Changes in concentrations of lysergol in urine and prolactin in plasma, rectal temperature and respiration rate in sheep selected for resistance or susceptibility to ryegrass staggers and fed ergovaline.

AIM: To determine the effects of feeding ryegrass seed containing ergovaline to sheep selected for resistance or susceptibility to ryegrass staggers on concentration of lysergol (a metabolite of ergovaline) in urine, prolactin in plasma, rectal temperature and respiration rate. METHODS: Two experiments were carried out using 12 Romney crossbred ewe lambs aged 9 months, comprising animals resistant (n=4), susceptible (n=4) or outcross (n=4) to ryegrass staggers. In Experiment 1, sheep were given either a single (Part A) or six (Part B) feed (s) of endophyte-infected seed containing ergovaline at 30 mg/kg dry matter (DM), at 42 µg ergovaline/kg bodyweight (BW), to simulate acute and chronic exposure to ergovaline, respectively. The concentration and excretion of lysergol in urine and concentration of prolactin in plasma were measured over 3 and 12 days, for Parts A and B respectively. In Experiment 2, after a recovery period of 7 days, the same sheep were fed with ergovaline at 67 µg/kg of BW for 7 days. Soon after the seventh feed the sheep were moved to a hothouse at 36.5°C and 60% humidity, and 3 h later their rectal temperatures and respiration rates were measured. RESULTS: The concentration of lysergol and excretion in urine increased to a peak between 6 and 9 h after exposure to ergovaline whereas the concentration of prolactin in plasma was markedly reduced. Differences in concentration and rate of excretion of lysergol in urine between animals resistant, outcross and susceptible to ryegrass staggers were not significant (p>0.1). The animals resistant to ryegrass staggers had a lower rectal temperature (p<0.05) and a faster respiration rate than the outcross and susceptible groups when exposed to high ambient temperature and high humidity. CONCLUSIONS: This study showed that excretion of lysergol in urine increased with each exposure of sheep to ergovaline. Animals genetically resistant to ryegrass staggers exhibited a lower rectal temperature and a faster respiration rate than those susceptible, demonstrating the possible cross resistance of sheep to ergovaline in a population originally selected for resistance to ryegrass staggers. Hence potential exists to select animals resistant to ryegrass staggers that are also resistant to ergovaline.

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.

Disposition and urinary metabolic pattern of cabergoline, a potent dopaminergic agonist, in rat, monkey and man.

1. The disposition and urinary metabolic pattern of 14C-cabergoline was studied in rat, monkey and man after oral administration of the labelled drug. 2. In all species radioactivity was mainly excreted in faeces, with urinary excretion accounting for 11, 13 and 22% of the dose in rat, monkey and man, respectively. 3. After oral treatment, biliary excretion of radioactivity in rat accounted for 19% of the dose within 24 h. 4. Unchanged drug in 0-24-h urine samples of rat, monkey and man amounted to 20, 9 and 10% of urinary radioactivity, respectively. In the 24-72-h urine samples of all species the relative percentage of unchanged drug increased compared with that measured in the 0-24-h urine. 5. The main metabolite was the acid derivative (FCE 21589), which in 0-24-h urine samples of rat, monkey and man accounted for 30, 21 and 41% of urinary radioactivity, respectively. 6. Other metabolites identified in urine of all species resulted from hydrolysis of the urea moiety, the loss of the 3-dimethylaminopropyl group and the deallylation of the piperidine nitrogen.

Determination of cabergoline in plasma and urine by high-performance liquid chromatography with electrochemical detection.

A sensitive and selective high-performance liquid chromatographic method for the determination of cabergoline in plasma and urine has been developed. After buffering plasma and urine samples, cabergoline was extracted with a methylene chloride-isooctane mixture, back-extracted into 0.1 M phosphoric acid, then analysed by reversed-phase high-performance liquid chromatography. Quantitation was achieved by electrochemical detection of the eluate. The linearity, precision and accuracy of the method were evaluated. No interference from the biological matrices (human plasma and urine) was observed. The assay was still inadequate in terms of sensitivity for the quantitation of cabergoline plasma concentrations after a single oral dose of 1 mg of the drug to humans, but was successfully used in the determination of the urinary excretion of the drug.

Disposition of the novel serotonin agonist, LY228729, in monkeys and rats.

