Pharmacokinetics of enrofloxacin and its metabolite ciprofloxacin after intravenous and oral administration of enrofloxacin in dogs

Rung, K., Riond, J.-L. & Wanner, M. Pharmacokinetics of enrofloxacin and its metabolite ciprofloxacin after intravenous and oral administration of enrofloxacin in dogs. J. vet
Four dogs were given 5 mg/kg body weight enrofloxacin intravenously (i.v.) and orally (p.o.) in a cross-over study. Plasma concentrations of the active ingredient enrofloxacin and its main metabolite ciprofloxacin were determined by a reversed phase liquid chromatographic method. Pharmacokinetic parameters of both substances were calculated by use of statistical moments and were compared to those of enrofloxacin described in the veterinary literature. Mean enrofloxacin t _½λZ was 2.4 h, mean Cl_s was 27.1 ml/min-kg, and mean V_ss was 7.0 1/kg. After i.v. and p.o. administration, concentrations of ciprofloxacin exceeding minimal inhibitory concentrations of several microorganisms were reached (C_max= 0.2 ng/ml, max = 2.2 h after intravenous administration; C_max= 0.2 (ig/ml, t _max= 3.6 h after oral administration). A considerable part of the antimicrobial activity is due to ciprofloxacin, the main metabolite of enrofloxacin.     

Pharmacokinetics of marbofloxacin in dogs after oral and parenteral administration

Six dogs were treated with a single intravenous (i.v.) dose (2 mg/kg) of marbofloxacin, followed by single oral (p.o.) doses of marbofloxacin at 1, 2 and 4 mg/kg, according to a three-way crossover design. The same experimental design was used for the subcutaneous (s.c.) route. In addition, a long-term trial involving eight dogs given oral doses of marbofloxacin at 2, 4 and 6 mg/kg/day for thirteen weeks was carried out. Plasma and urine samples were collected during the first two trials, plasma and skin samples were collected after the second of these trials. Plasma, urine and skin concentrations of marbofloxacin were determined by a reverse phase liquid chromatographic method. Mean pharmacokinetic parameters after i.v. administration were the following: t1/2β=12.4h; Cl _B= 0.10 L/h.kg; V _area= 1.9 L/kg. The oral bioavailability of marbofloxacin was close to 100% for the three doses. At 2 mg/kg, C _max of 1.4 μg/mL was reached at t _max of 2.5 h. Mean AUC and C _max values had a statistically significant linear relationship with the doses administered. About 40% of the administered dose was excreted in urine as unchanged parent drug. After s.c. administration, the calculated parameters were close to those obtained after oral administration, except t _max (about 1 h) which was shorter. The mean skin to plasma concentration ratio after the long-term trial was 1.6, suggesting good tissue penetration of marbofloxacin.     

Bioavailability of amprolium in fasting and nonfasting chickens after intravenous and oral administration

The bioavailability of amprolium (APL) was measured after intravenous (i.v.) and oral (p.o.) administration to chickens. Twelve healthy chickens weighing 1.28–1.41 kg received a dose of 13 mg APL/kg intravenously, and 13 or 26 mg APL/kg orally in both a fasted and a nonfasted condition in a Latin square design. Plasma samples were taken from the subwing vein for determination of APL concentration by HPLC method. The data following intravenous and oral administration were best fitted by 2-compartment and 1-compartment models, respectively, using weighted nonlinear least squares regression. The half-life beta t _½β, volume of distribution ( V d) and total body clearance ( Cl ) after intravenous administration were 0.21 h, 0.12 L/kg and 1.32 L/h.kg, respectively. The elimination half-life ( t _½ K_el) after oral administration was 0.292–0.654 h which is 1.5–3.2 times longer than after intravenous administration, suggesting the presence of a 'flip-flop' phenomenon in chickens. The maximum plasma concentration ( C _max) of 13 mg/kg APL administered orally to chickens during fasting was significantly (about four times) higher than that during nonfasting ( P < 0.05). Bioavailability during nonfasting was from 2.3 to 2.6%, and 6.4% during fasting.     

