The bioavailability and pharmacokinetics of ibuprofen, a nonsteroidal antiinflammatory drug, was studied in healthy Shetland ponies. Ibuprofen was administered IV, as a suspension, and as a solid solution oral paste to ponies from which food was withheld. The suspension paste was also administered to ponies that received hay and water ad libitum. Both formulations had an absolute bioavailability of about 80%. Bioavailability was not influenced by feeding.

To determine the effect of oral administration of prednisolone on thyroid function, 12 healthy Beagles were given 1.1 mg of prednisolone/kg of body weight every 12 hours for 22 days after 8 days of diagnostic testing of the dogs before treatment with prednisolone. Thyroid-stimulating hormone (TSH) and thyrotropin-releasing hormone (TRH) response tests were performed before treatment (days 1 and 8 of the study) and during treatment (days 21 and 28 of the study). Blood samples were collected daily at 8 AM and 2 and 8 PM to rule out normal daily hormone fluctuations as the cause of a potential decrease in serum triodothyronine (T3), thyroxine (T4), and free T4 (fT4) concentrations. Serum T3, T4, and fT4 concentrations before treatment and 1 day and 21 days after the first prednisolone dose were compared by analyses of variance. Post-TSH and -TRH serum T3 and T4 concentrations before and during treatment were compared, using the Student t test for paired data. Oral administration of prednisolone significantly (P < 0.005) decreased serum T3, T4, and fT4 concentrations in the 8 AM and 2 and 8 PM samples obtained 1 day and 21 days after the first prednisolone dose. Serum T4 and fT4 concentrations in 8 AM and 2 PM samples were significantly (P < 0.05) lower 21 days after the first prednisolone dose than they were at 1 day after the first dose. Before treatment, serum T4 concentration in the 2 PM samples was significantly (P < 0.05) higher than serum T4 concentration in 8 AM and 8 PM samples. Oral administration of prednisolone significantly (P < 0.01) decreased serum T3 and T4 concentrations 6 hours after TSH and TRH injections. Significant difference in the mean incremental change in serum T3 and T4 concentrations was not observed when comparing before- and during prednisolone treatment values for the TRH response test. However, for the TSH response test, the mean incremental changes in serum T3 and T4 concentrations were significantly (P < 0.01) lower during prednisolone treatment. Despite the decreased TSH response incremental change in serum T4 concentration during oral treatment with prednisolone, the lowest value observed fell within the before-treatment range. In addition, during treatment, baseline serum T3 and T4 concentrations after TSH administration increased, on average, 3.7 and 8.4 times, respectively.

The growth hormone (GH) secretagogue activity of variable dosages of clonidine (16.5, 50, 150, and 450 microgram/kg of body weight), given orally mixed with the daily food ration, was evaluated in young and old dogs. Significant (P < 0.05) increase in plasma GH concentration was detected at all dosages tested in young dogs and in response to all but the lowest dose tested in the old dogs fed the clonidine-containing diet. Old dogs had plasma GH concentration that exceeded that of young dogs when higher doses of clonidine were used. A clonidine (100 microgram/kg)-supplemented diet was fed to middle-aged dogs twice daily for 30 days. Significant (P < 0.01) increase of plasma GH concentration was observed on the first day of the feeding trial, but was undetectable by day 30. After feeding the clonidine-enhanced diet for 30 days, the effects on thymic morphology were variable, and there was no effect on plasma thymulin titer. Clonidine-fed dogs had significantly increased lymphocyte blastogenic responsiveness to mitogens, compared with that of control dogs, when evaluated as stimulation index.

Six mature Holstein bulls were each given 10 mg of phenylbutazone (PBZ)/kg of body weight, PO. Of the 6 bulls, 3 were given 10 mg of PBZ/kg by rapid IV administration 4 weeks later. Plasma concentration-vs-time data were analyzed, using nonlinear regression modeling (sum of exponential functions). The harmonic mean of the biologic half-life of PBZ was 62.6 +/- 12.9 hours after oral administration and 61.6 +/- 7.2 hours after IV administration. The mean residence time was 94.61 +/- 8.44 hours and 90.49 +/- 8.93 hours for oral and IV administration, respectively. The mean total body clearance was 0.0015 +/- 0.0003 L/h/kg, with the mean apparent volume of distribution 0.134 +/- 0.021 L/kg. Mean bioavailability was 73 +/- 2% after oral administration. Phenylbutazone was adequately absorbed from the gastrointestinal tract in bulls. The apparent volume of distribution was small, indicating that PBZ distributed mainly into plasma and extracellular fluid. The total body clearance was also small, which accounted for the long half-life of PBZ in bulls.

