Pharmacokinetics of sulphamethoxazole in calves and cows

The kinetics of sulphamethoxazole (SMZ) in plasma and milk, and its metabolism, protein binding and renal clearance were studied in three newborn calves and two dairy cows after intravenous administration. SMZ was predominantly acetylated; no hydroxy and glucuronide derivatives could be detected in plasma and urine. Age-dependent pharmacokinetics and metabolism of SMZ were observed. The plasma concentration-time curves of the N4-acetyl metabolite in the elimination phase were parallel to those of the parent drug; the N4-acetyl metabolite plasma percentage depended on age and ranged between 100% (new-born) to 24.5% (cow). SMZ was rapidly eliminated (elimination half-lives: 2.0-4.7 h) and exhibited a relatively small distribution volume (VDarea: 0.44-0.57 l/kg). SMZ was excreted predominantly by glomerular filtration, while its N4-acetyl metabolite was actively eliminated by tubular secretion.     

Pharmacokinetics of sulphamethoxazole in calves and cows

Summary

The kinetics of sulphamethoxazole (SMZ) in plasma and milk, and its metabolism, protein binding and renal clearance were studied in three newborn calves and two dairy cows after intravenous administration. SMZ was predominantly acetylated; no hydroxy and glucuronide derivatives could be detected in plasma and urine. Age‐dependent pharmacokinetics and metabolism of SMZ were observed. The plasma concentration‐time curves of the N₄‐acetyl metabolite in the elimination phase were parallel to those of the parent drug; the N₄‐acetyl metabolite plasma percentage depended on age and ranged between 100% (new‐born) to 24.5% (cow). SMZ was rapidly eliminated (elimination half‐lives: 2.0–4.7 h) and exhibited a relatively small distribution volume (V_Darea: 0.44–0.57 l/kg). SMZ was excreted predominantly by glomerular filtration, while its N₄‐acetyl metabolite was actively eliminated by tubular secretion.     

Dose dependent disposition of sulphadimidine and of its N4-acetyl and hydroxy metabolites in plasma and milk of dairy cows

The disposition of sulphadimidine (SDM) and of its N4-acetyl (N4-SDM) and two hydroxy metabolites, 6-hydroxymethyl-(SCH2OH) and 5-hydroxyasulphadimidine (SOH), was studied in plasma and milk of dairy cows following intramuscular or intravenous administration of sulphadimididine-33.3% at doses of 10, 45, 50, and 100 mg/kg. The main metabolite in plasma as well as in milk was SCH2OH. The metabolite percentages, the final plasma elimination half-lives, and the time of peak SDM concentrations in milk are presented for different dosages. The concentrations of SDM and its metabolites in milk ran parallel to those in plasma beyond 4 hours p.i. The metabolite concentrations in plasma and milk were lower than those of the parent SDM. Sulphate and glucuronide metabolites could not be detected in milk. At high doses (45 mg/kg or more) and SDM plasma concentrations exceeding 20 micrograms/ml, a capacity limited metabolism of SDM to SCH2OH was noticed, viz. a steady state concentration of SCH2OH and a biphasic elimination pattern for SDM and SCH2OH in plasma and milk. The mean ultrafiltrate ratios of the milk to plasma concentrations with respect to SDM, SCH2OH, SOH, and N4-SDM were: 0.69, 0.22, 020, and 0.63, respectively. The total amount of SDM and its metabolites recovered from the milk after milking twice daily over the whole experimental time was less than 2% of the applied dose. A bioassay method allowed of detecting qualitatively SDM concentrations exceeding 0.2 micrograms/ml in plasma or milk. Withholding times for edible tissues and milk are suggested.     

Pharmacokinetics, metabolism, and renal clearance of sulfadiazine, sulfamerazine, and sulfamethazine and of their N4-acetyl and hydroxy metabolites in calves and cows

The effect of molecular structure on the drug disposition and protein binding in plasma and milk, the urinary recovery, and the renal clearance of sulfadiazine, sulfamerazine, and sulfamethazine and of their N4-acetyl and hydroxy derivatives were studied in calves and cows. Sulfadiazine was highly acetylated and was slightly hydroxylated. Sulfamerazine and sulfamethazine were hydroxylated predominantly at the methyl group of the pyrimidine side chain; hydroxylation of the pyrimidine ring itself was more extensive for sulfamethazine than for sulfamerazine. At dosages between 100 and 200 mg/kg of body weight, sulfamethazine had a capacity-limited elimination pattern, which was not observed for sulfadiazine or sulfamerazine. The concentrations of the parent sulfonamide and its metabolites in plasma and milk were parallel, the latter being lower. Metabolite concentrations in milk were at least 8 times lower than those of the parent drug. Metabolism speeds drug elimination, producing compounds with renal clearance values higher than those of the parent drug. The effect on the metabolism and renal clearance of methyl substitution in the pyrimidine side chain is discussed.     