Pharmacokinetics, bioavailability and dosage regimen of sulphadiazine (SDZ) in camels (Camelus dromedarius)

The pharmacokinetics of sulphadiazine (SDZ) (100 mg/kg, body weight) were investigated in six camels ( Camelus dromedarius ) after intravenous (i.v.) and oral (p.o.) administration. Following i.v. administration, the overall elimination rate constant (β) was 0.029±0.001/h and the half-life ( t _½β) was 23.14±1.06 h. The apparent volume of distribution ( V d_(area)) was 0.790±0.075 L/kg and the total body clearance ( Cl _B) was 23.29±2.50 mL/h/kg. After p.o. administration, SDZ reached a peak plasma concentration ( C _max(cal.)) of 62.93±2.79 μg/mL at a post injection time of ( T _max(cal.)) 22.98±0.83 h. The elimination half-life was 19.79±1.22 h, not significantly different from that obtained by the i.v. route. The mean absorption rate constant (K_a) was 0.056±0.002 h⁻¹ and the mean absorption half-life ( t _½Ka) was 12.33±0.37 h. The mean availability ( F ) of sulphadiazine was 88.2±6.2%.
  To achieve and maintain therapeutically satisfactory plasma SDZ levels of 50 μg/mL, the priming and maintenance doses would be 80 mg/kg and 40 mg/kg intravenously and 90 mg/kg and 45 mg/kg orally, respectively, to be repeated at 24 h intervals.     

Pharmacokinetics of enrofloxacin in the red pacu (Colossoma brachypomum) after intramuscular, oral and bath administration

The intramuscular (i.m.), oral (p.o.), and bath immersion disposition of enrofloxacin were evaluated following administration to a cultured population of red pacu. The half-life for enrofloxacin following i.m. administration was 28.9 h, considerably longer than values calculated for other animals such as dogs, birds, rabbits, and tortoises. The 4 h maximum concentration ( C _max) of 1.64 μg/mL following a single 5.0 mg/kg dosing easily exceeds the in vitro minimum inhibitory concentration (MIC) for 20 bacterial organisms known to infect fish. At 48 h post i.m. administration, the mean plasma enrofloxacin concentration was well above the MIC for most gram-negative fish pathogens. The gavage method of oral enrofloxacin administration produced a C _max of 0.94 μg/mL at 6–8 h. This C _max was well above the reported in vitro MIC. A bath immersion concentration of 2.5 mg/L for 5 h was used in this study. The C _max of 0.17 μg/mL was noted on the 2 hour post-treatment plasma sample. Plasma concentrations of enrofloxacin exceeded published in vitro MIC's for most fish bacterial pathogens 72 h after treatment was concluded. Ciprofloxacin, an active metabolite of enrofloxacin, was detected and measured after all methods of drug administration. It is possible and practical to obtain therapeutic blood concentrations of enrofloxacin in the red pacu using p.o., i.m., and bath immersion administration. The i.m. route is the most predictable and results in the highest plasma concentrations of the drug.     

Serum and milk concentrations of apramycin in lactating cows, ewes and goats

A 20% solution of apramycin was administered intravenously (j.v.) and intramuscularly (i.m.) to lactating cows with clinically normal and acutely inflamed udders, to lactating ewes with normal or subclinically infected, inflamed udders and i.v. to lactating goats with normal udders. The i.v. disposition kinetics of apramycin was very similar in cows, ewes and goats. The elimination half-life was approximately 2 h and the steady-state volume of distribution was 1.26–1.45 L/kg. The absorption rate of the drug from the i.m. injection site was rapid, the i.m. bioavailability was 60–70% and the mean elimination half-life was 265 min in cows and 145.5 min in ewes. The binding percentage of apramycin to serum protein was low (< 22.5%). Concentrations of apramycin in milk produced by clinically normal mammary glands of cows, ewes and goats were consistently lower than in serum; the kinetic value AUC _milk/ AUC _serum was < 0.32. Drug penetration into the milk from the acutely inflamed quarters of cows was extensive; mastitis milk C _max values were more than tenfold greater than the C _max in normal milk. On the other hand, the drug had limited access to the milk produced by subclinically infected inflamed half-udders of ewes.     