Six mature Holstein bulls were given an 8-day course of phenylbutazone (PBZ) orally (loading dose, 12 mg of PBZ/kg of body weight and 7 maintenance doses of 6 mg of PBZ/kg, q 24 h). Plasma concentration-vs-time data were analyzed, using nonlinear regression modeling. The harmonic mean +/- pseudo-SD of the biologic half-life of PBZ was 61.8 +/- 12.8 hours. The arithmetic mean +/- SEM of the total body clearance and apparent volume of distribution were 0.0021 +/- 0.0001 L/h/kg and 0.201 +/- 0.009 L/kg, respectively. The predicted mean minimal plasma concentration of PBZ with this dosage regimen was 75.06 +/- 4.05 microgram/ml. The predicted minimal plasma drug concentration was compared with the observed minimal plasma drug concentration in another group of bulls treated with PBZ for at least 60 days. Sixteen mature Holstein bulls were given approximately 6 mg of PBZ/kg, PO, daily for various musculoskeletal disorders. The mean observed minimal plasma concentration of PBZ in the 16 bulls was 76.10 +/- 2.04 microgram/ml, whereas the mean predicted minimal plasma concentration was 74.69 +/- 3.10 microgram/ml. Dosages of 4 to 6 mg of PBZ/kg, q 24 h, or 10 to 14 mg of PBZ/kg, q 48 h, provided therapeutic plasma concentrations of PBZ with minimal steady-state concentrations between 50 and 70 microgram/ml.

Clorazepate dipotassium was administered orally to 8 healthy dogs at a dosage of 2 mg/kg of body weight, q 12 h, for 21 days. Serum disposition of nordiazepam, the principle metabolite of clorazepate, was determined after the first and last dose of clorazepate. Disposition variables were analyzed by use of model-independent pharmacokinetics by the predictive equations method and the trapezoidal rule method. Complete blood counts, serum chemical analyses, and urinalyses were performed before administration of clorazepate and at 10 and 21 days after administration of clorazepate. Maximal nordiazepam concentrations ranged from 446 to 1,542 ng/ml (814 +/- 334 ng/ml), at 59 to 180 minutes (97.9 +/- 42.0 minutes) after a single oral dose of clorazepate. Maximal nordiazepam concentrations ranged from 927 to 1,460 ng/ml (1,308 +/- 187.6 ng/ml), at 120 to 239 minutes (153 +/- 57.9 minutes) after multiple oral doses of clorazepate. Serum disposition was significantly altered after multiple doses of clorazepate. Using data determined by the predictive equations method, the mean residence time after multiple doses (712 +/- 214 minutes) was longer (P less than 0.05) than after a single dose (527 +/- 95.8 minutes). Oral volume of distribution after multiple doses of clorazepate (1.76 +/- 0.647 L/kg) was smaller (P less than 0.02) than after a single dose (3.18 +/- 1.52 L/kg). Oral clearance after multiple doses of clorazepate (3.09 +/- 0.726 milliliter/min/kg) was less (P less than 0.001) than after a singledose (6.54 +/- 2.15 ml/min/kg). Absorption half-life after multiple doses (72 minutes) was longer (P less than 0.01) than after a single dose (33 minutes). The elimination half-life after a single dose (284 minutes) was not significantly different after multiple doses (355 minutes). Significant changes (P less than 0.05) in serum chemical values after multiple doses of clorazepate included decreased concentrations of albumin, total protein, and calcium and increased concentrations of urea nitrogen and glucose. Serum activities of alkaline phosphatase and alanine transaminase increased after multiple doses of clorazepate. Significant changes (P less than 0.05) in the hemogram included increased total WBC count, segmented neutrophils, lymphocytes, and eosinophils. Urine pH after multiple doses (5.88 +/- 0.641) was lower (P less than 0.01) than after a single dose (7.44 +/- 1.29). All changes in laboratory values remained within our reference ranges. Mild sedation and ataxia developed in only 1 dog after the first dose of clorazepate. These effects were transient and did not redevelop with additional dosing. An oral clorazepate dosage of 2 microgram/kg, q 12 h, maintains serum nordiazepam concentrations considered to be therapeutic in human beings (500 to 1,900 ng/ml).

A specific thromboxane synthetase inhibitor, 3-methyl-2 (3-pyridyl)-1-indoleoctanoic acid (CGS 12970) was administered orally to 6 healthy adult Beagles at a dosage of 30 mg/kg of body weight. Blood generation of thromboxane B2 and urinary excretion of thromboxane B2 were measured before and after administration of CGS 12970. Although 97 +/- 0.4% inhibition of thromboxane B2 generation was observed within 2 hours after a single dose of CGS 12970 was administered orally, an effect on urinary excretion of thromboxane B2 was not observed. Additionally, oral administration of 30 mg/kg every 12 hours resulted in 80 +/- 14% inhibition of thromboxane B2 generation but had no effect on urinary thromboxane B2 excretion.

