Isometamidium in pigs: disposition kinetics, tissue residues and adverse reactions

The disposition and adverse effects of the anti-trypanosomal drug isometamidium in pigs were evaluated. Following intramuscular administration of the drug at doses of 0.5, 15 and 35 mg kg-1, the drug was rapidly absorbed within 15 to 30 minutes to reach maximum plasma concentrations of 12 to 477 (n = 6), 302 to 655 (n = 4) and 1620 (n = 1) ng ml-1, respectively. No drug was detectable in plasma (less than 5 ng ml-1) 24 hours after drug administration at the three doses used. The half-lives of disappearance of the drug from plasma during the terminal phase were 7.12 h for the pigs given a dose of 15 mg kg-1, and 7.20 h for the pig which received a dose of 35 mg kg-1. At all the intramuscular injection sites, high drug concentrations were found six weeks after administration. The most dramatic adverse reactions observed were: one death after intramuscular administration at a dose of 35 mg kg-1 to two animals, and two deaths after intravenous administration at a dose of 2 mg kg-1 to two animals. For all these cases, the immediate cause of death was acute cardiovascular collapse. Biochemical analyses and gross and histological examinations showed that the animals that tolerated the high doses of 15 and 35 mg kg-1 given intramuscularly had extensive and severe tissue damage at the injection sites. Significant increases in plasma gamma-glutamyltransferase and alanine aminotransferase following drug administration suggested a degree of hepatobiliary damage.     

Pharmacokinetics, urinary and mammary excretion of ceftriaxone in lactating goats

The pharmacokinetic properties of ceftriaxone were investigated in 10 goats following a single intravenous (i.v.) and intramuscular (i.m.) administration of 20 mg kg(-1) body weight. After i.v. injection, ceftriaxone serum concentration-time curves were characteristic of a two-compartment open model. The distribution and elimination half-lives (t(1/2alpha), t(1/2beta)) were 0.12 and 1.44 h respectively. Following i.m. injection, peak serum concentration (C(max)) of 23.6 microg ml(-1) was attained at 0.70 h. The absorption and elimination half-lives (t(1/2ab), t(1/2el)) were 0.138 and 1.65 h respectively. The systemic bioavailability of the i.m. administration (F %) was 85%. Following i.v. and i.m. administration, the drug was excreted in high concentrations in urine for 24 h post-administration. The drug was detected at low concentrations in milk of lactating goats. A recommended dosage of 20 mg kg(-1) injected i.m. every 12 h could be expected to provide a therapeutic serum concentration exceeding the minimal inhibitory concentrations for different susceptible pathogens.     

Effect of pantothenic acid on disposition kinetics and tissue residues of sulphadimidine in chickens

Sulphadimidine was administered to chickens via the intracrop route to determine plasma concentrations of the unchanged sulphonamide and its acetylated derivatives, kinetic disposition, tissue residues and acetylation. The sulphadimidine was given alone (group 1) at a dose of 200 mg kg-1 bodyweight. Pantothenic acid was given via the intracrop route at a dose of 100 mg kg-1 bodyweight one hour before (group 2) and six hours after (group 3) sulphadimidine administration (200 mg kg-1 bodyweight intracrop). The highest plasma concentrations of sulphadimidine in groups 1, 2 and 3 were reached in 1.73, 1.62 and 1.71 hours, respectively, following intracrop administration. In birds of groups 1, 2 and 3 no sulphadimidine was detected at 72, 24 and 48 hours, respectively, following its administration. Estimation of sulphadimidine in most of the body tissues revealed that all tissues examined had lower concentrations than plasma. In chickens given pantothenic acid (groups 2 and 3) before and after sulphadimidine administration, an increase in the concentration of N4 acetylated derivatives of sulphadimidine was observed compared with birds given sulphadimidine alone (group 1).     

The disposition kinetics and residues of fenvalerate in tissues following a single dermal application to black bengal goats

The disposition kinetics of fenvalerate were studied in goats after dermal application of 100 ml of 0.25% (w/v) solution. The insecticide persisted in the blood for 72 h. The mean (±SEM) V _d(area) and apparent t _1/2 () were 9.92±1.44 L/kg and 17.51±2.65 h, while the AUC and Cl_B values were respectively 82.15±7.40 g h/ml and 0.56±0.05 L/(kg h). Four days after the dermal application, the highest concentration of fenvalerate residues was found in the adrenal gland, followed by the biceps muscle, omental fat, liver, kidney, lung and cerebrum in that order. Fenvalerate caused hyperglycaemia but had no effect on serum protein and cholesterol levels. Serum acetylcholinesterase activities were increased after 24 h but were below the initial values from 48 to 120 h.Abbreviations Ache acetylcholinestase - AUC total area under the blood insecticide concentration-versus-time curve - Cl_B total body clearance - GLC gas-liquid chromatography - t _1/2() apparent elimination half-life - V _d(area) apparent volume of insecticide distribution based on area method     

