Absorption, Biokinetics, and Metabolism of the Dopamine D2 Receptor Agonist Hordenine (N,N-Dimethyltyramine) after Beer Consumption in Humans.

Hordenine, a natural constituent of germinated barley, is a biased agonist of the dopamine D2 receptor. This pilot study investigated the biokinetics of hordenine and its metabolites in four volunteers consuming beer equal to 0.075 mg hordenine/kg body weight. A new ultrahigh-performance liquid chromatography method coupled to electrospray ionization tandem mass spectrometry (UHPLC-ESI-MS/MS) method determined maximum plasma concentrations of 12.0-17.3 nM free hordenine after 0-60 min. Hordenine phase-II metabolism was first dominated by sulfation, but later by glucuronidation. The elimination half-lives in plasma were 52.7-66.4 min for free hordenine and about 60/80 min longer for hordenine sulfate and hordenine glucuronide. Urinary excretion peaked 2-3.5 h after consumption and accumulated to 3.78 µmol within 24 h, corresponding to 9.9% of the ingested dose. The observed hordenine levels in plasma seem too low to provoke direct interaction with the dopamine D2 receptor related to food reward, but synergistic or additive effects with alcohol or N-methyltyramine may occur.

Influence of hepatic impairment on the pharmacokinetics of the dopamine agonist rotigotine.

The transdermally applied dopamine receptor agonist rotigotine is extensively metabolized in the liver. An open-label, parallel-group study was conducted to evaluate the effects of moderate hepatic impairment on the pharmacokinetics, safety and tolerability of rotigotine. Eight subjects with normal hepatic function and nine with moderate hepatic impairment (Child-Pugh class B) received one rotigotine transdermal patch (providing a dose of 2 mg/24 h) daily for 3 days with a 24-h patch-on period. Blood and urine samples were collected to evaluate pharmacokinetic parameters characterizing drug bioavailability and elimination. Primary variables included plasma and urine concentrations of unconjugated rotigotine (active parent compound) and total rotigotine (unconjugated rotigotine plus sulfate and glucuronide conjugates) under steady-state (SS) conditions. For unconjugated rotigotine, point estimates for the ratios of AUC(0-24)SS and C max,SS between the two groups (normal vs. impaired hepatic function) were near 1: AUC(0-24)SS, 0.90 (90 % CI 0.59, 1.38) and C max,SS, 0.94 (90 % CI 0.66, 1.35); t max,SS and t 1/2 were lower in subjects with hepatic impairment, while renal clearance was unaffected and overall clearance was higher. For total rotigotine, C max,SS was higher in subjects with hepatic impairment compared with those with normal hepatic function (P = 0.0239, ANOVA). A tendency to reduced non-renal clearance was observed in subjects with hepatic impairment, consistent with their higher plasma concentrations of total rotigotine. Thus, moderate hepatic impairment did not influence the pharmacokinetics of unconjugated rotigotine under steady-state conditions suggesting that dose adjustment will not be required for patients with mild or moderate hepatic insufficiency. In addition, the rotigotine patch was well tolerated in subjects with moderate hepatic impairment.

Absorption, disposition, metabolic fate, and elimination of the dopamine agonist rotigotine in man: administration by intravenous infusion or transdermal delivery.

The dopamine agonist rotigotine was developed for the treatment of Parkinson's disease and restless legs syndrome. Disposition, metabolism, elimination, and absolute bioavailability of rotigotine were determined in six healthy male subjects by using two different forms of administration in a randomized sequence with a crossover design. Treatment A (continuous infusion) consisted of a single radiolabeled 12-h intravenous infusion of 1.2 mg of rotigotine (0.6 mg of [(14)C] and 0.6 mg of unlabeled rotigotine, 3.7 MBq) solution. Treatment B (transdermal application) consisted of a single 10-cm(2) patch containing 4.5 mg of unlabeled rotigotine with a patch-on period of 24 h. During the 12 h-infusion, total radioactivity concentration rapidly increased within 2 h; there was a slight additional increase toward the end of infusion. Plasma concentrations of total radioactivity declined by 75% within 12 h after completion of infusion. More than 94% of the radioactivity was excreted 216 h after the start of infusion, 71% by the kidneys and 23% by feces. Renal elimination of the parent compound was <1%. Systemically absorbed rotigotine was rapidly metabolized. The major rotigotine biotransformation pathway was conjugation of the parent compound, mainly by sulfation; a second pathway was the formation of phase 1 metabolites (N-desalkylation) with subsequent conjugation. Plasma concentration-time profiles of unchanged rotigotine during and after infusion and during and after patch administration were comparable. Absolute bioavailability of transdermally applied rotigotine was 37%.

