D. S. McKemie

Molecular cloning, expression and initial characterization of members of the CYP3A family in horses

The use of performance-enhancing drugs in the horse racing industry combined with the need for more rational approaches in the use of therapeutic agents in equids necessitates additional studies on the spectrum, content, and catalytic activities of hepatic cytochrome P450 monooxygenases in this species. In this study, three cytochrome P450 (P450) monooxygenases in the 3A family were cloned from, sequenced, and expressed in a baculovirus expression system. The proteins were designated CYP3A89, CYP3A96, and CYP3A97. Expression studies produced various results among the three proteins. CYP3A89 appears to undergo post-translational modification, producing a truncated protein, and although metabolically active, CYP3A97 did not have a detectable P450 spectrum. Expression of CYP3A96 produced a full-length, catalytically active protein. CYP3A96 catalyzed testosterone, and nifedipine metabolism was 20- and 10-fold slower, respectively, compared with the human counterpart, CYP3A4. Relative hepatic expression levels of each member of the CYP3A family, determined using quantitative reverse transcription-polymerase chain reaction, varied more than 1000-fold in individual horses. The results demonstrate substantial interspecies variability in metabolism of substrates by members of the CYP3A family in the horse and human and support the need to fully characterize 450-mediated metabolism in equids. These studies provide a framework for screening therapeutically useful drugs and provide a method for determination of metabolites of illegal performance-enhancing drugs without the time and expense of either in vivo studies or obtaining liver samples for in vitro analysis.

Pharmacokinetics and pharmacodynamics of tramadol in horses following oral administration

Tramadol is a synthetic opioid used in human medicine, and to a lesser extent in veterinary medicine, for the treatment of both acute and chronic pain. In humans, the analgesic effects are owing to the actions of both the parent compound and an active metabolite (M1). The goal of the current study was to extend current knowledge of the pharmacokinetics of tramadol and M1 following oral administration of three doses of tramadol to horses. A total of nine healthy adult horses received a single oral administration of 3, 6, and 9 mg/kg of tramadol via nasogastric tube. Blood samples were collected at time 0 and at various times up to 96 h after drug administration. Urine samples were collected until 120 h after administration. Plasma and urine samples were analyzed using liquid chromatography-mass spectrometry, and the resulting data analyzed using noncompartmental analysis. For the 3, 6, and 9 mg/kg dose groups, Cmax , Tmax, and the t1/2λ were 43.1, 90.7, and 218 ng/mL, 0.750, 2.0, and 1.5 h and 2.14, 2.25, and 2.39 h, respectively. While tramadol and M1 plasma concentrations within the analgesic range for humans were attained in the 3 and 6 mg/kg dose group, these concentrations were at the lower end of the analgesic range and were only transiently maintained. Furthermore, until effective analgesic plasma concentrations have been established in horses, tramadol should be cautiously recommended for control of pain in horses. No significant undesirable behavioral or physiologic effects were noted at any of the doses administered.

Pharmacokinetics and pharmacodynamics of butorphanol following intravenous administration to the horse

Butorphanol is a narcotic analgesic commonly used in horses. Currently, any detectable concentration of butorphanol in biological samples collected from performance horses is considered a violation. The primary goal of the study reported here was to update the pharmacokinetics of butorphanol following intravenous administration, utilizing a highly sensitive liquid chromatography-mass spectrometry (LC-MS) assay that is currently employed in many drug-testing laboratories. An additional objective was to characterize behavioral and cardiac effects following administration of butorphanol. Ten exercised adult horses received a single intravenous dose of 0.1 mg/kg butorphanol. Blood and urine samples were collected at time 0 and at various times for up to 120 h and analyzed using LC-MS. Mean±SD systemic clearance, steady-state volume of distribution, and terminal elimination half-life were 11.5±2.5 mL/min/kg, 1.4±0.3 L/kg, and 5.9±1.5 h, respectively. Butorphanol plasma concentrations were below the limit of detection (LOD) (0.01 ng/mL) by 48 h post administration. Urine butorphanol concentrations were below the LOD (0.05 ng/mL) of the assay in seven of 10 horses by 120 h post drug administration. Following administration, horses appeared excited as noted by an increase in heart rate and locomotion. Gastrointestinal sounds were markedly decreased for up to 24 h.

Preliminary pharmacokinetics of morphine and its major metabolites following intravenous administration of four doses to horses

The objective of the current study was to describe the pharmacokinetics of morphine and its metabolites following intravenous administration to the horse. A total of eight horses (two per dose group) received a single intravenous dose of 0.05, 0.1, 0.2, or 0.5 mg/kg morphine. Blood samples were collected up to 72 h postdrug administration, analyzed using LC-MS/MS and pharmacokinetic parameters determined. Behavior, step counts, and gastrointestinal activity were also assessed. The beta and gamma half-life for morphine ranged from 0.675 to 2.09 and 6.70 to 18.1 h, respectively, following administration of the four different IV doses. The volume of distribution at steady-state and systemic clearance ranged from 6.95 to 15.8 L/kg and 28.3 to 35.7 mL · min/kg, respectively. The only metabolites identified in blood samples were the primary metabolites identified in other species, 3-morphine-glucuronide and 6-morphine-glucuronide. Muscle fasciculations were observed at 0.2 and 0.5 mg/kg and ataxia noted at 0.5 mg/kg. Gastrointestinal activity was decreased in all dose groups (for up to 8 h in 7/8 horses and 24 h in one horse). This study extends previous studies and is the first report describing the metabolites of morphine in the horse. Plasma concentrations of morphine-3-glucuronide, a metabolite with demonstrated neuro-excitatory activity in mice, far exceeded that of morphine-6-glucuronide. Further study is warranted to assess whether the high levels of the morphine-3-glucuronide contribute to the dose-dependent excitation observed at high morphine doses.