Pharmacokinetics and tissue residues of norfloxacin and its N-desethyl- and oxo-metabolites in healthy pigs

The pharmacokinetic properties of norfloxacin were determined in healthy pigs after single intramuscular (i.m.) and intravenous (i.v.) dosage of 8 mg/kg body weight After i.m. and i.v. administration, the plasma concentration-time graph was characteristic of a two-compartment open model. After single i.m. administration, norfloxacin was absorbed rapidly, with a t _max of 1.46 ± 0.06 h. The elimination half-life ( t _1/2β) and the mean residence time of norfloxacin in plasma were 4.99 ± 0.28 and 6.05 ± 0.22 h, respectively, after i.m. administration and 3.65 ± 0.16 and 3.34 ± 0.16 h, respectively, after i.v. administration. Intramuscular bioavailability was found to be 53.7 ± 4.4%. Plasma concentrations greater than 0.2 μg/mL were achieved at 20 min and persisted up to 8 h post-administration. Maximal plasma concentration was 1.11 ± 0.03 μg/mL. Statistically significant differences between the two routes of administration were found for the half-lives of both distribution and elimination phases ( t _1/2α, t _1/2β) and apparent volume of distribution (V_d(area)). In pigs, norfloxacin was mainly converted to desethylenenorfloxacln and oxonorfloxacin. Considerable tissue concentrations of norfloxacin, desethylenenorfloxacin, and oxonorfloxacin were found when norfloxacin was administered intramuscularly (8 mg/kg on 4 consecutive days). The concentration of the parent fluoroquinolone in liver and kidney ranged between 0.015 and 0.017 μg/g on day 12 after the end of dosing.     

High performance liquid chromatography and pharmacokinetics of the non-steroidal anti-inflammatory drug oxindanac in calves

A high-performance liquid chromatographic method for the determination of the non-steroidal anti-inflammatory drug, oxindanac, in calf plasma is described. Recoveries over the concentration range 0.3 75 to 62.5 μg/ml were 90.2–107.8% with interassay coefficients of variation of 2.1–22.3%. The limit of detection was estimated as 0.10 μg/ml and the limit of quantification calculated to be 0.24 pg/ml in a 1 ml plasma sample. This method was used to establish the pharmacokinetics following intravenous (i.v.), intramuscular (i.m.) and oral (p.o.) administration to calves of oxindanac at a dose rate of 2 mg/kg. The elimination t ¹/₂, was long ( t 1/2 21.2 h after i.v. injection) and absorption was rapid (t¹/_2B 0.072 h) and complete ( F > 100%) following i.m. administration. Bioavailability was incomplete ( F = 66.6%) following p.o. administration to calves that had been fed on milk, and Wagner-Nelson analysis revealed twoabsorption phases ( t ¹/₂'s 0.20 and 1.9 h). Oxindanac produced long-lasting inhibition of serum TxB₂ production, with mean k_max values (% inhibition) of 96.8, 94.1 and 81.3 following i.v., i.m. and p.0. administration, respectively. A single i.v. or i.m. injection of 2 mg/kg oxindanac will probably be active in calves for at least 36–48 h.     

The disposition of suxibuzone in the horse

A high performance liquid chromatographic method is described to determine the anti-inflammatory drug suxibuzone (SXB) and its major metabolites phenylbutazone (PBZ) and oxyphenbutazone (OPBZ) in equine plasma and urine. When suxibuzone (6 mg/kg) was administered intravenously (i.v.) or orally (p.o.) no parent drug was detected in plasma or in urine. The disposition of the metabolite PBZ (i.v.) could be described by a 2 compartment model with a P half-life varying from 7.40 to 8.35 h. Due to severe side effects the use of i.v. suxibuzone should not be encouraged in the horse. PBZ and OPBZ were detected in plasma and urine after p.o. SXB administration. Peak plasma PBZ concentrations (8.8 ± 3.0 μg/ml) occurred 6 h after oral dosing and the terminal exponential constant was 0.11 ± 0.01 h^-1. Phenylbutazone and oxyphenbutazone were detectable in urine (> 1 μg/ml) for at least 36 h, after p.o. administration.
SXB was not hydrolyzed in vitro by horse plasma. Equine liver homogenates however appeared to have a very high capacity for hydrolysing SXB, indicating that first-pass effect could be responsible for the rapid disappearance of this NSAID in the horse.     