Chemically modified carbon paste electrode for the potentiometric flow injection analysis of piribedil in pharmaceutical preparation and urine.

A new carbon paste electrode selective for piribedil (PD) was prepared and fully characterized in terms of composition, usable pH range, response time and thermal stability. The electrode active recognition is by liquid ion-exchange mechanism via the use of piribedil phosphomolybdate as ion-exchanger dissolved in tricresyl phosphate as a more suitable solvent mediator for the paste. The modified electrode showed a Nernstian slope of 58.4+/-0.6 mV over the concentration range of 7.5 x 10(-7) to 1 x 10(-3)M with an average recovery of 98.3-101.0% and R.S.D. of 0.45-1.31%. The electrode exhibits good selectivity for PD with respect to a large number of inorganic cations, organic cations, sugars and amino acids. The developed electrode was successfully used for the potentiometric determination of PD in its aqueous solutions, pharmaceutical preparation, and urine in batch and flow injection analysis (FIA).

Erythromycin increases plasma concentrations of alpha-dihydroergocryptine in humans.

OBJECTIVE: Our objective was to investigate the potential for relevant pharmacotherapeutic interaction between cytochrome P4503A4 (CYP3A4)-inhibiting agents such as erythromycin and the dopamine agonist alpha-dihydroergocryptine (DHEC). METHODS: The study was carried out as a single-center, controlled, nonblinded, 2-way crossover clinical trial with randomly allocated period-balanced sequences, investigating two treatments of a single oral dose of 10 mg DHEC (on the morning of day 1), once administered alone (reference), once along with a 4-day treatment (days -2 to 1) of 500 mg erythromycin 3 times daily. Periods were separated by a washout of at least 14 days. Nine healthy white male volunteers, 22 to 42 years old, with a body weight range of 58 to 90 kg (body mass index, 20.2-25.1 kg x m(-2)) began the study. One subject discontinued prematurely, and 8 concluded the study in accordance with the study protocol. RESULTS: The plasma and urinary pharmacokinetics of DHEC and its metabolites were characterized by a large variability. Concomitant treatment with erythromycin led to respective increases of 9.5 (95% confidence interval [CI], 6.5 to 13.9) and 16.5 (95% CI, 8.7 to 31.5) times the maximum observed plasma drug concentration and the area under the time course of the plasma concentrations up to the last quantifiable concentration after dosing of unchanged DHEC (determined by radioimmunoassay). The 24-hour urinary excretion was on average 11 times larger (95% CI, 5.9 to 20.7). Qualitatively similar findings were recorded for the total of DHEC plus metabolites (as determined by enzyme immunoassay). CONCLUSIONS: The concomitant use of erythromycin or similarly CYP3A4-inhibiting agents along with direct dopaminergic agonists such as the ergoline DHEC may cause a clinically relevant increase in pharmacokinetic exposure, which may induce exaggerated dopaminergic effects.

Plasma and urine pharmacokinetics of the dopamine agonist alpha-dihydroergocryptine in patients with hepatic dysfunction.

