represent a substance group relevant in toxicological analyses, the aim of this work was the development of a complex multi-target screening strategy for the identification with liquid chromatography-tandem mass spectrometry. A simple protein precipitation was used as the sample preparation strategy. Further, a Luna 5 μm C18 (2) 100 Å, 150 × 2 mm analytical column was applied for the separation of relevant analytes with a Shimadzu HPLC. Signal detection was performed with a SCIEX API 5500 QTrap MS/MS system. The rodenticides investigated (α-chloralose, brodifacoum, bromadiolone, coumatetralyl, difenacoum, and warfarin) could be incorporated effectively into a multi-target screening strategy covering about 250 substances representing different groups with a limit of detection appropriate for substance identification. The strategy can easily be modified to perform semi-quantitative measurements for this substance group and could be supplemented by quantification based on standard addition.

Detection of pharmaceuticals in "dirty sprite" using gas chromatography and mass spectrometry

Dirty Sprite, also known as "lean" or "purple drank", is a preparation associated with the presence of codeine and promethazine. These drinks, predominantly used by young people, are mixtures of, for example, soft drinks, prescription medicines, and prescription cough syrups. The use of these illicit preparations started in Texas in the 1960s and become popularized in the 1990s. However, the misuse of these cocktails has become more common in other countries to date, for example, in Thailand. Given the illicit nature of these preparations and the lack of information available on the composition of these products, there is a need to identify and quantify the drugs that may be present. Three samples of Dirty Sprite were analyzed using GC-MS after liquid/liquid-extraction under acidic and basic conditions. Since the acidic extraction did not show the detection of relevant substances, samples were alkalized to pH ≥ 9, followed by extraction with 1-chlorobutane. GC-MS screening revealed the identification of codeine, dihydrocodeine, promethazine and impurities of cocaine. A selected ion monitoring method was developed for the quantification of these compounds using lemonade as a calibration matrix. Quantitative analysis showed concentrations of 130-mg/L codeine, 75-mg/L promethazine, and 3.4-mg/L cocaine in sample 1; 74-mg/L promethazine and 91-mg/L dihydrocodeine in sample 2; and 130-mg/L codeine combined with 68-mg/L promethazine in sample 3. The results also illustrate that the consumption of drugs detected in Dirty Sprite samples could lead to health risks given that these prescription medicines are consumed outside the medical environment.

Determination of drugs in exhumed liver and brain tissue after over 9 years of burial by liquid chromatography-tandem mass spectrometry-Part 2: Benzodiazepines, opioids, and further drugs

In this publication, benzodiazepines, opioids, and further drugs were analyzed in exhumed brain and liver tissue samples in 116 cases (total) after 9.5-16.5 years of burial. Solid phase extraction followed by liquid chromatography-tandem mass spectrometry was applied. Data from literature is listed summarizing the detectability of the presented analytes after a certain time of burial. In our study, 60% of the analyzed benzodiazepines, 100% of the opioids, and 82% of further drugs were detectable. Only the benzodiazepines lorazepam, nitrazepam, flunitrazepam, and its metabolite norflunitrazepam, and the drugs butylscopolamine, metronidazole, and omeprazole were not detectable at all. Percentage of positive findings (total, and separately for brain and liver tissue) and postmortem period are listed for each analyte. Correlation of detectability depending on postmortem period and condition of tissue are presented exemplarily for midazolam. No substantial correlation was observed. Despite a long time of burial, most benzodiazepines, opioids, and further drugs were detectable in the examined tissue samples. Our results may be a good support for future exhumations in which toxicological analyses are relevant.

Interpretation of melperone intoxication: post-mortem concentration distribution and interpretation of intoxication data

OBJECTIVES

Since melperone abuse with lethal intoxication is common, expert opinions based on therapeutical and lethal concentration ranges can be considered as important. Because there is a lack of information about fatalities caused by melperone mono-intoxications and data on tissue samples with concentration distribution, the aim of this work is the examination of lethal concentration ranges of melperone and drug quantification in different matrices.

METHODS

An LC-MS/MS method was applied for analyses performed in blood and tissue samples. Quantification based on standard addition and sample preparation on liquid-liquid extraction with 1-chlorobutane. An appropriate tissue homogenization was performed ahead of extraction with an IKA Ultra-Turrax-Tube-Drive^®. A Luna 5 µm C18 (2) 100 Å, 150  × 2 mm analytical column was used for chromatographic separation and the elution was performed with two mobile phases consisted of A (H₂O/methanol = 95/5, v/v) and B (H₂O/methanol = 3/97, v/v) both with 10 mM ammonium acetate and 0.1% acetic acid.

RESULTS

A multi-drug LC-MS/MS analytical method developed was applied successfully for melperone quantification in different post-mortem matrices. No analytical problems could be identified during method development and analyses of real samples. The melperone lethal concentration calculated in femoral blood of the drug mono-intoxication investigated was 10 mg/L. Melperone concentration distribution was presented for the first time.

CONCLUSIONS

The lethal reference concentration of melperone in femoral blood of 17.1 mg/L pointed out in different reference lists should be used with caution. Instead, a lower lethal melperone concentration should be considered. The post-mortem concentration distribution of the drug presented could be helpful in the interpretation of cases where no blood samples are available.

Interpretation of melperone intoxication: post-mortem concentration distribution and interpretation of intoxication data

OBJECTIVES

Since melperone abuse with lethal intoxication is common, expert opinions based on therapeutical and lethal concentration ranges can be considered as important. Because there is a lack of information about fatalities caused by melperone mono-intoxications and data on tissue samples with concentration distribution, the aim of this work is the examination of lethal concentration ranges of melperone and drug quantification in different matrices.

METHODS

An LC-MS/MS method was applied for analyses performed in blood and tissue samples. Quantification based on standard addition and sample preparation on liquid-liquid extraction with 1-chlorobutane. An appropriate tissue homogenization was performed ahead of extraction with an IKA Ultra-Turrax-Tube-Drive®. A Luna 5 µm C18 (2) 100 Å, 150  × 2 mm analytical column was used for chromatographic separation and the elution was performed with two mobile phases consisted of A (H2O/methanol = 95/5, v/v) and B (H2O/methanol = 3/97, v/v) both with 10 mM ammonium acetate and 0.1% acetic acid.

RESULTS

A multi-drug LC-MS/MS analytical method developed was applied successfully for melperone quantification in different post-mortem matrices. No analytical problems could be identified during method development and analyses of real samples. The melperone lethal concentration calculated in femoral blood of the drug mono-intoxication investigated was 10 mg/L. Melperone concentration distribution was presented for the first time.

CONCLUSIONS

The lethal reference concentration of melperone in femoral blood of 17.1 mg/L pointed out in different reference lists should be used with caution. Instead, a lower lethal melperone concentration should be considered. The post-mortem concentration distribution of the drug presented could be helpful in the interpretation of cases where no blood samples are available.

Determination of drugs in exhumed liver and brain tissue after over 9 years of burial by liquid chromatography-tandem mass spectrometry-Part 1: Cardiovascular drugs

This paper should serve as support for future exhumations in which an analysis of cardiovascular drugs is issued after over 9 years of burial. Amiodarone, amlodipine, atropine, bisoprolol, cafedrine, clonidine, esmolol, furosemide, hydrochlorothiazide, lisinopril, nifedipine, nitrendipine, phenprocoumon, torsemide verapamil, and xipamide were determined in liver and brain tissue of over 100 cases in which exhumation was performed after over 9 years of burial. Diagrams, showing the detectability depending on postmortem period as well as condition of tissues, are presented for furosemide.