Plasma pharmacokinetics and urine concentrations of meropenem in ewes

The pharmacokinetics of meropenem was studied in five ewes after single i.v. and i.m. dose of 20 mg/kg bw. Meropenem concentrations in plasma and urine were determined using microbiological assay method. A two-compartment open model was best described the decrease of meropenem concentration in plasma after an i.v. injection. The drug was rapidly eliminated with a half-life of elimination ( t _{1/2 β} ) of 0.39 ± 0.30 h. Meropenem showed a small steady-state volume of distribution [ V _d(ss)] 0.055 ± 0.09 L/kg. Following i.m. injection, meropenem was rapidly absorbed with a t _1/2ab of 0.25 ± 0.04 h. The peak plasma concentration ( C _max) was 48.79 ± 8.83  μ g/mL was attained after 0.57 ± 0.13 h ( t _max). The elimination half-life ( t _1/2el) of meropenem was 0.71 ± 0.12 h and the mean residence time ( MRT ) was 1.38 ± 0.26 h. The systemic bioavailability (F) after i.m. injection was 112.67 ± 10.13%. In vitro protein-binding percentage of meropenem in ewe's plasma was 42.80%. The mean urinary recoveries of meropenem over 24 h were 83% and 91% of the administered dose after i.v. and i.m. injections respectively. Thus, meropenem is likely to be efficacious in the eradication of many urinary tract pathogens in sheep.     

Influence of Pasteurella multocida infection on the pharmacokinetic behavior of marbofloxacin after intravenous and intramuscular administrations in rabbits

Abo-El-Sooud, K., Goudah, A. Influence of Pasteurella multocida infection on the pharmacokinetic behavior of marbofloxacin after intravenous and intramuscular administrations in rabbits. J. vet. Pharmacol. Therap. 33 , 63–68.
The pharmacokinetic behavior of marbofloxacin was studied in healthy ( n  = 12) and Pasteurella multocida infected rabbits ( n  = 12) after single intravenous (i.v.) and intramuscular (i.m.) administrations. Six rabbits in each group (control and diseased) were given a single dose of 2 mg/kg body weight (bw) of marbofloxacin intravenously. The other six rabbits in each group were given the same dose of the drug intramuscularly. The concentration of marbofloxacin in plasma was determined using high-performance liquid chromatography. The plasma concentrations were higher in diseased rabbits than in healthy rabbits following both routes of injections. Following i.v. administration, the values of the elimination half-life ( t _1/2β), and area under the curve were significantly higher, whereas total body clearance was significantly lower in diseased rabbits. After i.m. administration, the elimination half-life ( t _1/2el), mean residence time, and maximum plasma concentration ( C _max) were higher in diseased rabbits (5.33 h, 7.35 h and 2.24 μg/mL) than in healthy rabbits (4.33 h, 6.81 h and 1.81 μg/mL, respectively). Marbofloxacin was bound to the extent of 26 ± 1.3% and 23 ± 1.6% to plasma protein of healthy and diseased rabbits, respectively. The C _max /MIC (minimum inhibitory concentration) and AUC/MIC ratios were significantly higher in diseased rabbits (28 and 189 h) than in healthy rabbits (23 and 157 h), indicating the favorable pharmacodynamic characteristics of the drug in diseased rabbits.     

