Re-evaluation of the pharmacokinetics of xylazine administered to Thoroughbred horses.

Xylazine is widely used worldwide as a short-acting sedative in general equine and racing practice. In the UK, although it has a legitimate use during training, equine anti-doping rules state it is a prohibited substance on race day. The aim of the study was to produce a detection time (DT) to better inform European veterinary surgeons so that xylazine can be used appropriately under regulatory rules. Previous publications have various limitations pertaining to analysis method, particularly for plasma and limited length of time of sample collection. In this study, pharmacokinetic data were produced for xylazine and 4-OH-xylazine in equine urine and plasma following a single intravenous xylazine dose of 0.4 mg/kg to six Thoroughbred horses. Pharmacokinetic parameters were generated from a 3-compartmental model with clearance = 15.8 ± 4.88 ml min-1  kg-1 , Vss = 1.44 ± 0.38 L/kg, terminal half-life = 29.8 ± 12.7 hr and a DT determined at 71 hr for the administration of xylazine (Chanazine® ) in plasma and urine. Urine screening should aim to detect the 4-OH-xylazine metabolite, which can act as an indicator for the xylazine plasma concentration. A DT of 72 hr has been agreed by the European Horserace Scientific Liaison Committee, to be implemented in June 2019.

Detection of FG-4592 and metabolites in equine plasma, urine and hair following oral administration.

FG-4592 is a hypoxia-inducible factor inhibitor that has been approved for therapeutic use in some countries. This class of compounds can increase the oxygen carrying capacity of the blood and thus have the potential to be used as performance enhancing agents in sports. The purpose of this study was to investigate the detection of FG-4592 and metabolites in equine plasma and mane hair following a multiple dose oral administration to two Thoroughbred racehorses, to identify the best analytical targets for doping control laboratories. Urine samples were also analysed, and the results compared to previously published urine data. Liquid chromatography-high resolution mass spectrometry was used for metabolite identification in urine and plasma. Liquid chromatography-tandem mass spectrometry was used for full sample analysis of urine, plasma and hair samples and generation of urine and plasma profiles. FG-4592 and a mono-hydroxylated metabolite were detected in plasma. FG-4592 was detected with the greatest abundance and gave the longest duration of detection, up to 312 h post-administration, and would be the recommended target in routine doping samples. FG-4592 was detected in all mane hair samples collected post-administration, up to 166 days following the final dose, showing extended detection can be achieved with this matrix. To the best of the authors' knowledge, this is the first report of FG-4592 and metabolites in equine plasma and hair samples. Urine results were consistent with the previously published data, with FG-4592 offering the best target for detection and longest detection periods.

Detection of the growth hormone secretagogue MK-0677 in equine hair following oral administration.

MK-0677 (ibutamoren) is an orally active non-peptide growth hormone secretagogue that binds to the ghrelin receptor stimulating the secretion of endogenous growth hormone. It is one of the most prevalent performance-enhancing compounds currently available online and is potentially subject to abuse both in human and equine sports. The aim of the current study was to investigate whether it could be detected in equine hair following oral administration of MK-0677 mesylate to a Thoroughbred racehorse. MK-0677 and its O-dealkylated metabolite were extracted using an existing method for prohibited substances in equine hair and analysed by liquid chromatography tandem mass spectrometry. This enabled the detection of MK-0677 in all hair samples collected, up to 209 days in mane and 358 days in tail. A follow-up methodology with an extensive wash procedure was carried out for selected hair samples, which unambiguously verified the presence of MK-0677. Wash criteria to differentiate between internal incorporation (via bloodstream) and external deposition (via sweat and sebum) was also assessed and indicated internal incorporation for the samples collected at later time points (≥52 days) and a combination of internal incorporation and external deposition for hair samples collected at the earlier time point (2 days).

In vitro metabolism of the REV-ERB agonist SR-9009 and subsequent detection of metabolites in associated routine equine plasma and urine doping control samples.

SR-9009 is a synthetic compound widely available to purchase online as 'supplement' products due to its potential performance-enhancing effects, presenting a significant threat with regard to doping control in sport. In vitro metabolism with equine liver microsomes was performed to identify potential targets for detection of SR-9009. Six metabolites were identified, with the most abundant consisting of N-dealkylated metabolites (M1-M3). The addition of the identified metabolites to high-resolution accurate mass databases resulted in a positive finding for the N-dealkylated metabolite M1 of SR-9009 in an associated plasma and urine doping sample. Liquid chromatography-high-resolution mass spectrometry was used to verify the presence of the N-dealkylated metabolite (M1) in both matrices, with a low concentration of the parent compound and additional N-desalkyl metabolites (M2 and M3) detected in the plasma sample as supporting evidence of administration. To the best of the authors' knowledge, this is the first report of an adverse analytical finding in an equine sample for SR-9009 or its metabolites in equine doping control.

Equine metabolism of the growth hormone secretagogue MK-0677 in vitro and in urine and plasma following oral administration.