Evidence for polymorphism in the cytochrome P450 2D50 gene in horses.

Metabolism is an essential factor in the clearance of many drugs and as such plays a major role in the establishment of dosage regimens and withdrawal times. CYP2D6, the human orthologue to equine CYP2D50, is a drug-metabolizing enzyme that is highly polymorphic in humans leading to widely differing levels of metabolic activity. As CYP2D6 is highly polymorphic, in this study it was hypothesized that the gene coding for the equine orthologue, CYP2D50, may also be prone to polymorphism. Blood samples were collected from 150 horses, the CYP2D50 gene was cloned and sequenced; and full-length sequences were analyzed for single nucleotide polymorphisms (SNPs), deletions, or insertions. Pharmacokinetic data were collected from a subset of horses following the administration of a single oral dose of tramadol and probit analysis used to calculate metabolic ratios. Prior to drug administration, the ability of recombinant CYP2D50 to metabolize tramadol to O-desmethyltramadol was confirmed. Sequencing of CYP2D50 identified 126 exonic SNPs, with 31 of those appearing in multiple horses. Oral administration of tramadol to a subset of these horses revealed variable metabolic ratios (tramadol: O-desmethyltramadol) in individual horses and separation into three metabolic groups. While a limited number of horses of primarily a single breed were studied, the variability in tramadol metabolism to O-desmethyltramadol between horses and preliminary evidence of what appears to be poor, extensive, and ultra-rapid metabolizers supports further study of the potential for genetic polymorphisms in the CYP2D50 gene in horses.

Pharmacokinetics and effects on thromboxane B2 production following intravenous administration of flunixin meglumine to exercised thoroughbred horses

Flunixin meglumine is commonly used in horses for the treatment of musculoskeletal injuries. The current ARCI threshold recommendation is 20 ng/mL when administered at least 24 h prior to race time. In light of samples exceeding the regulatory threshold at 24 h postadministration, the primary goal of the study reported here was to update the pharmacokinetics of flunixin following intravenous administration, utilizing a highly sensitive liquid chromatography-mass spectrometry (LC-MS). An additional objective was to characterize the effects of flunixin on COX-1 and COX-2 inhibition when drug concentrations reached the recommended regulatory threshold. Sixteen exercised adult horses received a single intravenous dose of 1.1 mg/kg. Blood samples were collected up to 72 h postadministration and analyzed using LC-MS. Blood samples were collected from 8 horses for determination of TxB(2) and PGE(2) concentrations prior to and up to 96 h postflunixin administration. Mean systemic clearance, steady-state volume of distribution and terminal elimination half-life was 0.767 ± 0.098 mL/min/kg, 0.137 ± 0.12 L/kg, and 4.8 ± 1.59 h, respectively. Four of the 16 horses had serum concentrations in excess of the current ARCI recommended regulatory threshold at 24 h postadministration. TxB(2) suppression was significant for up to 24 h postadministration.

Detection, pharmacokinetics and cardiac effects following administration of clenbuterol to exercised horses

REASONS FOR PERFORMING STUDY The use of clenbuterol in performance horses necessitates the establishment of appropriate withdrawal times. OBJECTIVES To describe plasma and urine concentrations of clenbuterol following administration of 2 commonly used dosing regimens to racing fit Thoroughbreds. STUDY DESIGN Experimental. METHODS Twenty-two horses received an oral dose of 0.8 μg/kg bwt of clenbuterol twice daily for 30 days. A second group of 6 horses received clenbuterol according to the escalating dose protocol on the manufacturers label. Blood and urine samples were collected prior to, throughout and at various times up to 35 days post administration of the final dose. Drug concentrations were measured using liquid chromatography-mass spectrometry, and plasma data were analysed using noncompartmental analysis. Behavioural and physiological effects were monitored and heart rate was recorded throughout the course of the study. RESULTS Clenbuterol plasma concentrations were below the limit of quantification (10 pg/ml) of the assay by Day 4 in all horses receiving the chronic low-dose regimen and by Day 7 in 5 of 6 horses receiving the escalating dosing protocol. Urine clenbuterol concentrations fell below the limit of quantification of the assay between Days 21 and 28 in all 22 horses in the low-dose group and in 5 of 6 of the horses in the escalating dose group. Muscle fasciculations, sweating and transient increases in heart rate were noted in a small number of horses following clenbuterol administration, but tolerance to these effects occurred rapidly. CONCLUSIONS AND POTENTIAL RELEVANCE Establishment of appropriate withdrawal times for specific racing jurisdictions depends upon the threshold adopted by that specific jurisdiction. This study extends previous studies describing the pharmacokinetics of clenbuterol and describes plasma and urine concentrations following administration of 2 commonly used dosing regimens to racing fit Thoroughbreds, which will allow jurisdictions to establish withdrawal times in order to prevent inadvertent positive regulatory findings.