Closantel plasma and milk disposition in dairy goats: assessment of drug residues in cheese and ricotta

Closantel (CLS) is currently used in programs for the strategic control of gastrointestinal nematodes. CLS is extralabel used in different dairy goat production systems. From available data in dairy cows, it can be concluded that residues of CLS persist in milk. The current work evaluated the concentration profiles of CLS in plasma and milk from lactating orally treated dairy goats to assess the residues pattern in dairy products such as cheese and ricotta. Six (6) female Saanen dairy goats were treated orally with CLS administered at 10 mg/kg. Blood and milk samples were collected between 0 and 36 days post‐treatment. The whole milk production was collected at 1, 4, 7, and 10 days post‐treatment to produce soft cheese and ricotta. CLS concentrations in plasma, milk, cheese, whey, and ricotta were determined by HPLC. The concentrations of CLS measured in plasma were higher than those measured in milk at all sampling times. However, the calculated withdrawal time for CLS in milk was between 39 and 43 days postadministration to dairy goats. CLS residual concentrations in cheese (between 0.93 and 1.8 μg/g) were higher than those measured in the milk used for its production. CLS concentrations in ricotta were sixfold higher than those in the milk and 20‐fold higher than those in the whey used for its production. The persistent and high residual concentrations of CLS in the milk and in the cheese and ricotta should be seriously considered before issuing any recommendation on the extralabel use of CLS in dairy goat farms.     

Effect of short term starvation on disposition kinetics of chloramphenicol in goats

The effect of short term starvation on the disposition kinetics of chloramphenicol was determined in goats. The same dosage level (10 mg kg-1) administered intravenously produced higher serum concentrations in the animals when they were starved than when they were not starved. This could be attributed to the significantly smaller (P less than 0.05) volume of the central compartment. Starvation significantly decreased the rate of elimination of chloramphenicol while the apparent volume of distribution of the drug was not altered. A significant decrease in the body clearance, 1.36 +/- 0.95 ml (min kg)-1 in the starved condition compared with 3.78 +/- 2.19 mg (min kg)-1 in the controls, caused a corresponding increase in the half life of chloramphenicol. The decreased rate of elimination was attributed to decreased hepatic microsomal metabolism since starvation did not change the fraction of the dose excreted unchanged in the urine. The clinical significance of the altered disposition of chloramphenicol is that administration at the usual dosing rate would lead to accumulation of the drug and eventual toxicity.     

The disposition kinetics,urinary excretion and dosage regimen of amikacin in cross-bred bovine calves

The disposition kinetics, urinary excretion and dosage regimen of amikacin after a single intravenous administration of 10 mg/kg was investigated in six cross-bred bovine calves. At 1 min, the concentration of amikacin in the plasma was 116.9±3.16 µg/ml and the minimum therapeutic concentration was maintained for 8 h. The elimination half-life and volume of distribution were 3.09±0.27 h and 0.4±0.03 L/kg, respectively. The total body clearance (Cl_B) and T/P ratio were 0.09±0.002 L/kg/h and 4.98±0.41, respectively. Approximately 50% of the total dose of amikacin was recovered in the urine within 24 h after administration. Amikacin in concentrations ranging from 5 to 150 µg/ml bound to plasma proteins to the extent of 6.32%±0.42%. A satisfactory intravenous dosage regimen of amikacin in bovine calves would be 13 mg/kg followed by 12 mg/kg at 12 h intervals.     

Metabolism, excretion, pharmacokinetics and tissue residues of phenylbutazone in the horse

The pharmacokinetics, metabolism, excretion and tissue residues of phenylbutazone (PBZ) in the horse were studied following both intravenous and oral administration of the drug at a dose rate of 4.4 mg/kg. A 72-hour blood sampling schedule failed to demonstrate a third exponential phase; the plasma disposition following intravenous injection being described by a two compartment open model, with the following elimination phase parameters: beta = 0.13h-1, t1/2 beta = 5.46h, Vdarea = 0.141 1/kg and C1B = 17.9 ml/kg/h. The hydroxylated metabolites oxyphenbutazone (OPBZ) and gamma-hydroxyphenylbutazone (OHPBZ) were present in detectable concentrations in plasma for 72 and 24 h, respectively. After 36 h OPBZ concentrations exceeded plasma PBZ concentrations. In urine the principal metabolites were OPBZ and OHPBZ but smaller concentrations of another compound, probably gamma-hydroxyoxyphenbutazone (OHOPBZ), were also detected. The percentages of the administered dose recovered from urine were 30.7, 39.0 and 40.3 after 24, 48 and 72 h from the time of injection. Recovery of PBZ and its metabolites from urine was significantly reduced in the first 24 h after oral dosing when the horses had free access to hay, probably as a result of markedly delayed absorption, but this did not occur in animals deprived of food for a few hours before and after dosing. Determination of approximate values of urine/plasma (U/P) concentration ratios for PBZ and its metabolites relative to endogenous creatinine U/P concentration ratio suggested that PBZ was filtered in small amounts only because of the high degree of plasma protein binding and then excreted by diffusion trapping in the alkaline urine. Much higher U/P ratios were obtained for the hydroxylated derivatives, and one at least (OHPBZ) was secreted into urine.     