Pharmacokinetics, metabolism and renal clearance of sulphatroxazole in calves and cows

The pharmacokinetic analysis of plasma concentration--time curves after a single i.v. dose of 20 mg/kg sulphatroxazole (STZ) to calves and cows revealed a small distribution volume of STZ (mean VD(area) = 0.22-0.26 l/kg) and an age dependent elimination (mean t1/2 6.6-18.8 h). In calves and cows, STZ was extensively metabolized into the N4-acetyl and 5-hydroxy derivatives. In the plasma of calves, the N4-acetyl metabolite (N4-STZ) was present in greater amounts than the hydroxy metabolite (5-OH-STZ), while in cows' plasma concentration of these two metabolites were similar. In the milk of dairy cows STZ concentrations paralleled those of the metabolites and were approximately 21 times lower than corresponding plasma concentrations. The mean plasma protein binding of STZ and its metabolites ranged from 36.4 to 82.5% of total concentration. The N4-STZ derivative was excreted by tubular secretion; the 5-OH-STZ and the parent compound, mainly by glomerular filtration. In calves the majority of STZ administered was excreted as N4-STZ (40-52%), while in cows the parent drug dominated the urinary excretion (36%).     

Comparative aspects and sex differentiation of plasma sulfamethazine elimination and metabolite formation in rats, rabbits, dwarf goats, and cattle.

Plasma disposition and urinary recovery of sulfamethazine (SMZ), its N4-acetylated metabolite (N4AcSMZ), and 2 of its hydroxylated metabolites--5-hydroxysulfamethazine (5OHSMZ) and 6-hydroxymethylsulfamethazine (6CH2OHSMZ)--were determined in either sex of 4 animal species: rats, dwarf goats, rabbits, and cattle. Rats, rabbits, and dwarf goats had significant (P < 0.01) sex difference in SMZ plasma clearance. Male rats had higher plasma clearance than did female rats, and excreted higher amounts of the hydroxy metabolites and lower amounts of N4AcSMZ. The N4AcSMZ metabolite was predominant in plasma and urine of rabbits. Male rabbits had higher plasma clearance than did female rabbits, but differences in metabolite profile were not apparent. With regard to plasma SMZ elimination, the situation in goats was opposite to that in rats. Male goats had considerably lower clearance than did female goats. This was associated with a lower hydroxylation rat in males. Plasma half-life of SMZ in cows was lower than that in bulls, probably because of a smaller distribution volume in cows. Compared with elimination via urine, elimination via milk was negligible in cows. Significant differences in metabolite profiles were not found between bulls and cows. Similar to those in rats and mice, hormone-dependent xenobiotic metabolic pathways may exist in other species. Depending on species and xenobiotic compound residue concentrations of xenobiotics, their metabolites, or both may differ with sex of the animal, or may be altered after treatment with anabolic hormones.     

Pharmacokinetics of sulphanilamide and its three acetyl metabolites in dairy cows and calves

An intravenous low dosage of sulphanilamide (SAA) (14.0 mg/kg) to 6 pre-ruminant calves revealed a biphasic SAA plasma disposition with a mean elimination half-life of 4.1 h. The main metabolite in plasma was N4-acetylsulphanilamide (N4), which 4 hours after injection exceeded the parent SAA plasma concentration. Urinary recovery of SAA was 10 to 16% of the dose; of N4, it was at least 69%. Traces of the N1-acetyl (N1) metabolite and the doubly acetylated derivative (N1N4) were present in urine. The renal clearances of the N1 and N4 metabolites showed a tubular secretion pattern, which was at least 2 to 6 times higher than that of SAA. A single high oral SAA dose of 200 mg/kg to 3 dairy cows resulted in extensive metabolism of SAA into N4, N1, and N1N4 metabolites; their mean maximum plasma concentrations were 64, 48, 0.72 and 24 micrograms/ml, respectively. The mean disposition half-life of SAA in plasma and milk was 10 h. In milk the metabolite concentrations exceeded those in plasma; the N4 and N1N4 metabolite concentrations in milk exceeded that of SAA. The mean maximum concentrations of SAA, N4, N1, and N1N4 in milk were 52, 89, 2.3, and 98 micrograms/ml, respectively. For SAA and its metabolites, the binding to plasma and milk proteins was determined. No glucuronide or sulphate conjugates of SAA and its acetyl metabolites could be found in plasma, milk, or urine. Based on the sensitivity of the bioassay (0.2 micrograms SAA/ml), a withholding time of 5 days was suggested for milk following single oral SAA dosage of 200 mg/kg.     