Disposition and metabolic profile of the weak androgen Dehydroepiandrosterone (DHEA) following administration as part of a nutritional supplement to exercised horses

In order to ensure the welfare of performance horses and riders as well as the integrity of the sport, the use of both therapeutic and illegal agents in horse racing is tightly regulated. While Dehydroepiandrosterone (DHEA) is not specifically banned from administration to racehorses in the United States and no screening limit or threshold concentration exists, the metabolic conversion of DHEA to testosterone make its presence in nutritional supplements a regulatory concern. The recommended regulatory threshold for total testosterone in urine is 55 and 20 ng/mL for mares and geldings, respectively. In plasma, screening and confirmation limits for free testosterone (mares and geldings), of no greater than 0.1 and 0.025 ng/mL, respectively are recommended. DHEA was administered orally, as part of a nutritional supplement, to 8 exercised female thoroughbred horses and plasma and urine samples collected at pre-determined times post administration. Using liquid chromatography-mass spectrometry (LC-MS), plasma and urine samples were analyzed for DHEA, DHEA-sulfate, testosterone, testosterone-sulfate, pregnenolone, androstenedione, and androstenediol. DHEA was rapidly absorbed with maximal plasma concentrations reaching 52.0 ± 43.8 ng/mL and 32.1 ± 12.9 ng/mL for DHEA and DHEA sulfate, respectively. Free testosterone was not detected in plasma or urine samples at any time. Maximum sulfate conjugated testosterone plasma concentrations were 0.98 ± 1.09 ng/mL. Plasma testosterone-sulfate concentrations did not fall below 0.1 ng/mL and urine testosterone-sulfate below 55 ng/mL until 24-36 h post DHEA administration. Urine testosterone sulfate concentrations remained slightly above baseline levels at 48 h for most of the horses studied.

Phase I clinical trial of oral rosiglitazone in combination with intravenous carboplatin in cancer-bearing dogs

Rosiglitazone is an FDA-approved peroxisome proliferator-activated receptor gamma (PPARγ) agonist and antidiabetic agent in humans that has been investigated for its ability to reduce tumor cell growth. The purpose of this study was to determine the maximally tolerated dose, peak plasma concentrations and side effect profile of oral rosiglitazone when combined with carboplatin in dogs with cancer. Rosiglitazone was administered at 6 and 8 mg/m(2) to seven dogs. Carboplatin was administered at 240-300 mg/m(2) in combination with rosiglitazone. For toxicity evaluation, the toxicity data for the seven dogs in this study were combined with the toxicity data from three dogs previously reported in a methodology study. Peak plasma rosiglitazone concentrations varied with dose. The dose-limiting toxicity was hepatic at a dose of 8 mg/m(2). Three dogs had mild to moderate alanine aminotransferase elevations but no changes in total bilirubin, alkaline phosphatase, blood glucose or γ-glutamyltranspeptidase values were noted.

Pharmacokinetic and pharmacodynamics of xylazine administered to exercised thoroughbred horses

There is limited data describing xylazine serum concentrations in the horse and no reports of concentrations beyond 24 hours. The primary goal of the study reported here was to update the pharmacokinetics of xylazine following intravenous (IV) administration in order to assess the applicability of current regulatory recommendations. Pharmacodynamic parameters were determined using PK-PD modeling. Sixteen exercised adult Thoroughbred horses received a single IV dose of 200 mg of xylazine. Blood and urine samples were collected at time 0 and at various times for up to 96 hours and analyzed using liquid chromatography tandem mass spectrometry. Xylazine serum concentrations were best fit by a 3-compartment model. Mean ± SEM systemic clearance, volume of distribution at steady state, beta half-life and gamma half-life were 12.7 ± 0.735 mL/min/kg, 0.660 ± 0.053 L/kg, 2.79 ± 0.105 hours and 26.0 ± 1.9, respectively. Immediately following administration, horses appeared sedate as noted by a decrease in chin-to-ground distance, decreased locomotion and decreased heart rate (HR). Sedation lasted approximately 45 minutes. Glucose concentrations were elevated for 1-hour post administration. The EC50 (IC50) was 636.1, 702.2, 314.1 and 325.7 ng/mL for HR, atrioventricular block, chin-to-ground distance and glucose concentrations, respectively. The Emax (Imax) was 27.3 beats per minute, 47.5%, 42.4 cm and 0.28 mg/dL for HR, atrioventricular block, chin-to-ground distance and glucose concentrations, respectively. Pharmacokinetic parameters differ from previous reports and a prolonged detection time suggests that an extended withdrawal time, beyond current regulatory recommendations, is warranted to avoid inadvertent positive regulatory findings in performance horses. Copyright