Intravenous disposition kinetics, oral and intramuscular bioavailability and urinary excretion of norfloxacin nicotinate in donkeys

An aqueous solution of norfloxacin nicotinate (NFN) was administered to donkeys (Aquus astnus) intravenously (once at 10 mg/kg), intramuscularly and orally (both routes once at 10 and 20 mg/kg, and for 5 days at 20 mg/kg/day). Blood samples were collected at predetermined times after each treatment and urine was sampled after intravenous drug administration. Serum NFN concentrations were determined by microbiological assay. Intravenous injection of NFN over 45–60 s resulted in seizures, profuse sweating and tachycardia. The intravenous half-life (t_1/2β was 209 ± 36 min, the apparent volume of distribution (V_d(area)) was 3.34 ± 0.58 L/kg, the total body clearance (Cl_E) was 1.092 ± 0.123 ± 10^--²mL/min/kg and the renal clearance (C1_R) was 0.411 ± 0.057 ± 10^--²mL/min/kg. Oral bioavailability was rather poor (9.6% and 6.4% for the 10 and 20 mg/kg doses respectively). Multiple oral treatments did not result in any clinical gastrointestinal disturbances. After intramuscular administration (20 mg/kg), serum NFN concentrations > 0.25 μg/mL (necessary to inhibit the majority of gram-negative bacteria isolated from horses) were maintained for 12 h. The intramuscular bioavailability was 31.5% and 18.8% for the 10 and 20 mg/kg doses respectively. After multiple dosing some local swelling was observed at the injection site. About 40% of the intravenous dose was recovered in the urine as parent drug. The results of comprehensive haematological and blood biochemistry tests indicated no abnormal findings except elevation in serum CPK (creatine phosphokinase) values after multiple intramuscular dosing. On the basis of the in vitro-determined minimum inhibitory concentrations of the drug and serum concentrations after multiple dosing, the suggested intramuscular dosage schedules for the treatment of gram-negative bacterial infections in Equidae are 10 mg/kg every 12 h or 20 mg/kg every 24 h.     

Influence of induced disease states on the disposition kinetics of imidocarb in goats

The influence of fever, induced by different agents, on the disposition kinetics of imidocarb was determined in goats. Escherichia coli endotoxin (0.2 microgram/kg), Trypanosoma evansi (10(7) in 1 ml sterile glucose citrate), and Infectious Bovine Rhinotracheitis virus (10(6.5)TCID50) were the agents administered to induce the febrile state. In control and febrile animals the two-compartment model was used to describe the disposition kinetics of the drug. Fever caused significant changes to occur in the apparent volume of distribution and the body (systemic) clearance of imidocarb, but the half-life remained unchanged. The statistical significance of the changes in these pharmacokinetic parameters varied with the etiology of the febrile state. E. coli endotoxin and IBR virus caused corresponding decreases in apparent volume of distribution and clearance of imidocarb, while fever induced with T. evansi caused highly significant increases in both pharmacokinetic parameters. It was concluded that the alterations in the disposition kinetics of imidocarb that occurred in the febrile goats were related not only to the febrile reaction per se but also to the pathophysiology of the disease condition.     

Disposition kinetics and urinary excretion of ciprofloxacin in goats following single intravenous administration

We evaluated the pharmacokinetics of ciprofloxacin in serum (n = 6) and urine (n = 4) in goats following a single intravenous administration of 4 mg/kg body weight. The serum concentration-time curves of ciprofloxacin were best fitted by a two-compartment open model. The drug was detected in goat serum up to 12 h. The elimination rate constant (β) and elimination half-life (t_1/2β) were 0.446 ± 0.04 h^-1 and 1.630 ± 0.17 h, respectively. The apparent volume of distribution at steady state (Vd_ss) was 2.012 ± 0.37 l/kg and the total body clearance (Cl_B) was 16.27 ± 1.87 ml/min/kg. Urinary recovery of ciprofloxacin was 29.70% ± 10.34% of the administered dose within 36 h post administration. In vitro serum protein binding was 41% ± 13.10%. Thus, a single daily intravenous dose of 4 mg/kg is sufficient to maintain effective levels in serum and for 36 h in urine, allowing treatment of systemic, Gram-negative bacterial infections and urinary tract infections by most pathogens.     