The disposition of a novel 5HT-1a agonist, LY228729, was studied in rats after oral administration and in monkeys after both i.v. and oral administration of a radiolabeled drug. Plasma concentrations of LY228729 declined with a half-life of 2.3 and 1.5 hr in monkeys after oral dosing and i.v. administration, respectively, and 1.9 hr in rats dosed orally. Peak plasma concentrations of the N-despropyl metabolite were greater than the parent drug following oral administration in both rats and monkeys and declined with a half-life of 3.2-3.5 hr. Plasma levels of total radioactivity rapidly exceeded that of the parent drug in both species. Radioactivity was eliminated more slowly, with terminal half-lives of 39.4 hr in the monkey and 48.6 hr in the rat. The parent drug and its despropyl metabolite accounted for only a small percentage of the total radioactivity in the plasma. Following i.v. and oral administration, radioactivity was eliminated predominantly in the urine of monkeys, but was distributed evenly between the urine and feces of rats. Parent drug and the N-despropyl metabolite were the major products in rat urine. In the monkey, the major metabolite was an uncharacterized polar compound.

Excretion balance and urinary metabolic pattern of [3H]cabergoline in man.

After oral administration of [3H]cabergoline to man at a single nominal dose of 0.6 mg/subject radioactivity is mainly eliminated by the faecal route (72% of the dose after 10 days). Urine contains 18% of the dose after the same period. The unchanged drug and metabolites present in urine were identified by comparison with reference compounds and quantified by radio-TLC analysis. Cabergoline is extensively metabolized. Unchanged drug in 0-24 h urine represents less than 14% of urinary radioactivity, reaching 20% in 0-96 h urine. The acid derivative FCE 21589 is the main metabolite, amounting to 38% and 30% of the urinary radioactivity in 0-24 h and 0-96 h urine, respectively. The amide derivative FCE 21590 appears to be present in only a small amount, accounting for no more than 4% of the urinary radioactivity in the urine of the first 24 hours after administration and increasing to about 8% in the 0-96 h urine.

Metabolic fate of FCE 22716, a new antihypertensive agent, and of its N-oxide (FCE 24220) in the rat.

[3H]-FCE 22716 and [3H]-FCE 24220 were given both orally and intravenously to the rat. Radioactivity was mainly eliminated by the faecal route after oral administration in both cases. After intravenous administration, renal excretion was twice the faecal one in the case of FCE 22716, whereas for FCE 24220 the two routes were equal. In urine FCE 22716 was eliminated almost completely unchanged after both oral and intravenous administration. FCE 24220 was extensively reduced to FCE 22716 after oral administration, whereas after intravenous treatment, this reduction, although important, was not complete.

Disposition and biotransformation of quinpirole, a new D-2 dopamine agonist antihypertensive agent, in mice, rats, dogs, and monkeys.

The disposition and metabolism of quinpirole were studied in rats, mice, dogs, and monkeys. A single 2 mg/kg dose of 14C-quinpirole was administered orally to rats, mice, and monkeys. Dogs were given a single 0.2 mg/kg iv dose of 14C-quinpirole. Of the dose administered, 75-96% was recovered in the urine within 72 hr, with the majority being excreted during the first 24 hr. Peak plasma concentrations of radioactivity and quinpirole were coincident and were observed within 0.25 hr in rodents and at 2 hr in monkeys. Unchanged quinpirole accounted for 0.9%, 36%, and 69% respectively. Biotransformation of quinpirole was compared by quantitating the urinary metabolites by HPLC. The percentage of the radioactivity in urine representing unchanged drug was determined for each species: monkey (3%), dog (13%), mouse (40%), and rat (57%). The majority of 14C-quinpirole was shown to be biotransformed in rats, mice, and monkeys through common metabolic pathways but to various extents. Most metabolites resulted from structural alterations (N-dealkylation, lactam formation, omega and omega-1 hydroxylation) that centered around the piperidine ring portion of the molecule. These metabolites were less important in dogs. The major metabolic pathway in dogs involved hydroxylation of a methylene carbon adjacent to the pyrazole nucleus of quinpirole followed by O-glucuronidation. Evidence of metabolism of the pyrazole moiety was found in the isolation of an N-glucuronide conjugate of quinpirole from monkey urine.

Physiologic disposition of pergolide.

Pergolide, a synthetic ergoline, is a potent long-acting dopaminergic drug effective in Parkinson's disease and amenorrhea-galactorrhea. After 138 micrograms 14C-pergolide orally to healthy subjects, radioactivity was present in plasma and red blood cells. Salivary radioactivity was one third to one tenth that in plasma. Radioactivity in plasma appeared after 15 to 30 min, peaked at 1 to 2 hr, and was barely detectable after 96 hr. Plasma radioactivity was not attributable to pergolide, and the levels did not correlate well with the duration of the prolactin-lowering effect induced by pergolide. Pergolide became bound to several plasma proteins and could not be displaced by other drugs that are also bound or by possible metabolites of pergolide. Radioactivity was eliminated as pergolide metabolites in urine (55%), feces (40%), and breath (5%, as 14CO2).