Plasma pharmacokinetics of ranitidine HCl in adult horses

Plasma pharmacokinetics of ranitidine HCl were investigated after intravenous (i.v.) and oral (p.o.) administration of 2.2 mg/kg drug to six healthy adult horses. Concentrations of ranitidine were determined using normal-phase, high-performance liquid chromatography. Plasma concentrations of ranitidine HCl declined from a mean of 5175 ng/mL at 5 min to 37 ng/mL at 720 min after i.v. administration. A three-exponent equation, C_p= A₁· e^–k1t+ A₂· e^–k2t+ A₃· e^–k3t, best described data for all horses. Mean values for model-independent values calculated from the last quantifiable time point were: apparent volume of distribution (Vd_ss) = 1.07 L/kg; area under the curve ( AUC ) = 231,000 ng · min/mL; area under the moment curve ( AUMC ) = 26,900,000 ng · min²/mL; mean residence time ( MRT ) = 113 min; and clearance (Cl) = 9.8 mL/min.kg. Following p.o. administration, a two-exponent equation, C_p= A₁· e^–k1t+ A₂· e^–k2t, best described the data for five horses; data for the remaining horse were best described by a three-exponent equation. Mean values of pharmacokinetic values from the p.o. study include: AUC = 59,900 ng · min/mL; AUMC = 10,600,000 ng · min²/mL; mean absorption time ( MAT ) = 58.9 min; T _max= 99.2 min; C _max= 237 ng/mL; and F = 27%.     

Bioavailability, pharmacokinetics, and tissue distribution of 14C homidium after parenteral administration to Boran cattle

The absorption, distribution and elimination characteristics of ¹⁴C homidium have been described in non-infected and Trypanosoma congolense -infected cattle treated with ¹⁴C homidium chloride by either intramuscular (i.m.) or intravenous (i.v.) injection at a dose level of 1 mg/kg body weight. Results show that the mean (± SD) elimination of the drug from plasma followed a biexponential process, with half-lives of 0.084 ± 0.006 h and 97.66 ± 16.28 h for the distribution and elimination phases after intravenous injection, respectively. Bioavailability of the intramuscular dose was 62.5% and 57.8% in non-infected and trypanosome-infected cattle, respectively. Absorption was rapid, with a t _max of 15 min and a mean C _max (± SD) of 268.4 ± 4.09 ng/mL following the intramuscular dose in non-infected cattle. The major route of excretion was via faeces. Approximately 90% of the total dose given to non-infected i.m.-treated cattle was excreted within 14 days. Following intramuscular administration of the drug, residues remained high in the major excretory organs, with the liver having concentrations of 1411 and 1199 ng/g after 14 and 28 days, respectively. Over the same period, the values in the kidneys were 649 and 448 ng/g. Concentrations in the liver 14 and 21 days following i.v. treatment were 2195 and 2454 ng/g, respectively. These results show that there was no significant difference in liver drug residues between 14 and 21 days, or 28 days depending on the treatment given, suggesting that once the drug is in this organ, it is released back into the circulation at an extremely slow rate.     

The pharmacokinetics, pharmacological responses and behavioral effects of acepromazine in the horse

After intravenous (i.v.) injection, acepromazine was distributed widely in the horse ( V_d = 6.6 litres/kg) and bound extensively (>99%) to plasma proteins. Plasma levels of the drug declined with an α phase half-life of 4.2 min, while the β phase or elimination half-life was 184.8 min. At a dosage level of 0.3 mg/kg acepromazine was detectable in the plasma for 8 h post dosing. The whole blood partitioning of acepromazine was 46% in the plasma phase and 54% in the erythrocyte phase.
Penile prolapse was clearly evident at doses from 0.01 mg/kg to 0.4 mg/kg i.v., and the duration and extent of protrusion were dose related. Hematocrit levels were significantly lowered by administration of 0.002 mg/kg i.v. (about 1 mg to a 500 kg horse) and increasing dosages resulted in greater than 20% lowering of the hematocrit from control levels. Pretreatment of horses with acepromazine also reduced the variable interval (VI 60) responding rate in all horses tested.
These data show that hematocrit changes are the most sensitive pharmacological responses to acepromazine, followed by changes in penile extension, respiratory rate, VI responding and locomotor responses. Acepromazine is difficult to detect in plasma at normal clinical doses. However, because of its large volume of distribution, its urinary elimination is likely prolonged, and further work on its elimination in equine urine is required.     