Disposition kinetics of cloxacillin were examined in calves after topical administration of benzathine cloxacillin and single IV administration of sodium cloxacillin, and the susceptibility of 17 field isolates of Moraxella bovis was measured. For the IV pharmacokinetic phase, sodium cloxacillin was administered at dosage of 10 mg/kg of body weight to male Holstein calves (n = 6, weighing 146 to 170 kg), and serum concentration of cloxacillin was measured thereafter for 10 hours. For the ocular pharmacokinetic phase, 6 calves were given either of 4 benzathine cloxacillin topical formulations consisting of 50-, 125-, 250-, or 375-mg doses. Treatment was repeated every 10 days until all 4 benzathine cloxacillin dosages were tested in the same 6 calves. Blood and tears were collected for 72 hours after each benzathine cloxacillin formulation was administered, and the concentration of cloxacillin in each specimen was measured, using a bioassay. The minimal inhibitory concentration of cloxacillin for 17 field isolates of M bovis was determined by use of an agar pour-plate dilution assay. After single IV administration of sodium cloxacillin, its half-life, body clearance, and volume of distribution were 19.5 +/- 12.8 minutes, 18.3 +/- 2.2 ml/min.kg, and 496 +/- 290 ml/kg, respectively. After topical administration of benzathine cloxacillin, cloxacillin concentration in lacrimal fluid peaked between 30 and 45 minutes and ranged between 963 microgram/ml and 3,256 microgram/ml for the 125- and 375- mg doses, respectively. There was no detectable cloxacillin activity in the lacrimal fluid of any calf by 36 hours after topical administration of benzathine cloxacillin, and cloxacillin was not detected in the serum at any time. The mean lacrimal fluid cloxacillin concentration for the 4 groups during the first 8 hours was not significantly different; however, by 12 hours, the cloxacillin concentration in tears from calves of the 250- and 375-mg groups was significantly (P < 0.05) greater than that in calves of the 50- and 125-mg groups. Cloxacillin concentration greater than or equal to 3.13 microgram/ml was maintained for a significantly (P < 0.05) longer time after treatment, using the 375-mg dose, compared with the 50-mg dose of benzathine cloxacillin. The minimal inhibitory concentration of cloxacillin for 1 isolate was 6.25 microgram/ml, but was less than or equal to 3.13 microgram/ml for 16 other M bovis isolates.

A 2 X 2 crossover design trial was conducted in gilts to determine the bioavailability and pharmacokinectics of tetracycline hydrochloride. The bioavailability of tretracycline hydrochloride administered orally to fasted gilts was approximately 23%. After intravascular administration, the disposition kinetics of tetracycline in plasma were best described by a triexponential equation. The drug had a rapid distribution phase followed by a relatively slow elimination phase, with half-life of 16 hours. Its large volume of distribution (4.5 +/- 1.06 L/kg) suggested that tetracycline is distributed widely in swine tissues. Total body clearance was 0.185 +/- 0.24 L/kg/h. Other pharamacokinectic variables were estimated. In a second trial, 3 gilts were fed a ration containing 0.55 g of tetracycline hydrochloride/kg of feed. Resulting plasma concentration of tetracycline was determined at selected times during 96 hours after exposure to the medicated feed. Plasma drug concentration peaked (0.6 microgram/ml) at 72 hours after access to the medicated feed.

Norfloxacin, a 4-quinolone antibiotic, was administered orally to 4 healthy dogs at dosages of 11 and 22 mg/kg of body weight, every 12 hours for 4 days, with a 4-week interval between dosing regimens. Serum and tissue cage fluid (TCF) norfloxacin concentrations were measured at 0, 0.5, 1, 1.5, 2, 3, 4, 5, 6, 8, 10, and 12 hours after the first and seventh dose of each dosing regimen. When administered at a dosage of 11 mg/kg, the mean peak serum concentration (Cmax) was 1.0 micrograms/ml at 1 hour, the time of mean peak concentration (Tmax) after the first dose. After the seventh dose, the Cmax was 1.4 micrograms/ml at Tmax of 1.5 hours. The Tmax for the TCF concentration was 5 hours, with Cmax of 0.3 micrograms/ml and 0.7 micrograms/ml after the first and seventh dose, respectively. When administered at a dosage of 22 mg/kg, the serum Tmax was 2 hours after the first dose, with Cmax of 2.8 micrograms/ml. After the seventh dose, the serum Tmax was 1.5 hours, with Cmax of 2.8 micrograms/ml. The Tmax for the TCF concentration was 5 hours after the first and seventh doses, with Cmax of 1.2 micrograms/ml and 1.6 micrograms/ml, respectively. After the seventh dose, the serum elimination half-life was 6.3 hours for a dosage of 11 mg/kg and was 6.7 hours for a dosage of 22 mg/kg. For serum concentration, the area under the curve from 0 to 12 hours (AUC0 leads to 12) was 8.77 micrograms.h/ml and 18.27 micrograms.h/ml for dosages of 11 mg/kg and 22 mg/kg, respectively. The corresponding AUC0 leads to 12 for the TCF concentration was 6.20 micrograms.h/ml and 16.42 micrograms.h/ml. The percentage of TCF penetration (AUC(TCF)/AUCserum) was 71% at a dosage of 11 mg/kg and 90% at a dosage of 22 mg/kg.