Ibutamoren mesylate, or MK-0677, is an orally active, nonpeptide growth hormone secretagogue that has been developed to stimulate excretion of endogenous growth hormone. It has been evaluated for the treatment of a range of clinical conditions but is not available therapeutically. Nonetheless, MK-0677 is widely available to purchase online, sold as 'supplement' products. The mode of action and relative ease of purchase make MK-0677 a potential threat with regard to sports doping. The aim of this study was to investigate the metabolism of MK0677 in the horse following in vitro incubation and oral administration to two Thoroughbred racehorses, in order to identify the most appropriate analytical targets for doping control laboratories. Liquid chromatography high resolution mass spectrometry was used for metabolite identification, and subsequently, liquid chromatography-tandem mass spectrometry was used to generate full metabolite profiles for post-administration urine and plasma samples. Fourteen phase I metabolites were identified in vitro; 13 of these were subsequently detected in urine and nine in plasma collected post-administration, alongside the parent compound in both matrices. In both urine and plasma, the longest duration of detection was observed for an O-dealkylated metabolite of MK-0677, and therefore, this would be the best target for the detection of MK-0677 administration. MK-0677 and the O-dealkylated metabolite were found to be excreted largely unconjugated in urine and plasma.

In vitro and in vivo metabolism of the anabolic-androgenic steroid oxandrolone in the horse.

Oxandrolone is an anabolic-androgenic steroid with favourable anabolic to androgenic ratio, making it an effective anabolic agent with less androgenic side effects. Although its metabolism has been studied in humans, its phase I and II metabolism has not been previously reported in the horse. The purpose of this study was to investigate the in vitro metabolism of oxandrolone (using both equine liver microsomes and S9) and in vivo metabolism following oral administration (three daily doses of 50 mg of oxandrolone to a single Thoroughbred horse), using both gas and liquid chromatography-mass spectrometry techniques. The in vitro phase I transformations observed included 16-hydroxylated (two epimers), 17-methyl-hydroxylated and 16-keto metabolites. In addition to parent oxandrolone and these hydroxylated metabolites, the 17-epimer and a 17,17-dimethyl-18-norandrost-13-ene analogue were detected in biological samples following the administration. 16-keto-oxandrolone was only observed in urine. The 16- and 17-methyl-hydroxylated oxandrolone metabolites were predominantly excreted as sulfate conjugates in urine, whereas parent oxandrolone, its epimer and 17,17-dimethyl-18-norandrost-13-ene derivative were found predominantly in the unconjugated urine fraction. The most abundant analyte detected in both plasma and urine was parent oxandrolone. However, the longest detection period using the developed analytical method was provided by 17-hydroxymethyl-oxandrolone in both matrices. The results of this study provided knowledge of how best to detect the use of oxandrolone in regulatory samples.

Identification of equine in vitro metabolites of seven non-steroidal selective androgen receptor modulators for doping control purposes.

Selective androgen receptor modulators, SARMs, are a large class of compounds developed to provide therapeutic anabolic effects with minimal androgenic side effects. A wide range of these compounds are available to purchase online and thus provide the potential for abuse in sports. Knowledge of the metabolism of these compounds is essential to aid their detection in doping control samples. In vitro models allow a quick, cost-effective response where administration studies are yet to be carried out. In this study, the equine phase I metabolism of the non-steroidal SARMs GSK2881078, LGD-2226, LGD-3303, PF-06260414, ACP-105, RAD-140 and S-23 was investigated using equine liver microsomes. Liquid chromatography coupled to a QExactive Orbitrap mass spectrometer allowed identification of metabolites with high resolution and mass accuracy. Three metabolites were identified for both GSK2881078 and LGD-2226, four for LGD-3303 and RAD-140, five for PF-06260414, twelve for ACP-105 and ten for S-23. The equine metabolism of GSK-2881078, LGD-2226, LGD-3303 and PF-06260414 is reported for the first time. Although the equine metabolism of ACP-105, RAD-140 and S-23 has previously been reported, the results obtained in this study have been compared with published data.

Equine metabolism of the selective androgen receptor modulator AC-262536 in vitro and in urine, plasma and hair following oral administration.

AC-262536 is one of a number of selective androgen receptor modulators that are being developed by the pharmaceutical industry for treatment of a range of clinical conditions including androgen replacement therapy. Though not available therapeutically, selective androgen receptor modulators are widely available to purchase online as (illegal) supplement products. The growth- and bone-promoting effects, along with fewer associated negative side effects compared with anabolic-androgenic steroids, make these compounds a significant threat with regard to doping control in sport. The aim of this study was to investigate the metabolism of AC-262536 in the horse following in vitro incubation and oral administration to two Thoroughbred horses, in order to identify the most appropriate analytical targets for doping control laboratories. Urine, plasma and hair samples were collected and analysed for parent drug and metabolites. Liquid chromatography-high-resolution mass spectrometry was used for in vitro metabolite identification and in urine and plasma samples. Nine phase I metabolites were identified in vitro; four of these were subsequently detected in urine and three in plasma, alongside the parent compound in both matrices. In both urine and plasma samples, the longest detection window was observed for an epimer of the parent compound, which is suggested as the best target for detection of AC-262536 administration. AC-262536 and metabolites were found to be primarily glucuronide conjugates in both urine and plasma. Liquid chromatography-tandem mass spectrometry analysis of post-administration hair samples indicated incorporation of parent AC-262536 into the hair following oral administration. No metabolites were detected in the hair.