Investigation of pharmacokinetic parameters of tiamulin after intramuscular and subcutaneous administration in normal dogs

Laber, G. Investigation of pharmacokinetic parameters of tiamulin after intramuscular and subcutaneous administration in normal dogs. J. vet. Pharmacol. Therap. 11 , 45–49.
Kinetic variables for tiamulin in the normal dog have been determined. Serum concentrations of tiamulin were compared after intramuscular (i.m.) and subcutaneous (s.c.) administration of a single dose of tiamulin. Following a single i.m. dose of 10 mg/kg body weight, the compound was calculated to have a C_max= 0.61 ± 0.15 μg/ml, a T _max= 6 h and a t _½= 4.7 ± 1.4 h. Tiamulin showed dose-dependent pharmacokinetics when given as a single s.c. dose of either 10 mg or 25 mg/kg body weight. For the lower dose, the values C_max= 1.55 ± 0.11 μg/ml, T _max= 8 h and 1 _max= 4.28 ± 0.18 h were obtained. For the higher dose C _max= 3.14 ± 0.04 μg/ml, T _max= 8 h and t _½= 12.4 ± 3.4 h were calculated. When tiamulin was administered subcutaneously at a dose rate of 10 mg/kg body weight, higher and better maintained serum levels were achieved than those following i.m. administration. After repeated s.c. doses no significant accumulation of tiamulin occurred. Assuming that a continuous effective serum concentration is necessary throughout the course of therapy, these data would indicate that tiamulin should be given every 24 h.     

Plasma pharmacokinetics of ranitidine HCl in foals

Plasma pharmacokinetics of ranitidine HCl were investigated after intravenous (i.v.) and oral (p.o.) administration of drug to six healthy foals. Twelve- to sixteen-week-old foals received 2.2 mg ranitidine/kg i.v. and 4.4 mg ranitidine/kg p.o. Concentrations of ranitidine were determined using normal phase high performance liquid chromatography. Plasma concentrations of ranitidine HCl declined from a mean of 3266 ng/mL at 5 min to 11 ng/mL at 720 min after administration. The profile of the plot of concentrations of ranitidine HCl vs. time was best described by a two-exponent equation for two foals; data for the remaining four foals were best described by a three-exponent equation. Mean values for model-independent values were: apparent volume of distribution ( V d_ss) = 1.46 L/kg; area under the curve ( AUC ) = 16 7442 ng·min/mL; area under the moment curve ( AUMC ) = 18 068 221 ng·min²/mL; mean residence time ( MRT ) = 108.9 min; and clearance ( Cl ) = 13.3 mL/min.kg. Following p.o. administration, a two-exponent equation best described data for five foals; data for the remaining foal were best described by a three-exponent equation. Mean values of the pharmacokinetic values from the p.o. study include: AUC  = 12 6413 ng·min/mL; AUMC  = 18 039 825 ng·min²/mL; mean absorption time ( MAT ) = 32.0 min; observed time to maximum plasma concentration ( T _max) = 57.2 min; maximum observed plasma concentration ( C _max) = 635.7 ng/mL; and bioavailability ( F ) = 38%.     

Pharmacokinetics of parenteral and oral sustained-release morphine sulphate in dogs

The pharmacokinetics of single-dose morphine sulphate (MS) administered intravenously (i.v.) and intramuscularly (i.m.) and of oral sustained-release morphine sulphate (OSRMS) were studied in dogs. Beagles (n = 6) were randomly assigned to six treatment groups using a Latin square design. Treatments included MS 0.5 and 0.8 mg/kg i.v. and i.m. and OSRMS 15 and 30 mg orally (p.o). Serum samples were drawn at intervals up to 420 min following parenteral MS and 720 min following OSRMS. Serum was analysed for morphine concentration using a radioimmunoassay . Pharmacokinetic analysis of the results revealed that MS was eliminated by a first-order process best described by a two-compartment model. For i.v. and i.m. data there were no statistically significant differences (P c 0.0 5) between steady-state volume of distribution, half-life of elimination and plasma clearance. As expected, area under the concentration vs. time curve (AUC) was significantly greater for the 0.8 mg/kg dosage for i.v. and i.m. routes, and time to maximum serum concentration was significantly longer following i.m. administration. For OSRMS there were no significant differences between dosage for any parameter (AUC, C_max. t_max t_½ F) and prolonged absorption of the drug occurred over approximately 6 h. Bioavailability (F) for both oral dosages was approximately 20%. The i.m. route is an effective method for rapid and complete delivery of MS to dogs. OSRMS may be useful in the provision of long-term analgesic therapy in dogs, but further work is required to verify the safety and effectiveness of this preparation.     