OBJECTIVE: The aim of this study was to evaluate the pharmacokinetic behavior of unchanged alpha-dihydroergocryptine (DHEC, Almirid, Desitin Arzneimittel GmbH, Hamburg, Germany, under licence of Polichem S.A., Luxembourg) and total DHEC (unchanged DHEC and pooled metabolites) in plasma and urine in patients with impaired hepatic function, following administration of single oral doses. METHODS: The study was carried out according to an open, uncontrolled, parallel-group design, investigating two study groups: patients with hepatic dysfunction, i.e. with evidence of stable cirrhosis (n = 10) and age- and sex-matched healthy subjects (n = 8). Each subject received a single dose of 20 mg DHEC. Blood samples were taken at specified intervals up to 72 h after dosing and urine was collected fractionally for 24 h. Concentrations of unchanged DHEC were determined by RIA and concentrations of total DHEC (unchanged and pooled metabolites) by EIA. RESULTS: The plasma and urinary pharmacokinetics of DHEC and its metabolites were characterized by large variability. In patients with impaired hepatic function, the geometric mean Cmax and AUC(0-infinity) values for unchanged DHEC were 571.3 pg/ml (CV: 0.87) and 4038 pg x h/ml (CV: 1.04) and were approximately 2 times (2.04, 95% CI: 0.93 to 4.46 and 2.11, 95% CI: 0.58 to 7.73 for Cmax and AUC(0-infinity), respectively) larger than those measured in age-matched healthy controls. The 24-hour urinary excretion was approximately 3 times (3.41, 95% CI: 0.95 to 12.21) higher in patients with hepatic dysfunction. Similar results were obtained for total DHEC. CONCLUSIONS: The results reflect an increased systemic exposure in patients with impaired hepatic function which is not due to a reduced urinary excretion/elimination or reduced renal clearance. The most likely mechanism involved is a reduction in pre-systemic biotransformation. The observed range of effects on the pharmacokinetics of DHEC in patients with compromized hepatic function does not suggest the need to revise the dosage recommendations, since treatment with DHEC is generally started with low doses and is slowly up-titrated according to the individual response and the occurrence of adverse effects. Nevertheless, lower maintenance doses are likely to be achieved.

The effect of food on cabergoline pharmacokinetics and tolerability in healthy volunteers.

The effect of food on the pharmacokinetics and tolerability of cabergoline in man was investigated. For this purpose an open, randomized, single-dose study was conducted in 12 healthy male volunteers who received 1 mg cabergoline as tablets both under fasting conditions and after a breakfast containing a substantial amount of carbohydrates, fat, and proteins, in a crossover fashion. The two treatments were separated by a 4 week washout period. Plasma and urine were collected up to 336 and 168 h respectively after administration and cabergoline concentration was measured in both fluids using a validated radioimmunoassay. Tolerability assessment included haematology, blood chemistry, and urinalysis, blood pressure and heart rate measurements, and ECG. Under both fasting and fed conditions low but persistent cabergoline plasma levels were observed in the present study up to 2 weeks after drug intake, in agreement with the long-lasting prolactin-lowering activity of the drug. In subjects receiving cabergoline under fed or fasting conditions, Cmax values averaged 44 and 54 pg mL(-1), AUC(0-336 h) averaged 6392 and 5331 pg h mL(-1), Ae(0-168 h) averaged 12.7 and 11.9 micrograms, and t1/2 averaged 109.7 and 101.3 h, respectively. No statistically significant difference was found when Cmax, AUC(0-336 h), t1/2, and Ae(0-168 h) from subjects treated under fasting and fed conditions were compared. Median tmax values in subjects treated under fasting or fed conditions were identical (2.5 h). The statistical analysis applied to the parameters chosen to evaluate the variations in the blood pressure profiles observed either supine or standing did not show any significant difference between the fed and fasting conditions. Heart rate values were not significantly modified after cabergoline under either fed or fasting conditions. Laboratory evaluation showed some minor deviations from normal, which were not clinically relevant (only one subject showed an occasional and transient elevation in alkaline phosphatase which disappeared in the subsequent laboratory evaluations) and were considered for the most part not to be drug related. Eleven subjects reported adverse events (one after both treatments, five only after drug intake under fasting conditions, and five only after drug intake with food.