Investigations into the analysis of intact drug conjugates in animal sport doping control - Development and assessment of a rapid and economical approach for screening greyhound urine.

Animal sport doping control laboratories are constantly reviewing ways in which they can improve their service offering whilst ensuring that they remain economically viable. This paper describes the development and assessment of a rapid and economical method for the detection of intact glucuronide conjugates of three anabolic steroids and their metabolites along with three corticosteroids in canine urine. The analysis of intact drug conjugates for animal sport doping control is generally not performed routinely as it presents a number of analytical challenges, not least of which is the lack of availability of appropriate reference standards. Here, we report the development of a UHPLC-MS/MS method using APCI in the negative ion mode for the detection of intact phase II conjugates, including the importance of in vitro incubations in order to provide appropriate reference materials. Cross-validation of the developed method demonstrated that the detection capability of the intact phase II conjugates of stanozolol, boldenone, nandrolone, and their metabolites along with the corticosteroids dexamethasone and methylprednisolone was equivalent to that achieved in routine race-day screens. The new process has been in operation for approximately 2 years and has been used to analyze in excess of 13500 canine urine samples, resulting in a number of positive screening findings. To the best of our knowledge, this is the first reported use of a routine screen for intact drug conjugates within animal sport doping control.

Investigation of the metabolism of the selective androgen receptor modulator LGD-4033 in equine urine, plasma and hair following oral administration.

LGD-4033 is one of a number of selective androgen receptor modulators (SARMs) that are being developed by the pharmaceutical industry to provide the therapeutic benefits of anabolic androgenic steroids, without the less desirable side effects. Though not available therapeutically, SARMs are available for purchase online as supplement products. The potential for performance enhancing effects associated with these products makes them a significant concern with regards to doping control in sports. The purpose of this study was to investigate the metabolism of LGD-4033 in the horse following oral administration, in order to identify the most appropriate analytical targets for doping control laboratories. LGD-4033 was orally administered to two Thoroughbred horses and urine, plasma and hair samples were collected and analysed for parent drug and metabolites. LC-HRMS was used for metabolite identification in urine and plasma. Eight metabolites were detected in urine, five of which were excreted only as phase II conjugates, with the longest detection time being observed for di- and tri-hydroxylated metabolites. The parent compound could only be detected in urine in the conjugated fraction. Seven metabolites were detected in plasma along with the parent compound where mono-hydroxylated metabolites provided the longest duration of detection. Preliminary investigations with hair samples using LC-MS/MS analysis indicated the presence of trace amounts of the parent compound and one of the mono-hydroxylated metabolites. In vitro incubation of LGD-4033 with equine liver microsomes was also performed for comparison, yielding 11 phase I metabolites. All of the metabolites observed in vivo were also observed in vitro.

In vitro metabolism of the novel synthetic opioid agonist cyclopropylfentanyl and subsequent confirmation in authentic human samples using liquid chromatography-high resolution mass spectrometry.

Novel synthetic opioids (NSOs) are a class of novel psychoactive substances (NPS) that are growing in popularity and presenting a significant public health risk. Included in this class are derivatives of the highly potent analgesic, fentanyl. Cyclopropylfentanyl (CycP-F) was first reported to the EU Early Warning System in August 2017, and was subsequently linked to more than 100 deaths in the US alone. Limited pharmacological, pharmacokinetic or toxicological data is available for many emerging NSOs; however we can expect novel fentanyl analogues to present limited detection windows, short onset, narrow therapeutic indices and the potential for very high potency. Knowledge of the metabolism of these drugs is essential for the identification of analytical targets for their detection. Therefore in vitro metabolites of CycP-F were produced using human liver microsomal incubations. Metabolites formed were elucidated using liquid chromatography-high resolution accurate mass analysis (LC-HRAM). Identified metabolites were added to our accurate mass screening database for NPS which was utilised for subsequent screening analysis. CycP-F and metabolites were identified in two human blood case samples. Eleven metabolites were identified in vitro, with the major metabolites produced via N-dealkylation, monohydroxylation and N-oxidation. Analysis of the positive case samples identified four in vivo metabolites, all of which were observed in vitro. The major metabolite identified in vitro and in vivo was the N-dealkylated nor-metabolite; two further mono-hydroxylated and one dihydroxylated metabolite were detected in vivo.