Sulfatroxazole: pharmacokinetics, metabolism and urinary excretion in goats and pigs

The disposition of sulfatroxazole (STZ) has been studied in goats and pigs after intravenous administration of a single dose. The percentage of protein-binding decreased with increasing plasma concentration in both species. At 100 micrograms/ml about 85% was bound to plasma proteins in goats, while the corresponding value was only 55% in pigs. Two metabolites of STZ were isolated from urine and identified as N4-acetyl-STZ and 3-sulfanilamido-4-methyl-5-hydroxy-methyl-isoxazole (5'-OH-STZ). The goats excreted about 80% of the dose in urine. The majority (64%) was excreted as unchanged STZ, while N4-acetyl-STZ and 5'-OH-STZ made up 19% and 18%, respectively. The pigs excreted 95% of the dose in urine. Unchanged STZ amounted to 30% and N4-acetyl-STZ to 70% of the urinary excretion in pigs, while there were only traces of 5'-OH-STZ.     

Comparative pharmacokinetic disposition of closantel in sheep and goats

The pharmacokinetic disposition of closantel was examined following intraruminal (i.r.) or intramuscular (i.m.) administration to adult Merino sheep and to adult and 3-month-old, suckling Angora goats. In adult goats the maximum concentration (C_max) and area under the plasma concentration with time curve ( AUC ) following 3.75, 7.5 and 15.0 mg closantel/kg given i.r. increased with dose however the time of C_max (r_max= 2.6d) in plasma was unaffected by dose rate. The elimination phase (K₁₀) of closantel was monoexponential with a half-life ( t _½) of 4.7d again unaffected by dose rate. Apart from a more rapid absorption phase and earlier T_max following 3.75 mg closantel/kg i.m., pharmacokinetic behaviour was similar to that following i.r. administration at 3.75 or 7.5 mg/kg. Although absorption rate was more rapid in kids after i.r. administration at 7.5 mg/kg, pharmacokinetic disposition of closantel was otherwise similar to that in adult goats. No closantel was detected in milk of treated does or in the plasma of their kids. I.R. closantel at 7.5 mg/kg was more slowly absorbed in goats than in sheep but C_max was similar in both species. However, K₁₀ t _½ was significantly shorter in goats (4d) than in sheep (14d). Faster elimination resulted in an almost three-fold lowering of AUC in goats and could dramatically reduce the sustained action of closantel in this species compared with sheep.     

Influence of aflatoxin B1 on the kinetic disposition,systemic bioavailability and tissue residues of doxycycline in chickens

1. Disposition kinetics of doxycycline (doxy) was studied in healthy chickens and chickens experimentally intoxicated with aflatoxin B1 by intravenous, oral or intramuscular (i.m.) injection, in a single dose of 15 mg/kg body weight. In addition, the tissue distribution and residual pattern of the drug were determined in healthy and intoxicated chickens. 2. The maximum serum concentrations of doxy were reached 1.97 and 2.37 h after oral, and 1.57 and 2.92 h after i.m. dosage in healthy and aflatoxic birds, respectively. 3. The volumes of distribution and total body clearances were higher in aflatoxic birds (1.75 l/kg and 14.61 ml/kg/min) than in healthy chickens (0.93 l/kg and 4.6 ml/kg/min). Data relating to intravenous injection were analysed using a two-compartment open model curve fit. 4. Lower values of systemic bioavailability were observed in intoxicated birds (30.9 and 33.9%) than healthy ones (43.7 and 57.3%) after oral and i.m. administration, respectively. 5. The highest concentration of doxy residues were present in liver, kidney and serum followed by heart and muscles. Doxy residue concentrations in edible tissues was below the EEC limit 6 d after cessation of oral or i.m. medication with 15 mg/kg body weight twice daily for 5 successive days.     

Mammary and renal excretion of chlorpromazine in goats

In experiments on goats it was found that the binding of chlorpromazine (Cpz) to the proteins in plasma and milk ranged between 91–99 and 91–97 %, respectively, and was independent of the drug concentration in the samples. The in vitro binding of chlorpromazine in whole milk (96%) was significantly higher (P<0.01) than the protein binding in skim milk (91%) because the drug was concentrated in the butterfat. The concentration of Cpz was always higher in the milk than in the corresponding plasma samples. The renal clearance of Cpz in goats with normal urine pH was very small (0.16 ml min^-1) due to the high degree of plasma protein binding and of back diffusion. The mechanisms involved during the renal excretion of Cpz in goats included glomerular filtration, probably active tubular secretion and pH dependent back diffusion.