Bioavailability and pharmacokinetics of ibuprofen in the broiler chicken

The intravenous, intramuscular and oral pharmacokinetics of ibuprofen in broiler chickens were investigated. In a preliminary study, plasma ibuprofen concentration-time profiles, following i.v. (25 mg/kg) dosing were best described by a 2-compartment model. After intravenous administration, the volume of distribution at steady-state ( V _d(ss)), the total systemic clearance ( Cl _B), the elimination half-life (t_1/2p) and the MRT were 0.303 L/kg, 482.3 ml/h-kg, 2.71 h and 1.02 h, respectively. After intramuscular administration of ibuprofen, the t _max and C _max were 0.37 h, and 42.2μg/mL, respectively, with an estimated bioavailability of 46.7%. After oral administration of ibuprofen, the t _max and C _max were 0.31 h and 23.91 μg/mL, respectively, with an estimated bioavailability of 24.2%. This is a preliminary study, examining the use of ibuprofen in broiler chickens, and should be followed by tissue residue and efficacy studies in different disease states.     

Influence of administration route on the biotransformation of amoxicillin in the pig

A comparison was made in the plasma concentration of the major metabolites of amoxicillin (AMO), i.e. amoxicilloic acid (AMA) and amoxicillin diketopiperazine-2',5'-dione (DIKETO) in portal and jugular venous plasma after oral (p.o.) and intravenous (i.v.) AMO administration to pigs, in order to study a possible presystemic degradation of AMO in the gastro-intestinal tract and liver. Almost identical plasma concentration-time curves were obtained for AMO and its metabolites in portal and jugular venous plasma, both after p.o. and i.v. AMO administration. Almost immediately after i.v. AMO administration, high AMA and DIKETO concentrations were measured in plasma, while after p.o. dosing, the metabolites appeared in plasma after almost complete absorption of AMO. No significant differences in pharmacokinetic parameters of AMO, AMA and DIKETO, derived from the concentration-time profiles in portal and jugular venous plasma were calculated, both after i.v. and p.o. AMO administration ( P  > 0.05). After p.o. administration, the half-life of elimination ( t _1/2(el)) for AMA is at least two or three times the t _1/2(el) of AMO (0.75 h for AMO vs. 2.69 h for AMA), indicating the slower clearance of the metabolite. It could be hypothesized that AMA is only eliminated by glomerular filtration, as its open β-lactam structure might not be recognized by the transport carrier in the proximal tubule of the kidney. The results of the study indicate that AMO is not substantially metabolized presystemically in the gut and liver. Therefore, it may be assumed that the kidney may be the major organ for AMO biotransformation. Future in vivo and in vitro experiments should be performed to state this hypothesis.     

Pharmacokinetics and disposition of clenbuterol in the horse

The pharmacokinetics of clenbuterol (CLB) following a single intravenous (i.v.) and oral (p.o.) administration twice daily for 7 days were investigated in thoroughbred horses. The plasma concentrations of CLB following i.v. administration declined mono-exponentially with a median elimination half-life ( t _1/2k) of 9.2 h, area under the time–concentration curve ( AUC ) of 12.4 ng·h/mL, and a zero-time concentration of 1.04 ng/mL. Volume of distribution ( V _d) was 1616.0 mL/kg and plasma clearance ( Cl ) was 120.0 mL/h/kg. The terminal portion of the plasma curve following multiple p.o. administrations also declined mono-exponentially with a median elimination half-life ( t _1/2k) of 12.9 h, a Cl of 94.0 mL/h/kg and V _d of 1574.7 mL/kg. Following the last p.o. administration the baseline plasma concentration was 537.5 ± 268.4 and increased to 1302.6 ± 925.0 pg/mL at 0.25 h, and declined to 18.9 ± 7.4 pg/mL at 96 h. CLB was still quantifiable in urine at 288 h following the last administration (210.0 ± 110 pg/mL). The difference between plasma and urinary concentrations of CLB was 100-fold irrespective of the route of administration. This 100-fold urine/plasma difference should be considered when the presence of CLB in urine is reported by equine forensic laboratories.