A preliminary investigation of lung availability of cannabinoids by smoking marijuana or dabbing BHO and decarboxylation rate of THC- and CBD-acids.

Highly potent cannabis concentrates obtained by butane or by supercritical carbon dioxide-extraction are gaining popularity. These extracts called butane hash oil (BHO) with Δ9-tetrahydrocannabinolic acid A (THCA) contents above 60% are consumed by flash vaporization on a glowing titanium nail, followed by inhalation of the resulting vapor through a water pipe in a single puff - a technique referred to as "dabbing". We herein investigated the decarboxylation rate of THCA during artificial smoking of cannabis plant material and simulated dabbing, and the lung availability of Δ9-tetrahydrocannabinol (THC) which we define as the recovery of THC in the smoke and vapor condensates. Preliminary smoking and dabbing experiments were performed using an apparatus built in-house. Due to availability of cannabidiol (CBD)-rich hemp in Switzerland, we included a sample of CBD flowers in our experiments and investigated the decarboxylation and recovery of cannabidiolic acid (CBDA) and CBD, respectively. Decarboxylation of THCA and CBDA during combustion of the plant material and vaporization of the BHO, respectively, was complete. The high recovery of total THC (75.5%) by dabbing cannot be achieved by smoking marijuana. Lung availability ranged from 12% for mixed cannabis material with a rather low THC content, to approximately 19-27% for marijuana flowers, similar for THC in marijuana as for CBD in CBD-rich marijuana. In reality, when smoking a joint, further losses in recovery must be assumed by additional sidestream smoke. The rather high lung availability of THC via dabbing can explain the increased psychoactive and adverse effects associated with this new trend of cannabis consumption.

Drug-related death: adulterants from cocaine preparations in lung tissue and blood.

The abuse of drugs such as street cocaine is known to cause a variety of toxic effects, some of which involve the lungs and often induce lethal complications. While the toxicity of cocaine itself is reviewed well, the influence of toxic effects of its adulterants on the human body is not thoroughly studied. Therefore, we examined heart blood, femoral vein blood and lung tissue from 11 cases for typically used adulterants in cocaine preparations and check whether if the concentrations in the lung tissue are higher than in the blood. The adulterants were isolated using solid-phase (SPE) and liquid-liquid extraction (LLE) and quantified via high-pressure-liquid-chromatography-time-of-flight-mass spectrometry (LC/TOF-MS). Five adulterants, i.e., phenacetin, lidocaine, diltiazem, levamisole and hydroxyzine, were detected. We found out that the concentration of these substances was often higher in the lung than in the analogous analysed body fluids. It should therefore be considered whether - for the determination in the cause of death - the lung should be examined in addition to heart blood, urine or brain tissue.

Studies on the phase I metabolism of the new designer drug 3-fluoromethcathinone using rabbit liver slices.

The metabolism of the novel designer drug 3-fluoromethcathinone (3-FMC), sold as "legal highs", was investigated in vitro via cryopreserved rabbit liver slices. The pharmacological properties and toxicological effects of 3-FMC and its metabolites are not known yet. It can be assumed that 3-FMC will cause effects similar to 4-methylmethcathinone (mephedrone) and methcathinone. For the metabolism studies, pretests were performed with rabbit liver slices incubated with kavain to evaluate optimal conditions. Finally, six known metabolites of kavain were revealed and therefore sufficient information about the suitability of the enzyme system of the rabbit liver slices was obtained. Under optimized conditions, 3-FMC was added to Krebs-Henseleit buffer, pH 7.4 containing NADPH and bicarbonate and incubated with a single rabbit liver slice at 37°C. The metabolism was monitored at 5, 30 and 180 min, respectively. The metabolites formed via the former cryopreserved rabbit liver slices were examined by LC/MS-TOF. Metabolites were identified by their exact masses and isotopic patterns. 3-Fluorocathinone, 3-fluorocathinone-imine, hydroxy-3-fluoromethcathinone and 3-fluoromethcathinone-diol were formed as the main metabolites.

Rapid isolation procedure for Δ9-tetrahydrocannabinolic acid A (THCA) from Cannabis sativa using two flash chromatography systems.

Two isolation procedures for Δ9-tetrahydrocannabinolic acid A (THCA), the biogenetic precursor in the biosynthesis of the psychoactive Δ9-tetrahydrocannabinol (THC) in the cannabis plant, are presented. Two flash chromatography systems that can be used independently from each other were developed to separate THCA from other compounds of a crude cannabis extract. In both systems UV absorption at 209 and 270 nm was monitored. Purity was finally determined by HPLC-DAD, NMR and GC-MS analysis with a focus on the impurity THC. System 1 consisted of a normal phase silica column (120 g) as well as cyclohexane and acetone--both spiked with the modifier pyridine--as mobile phases. Gradient elution was performed over 15 min. After the chromatographic run the fractions containing THCA fractions were pooled, extracted with hydrochloric acid to eliminate pyridine and evaporated to dryness. Loading 1800 mg cannabis extract yielded 623 mg THCA with a purity of 99.8% and a THC concentration of 0.09%. System 2 was based on a reversed-phase C18 column (150 g) combined with 0.55% formic acid and methanol as mobile phases. A very flat gradient was set over 20 minutes. After pooling the THCA-containing fractions methanol was removed in a rotary evaporator. THCA was re-extracted from the remaining aqueous phase with methyl tert-butyl ether. The organic phase was finally evaporated under high vacuum conditions. Loading 300 mg cannabis extract yielded 51 mg THCA with a purity of 98.8% and a THC concentration of 0.67%.

Detection of Delta9-tetrahydrocannabinolic acid A in human urine and blood serum by LC-MS/MS.

Delta9-tetrahydrocannabinolic acid A (Delta9-THCA-A) is the precursor of Delta9-tetrahydrocannabinol (Delta9-THC) in hemp plants. During smoking, the non-psychoactive Delta9-THCA-A is converted to Delta9-THC, the main psychoactive component of marihuana and hashish. Although the decarboxylation of Delta9-THCA-A to Delta9-THC was assumed to be complete--which means that no Delta9-THCA-A should be detectable in urine and blood serum of cannabis consumers--we found Delta9-THCA-A in the urine and blood serum samples collected from police controls of drivers suspected for driving under the influence of drugs (DUID). For LC-MS/MS analysis, urine and blood serum samples were prepared by solid-phase extraction. Analysis was performed with a phenylhexyl column using gradient elution with acetonitrile. For detection of Delta9-THCA-A, the mass spectrometer (MS) (SCIEX API 365 triple-quadrupole MS with TurboIonSpray source) was operated in the multiple reaction monitoring (MRM) mode using the following transitions: m/z357 --> 313, m/z357 --> 245 and m/z357 --> 191. Delta9-THCA-A could be detected in the urine and blood serum samples of several cannabis consumers in concentrations of up to 10.8 ng/ml in urine and 14.8 ng/ml in serum. The concentration of Delta9-THCA-A was below the Delta9-THC concentration in most serum samples, resulting in molar ratios of Delta9-THCA-A/Delta9-THC of approximately 5.0-18.6%. Only in one case, where a short elapsed time between the last intake and blood sampling is assumed, the molar ratio was 18.6% in the serum. This indicates differences in elimination kinetics, which need to be investigated in detail.