Disposition of sulfadimidine and its N4-acetyl and hydroxy metabolites in horse plasma

The plasma disposition of sulfadimidine (SDM) and its metabolites N4-acetylsulfadimidine (N4-SDM), 6-hydroxymethyl-4-methyl-pyrimidine (SCH2OH) and 5-hydroxy-4,6-dimethyl-pyrimidine (SOH), was studied in three horses following intravenous administration of SDM at dose levels of 20 and 200 mg/kg in cross-over trials. The percentages of N4-SDM (0.58-0.90%), SOH (0.83-6.75%) and SCH2OH (0.38-0.71%) in plasma, expressed as a percentage of the total sulfonamide concentration, were small and their plasma concentrations were parallel with SDM from 4 h following administration. At high doses (200 mg/kg), the elimination half-life was slightly longer than at low doses (6.0, 10.5, 11.0 vs 5.0, 9.5, 9.5, respectively). The plasma protein binding was related to the dose; it was for the 20 and 200 mg/kg doses, respectively:SDM:61.5-73.3% and 50.5-52.1%; SOH: 47.1-71.0% and 36.7-39.5%, and for N4-SDM: 45.9-63.2% and 38.3-53.7%. The protein binding for SCH2OH, measured in samples obtained at the high dose level, ranged from 13.8 to 20.0%.     

Pharmacokinetics of a sulphamethoxazole/trimethoprim formulation in pigs after intravenous administration

Plasma disposition, metabolism, protein binding and renal clearance of sulphamethoxazole (SMZ) and trimethoprim (TMP) were studied in four pigs after intravenous administration at a dose of 40 and 8 mg/kg, respectively. SMZ and TMP were quickly eliminated (mean elimination half-lives: 2.7 and 2.4 h, respectively). SMZ was predominantly acetylated; no hydroxy and glucuronide derivates could be detected in plasma and urine. TMP was 0-demethylated into 4-hydroxytrimethoprim (M1) and 3-hydroxytrimethoprim (M4) metabolite and subsequently extensively glucuronidated. SMZ, TMP and its M1 metabolite were excreted predominantly by glomerular filtration, while N4-acetylsulphamethoxazole and glucuronide conjugates of the M1 and M4 metabolites of TMP were actively eliminated by tubular secretion. The proportional drug percentage being present in the urine as parent compound was 13.1% for TMP and 16.0% for SMZ. The glucuronide conjugates of the M1 and M4 metabolites formed the main part (81.5%) of urinary TMP excretion pattern.     

Pharmacodynamics and pharmacokinetics of phenylbutazone in calves

Phenylbutazone (PBZ) was administered to six calves intravenously (i.v.) and orally at a dose rate of 4.4 mg/kg in a three-period cross-over study incorporating a placebo treatment to establish its pharmacokinetic and pharmacodynamic properties. Extravascular distribution was determined by measuring penetration into tissue chamber fluid in the absence of stimulation (transudate) and after stimulation of chamber tissue with the mild irritant carrageenan (exudate). PBZ pharmacokinetics after i.v. dosage was characterized by slow clearance (1.29 mL/kg/h), long-terminal half-life (53.4 h), low distribution volume (0.09 L/kg) and low concentrations in plasma of the metabolite oxyphenbutazone (OPBZ), confirming previously published data for adult cattle. After oral dosage bioavailability (F) was 66%. Passage into exudate was slow and limited, and penetration into transudate was even slower and more limited; area under curve values for plasma, exudate and transudate after i.v. dosage were 3604, 1117 and 766 microg h/mL and corresponding values after oral dosage were 2435, 647 and 486 microg h/mL. These concentrations were approximately 15-20 (plasma) and nine (exudate) times greater than those previously reported in horses (receiving the same dose rate of PBZ). In the horse, the lower concentrations had produced marked inhibition of eicosanoid synthesis and suppressed the inflammatory response. The higher concentrations in calves were insufficient to inhibit significantly exudate prostaglandin E2 (PGE2), leukotriene B4 (LTB4) and beta-glucuronidase concentrations and exudate leucocyte numbers, serum thromboxane B2 (TxB2), and bradykinin-induced skin swelling. These differences from the horse might be the result of: (a) the presence in equine biological fluids of higher concentrations than in calves of the active PBZ metabolite, OPBZ; (b) a greater degree of binding of PBZ to plasma protein in calves; (c) species differences in the sensitivity to PBZ of the cyclo-oxygenase (COX) isoenzymes, COX-1 and COX-2 or; (d) a combination of these factors. To achieve clinical efficacy with single doses of PBZ in calves, higher dosages than 4.4 mg/kg will be probably required.     

The role of plasma protein binding on the metabolism and renal excretion of sulphadimethoxine and its metabolite N4-acetylsulphadimethoxine in pigs

The effects of plasma protein binding on the elimination of sulphadimethoxine (SDM) were examined after intravenous administration of 6.25, 12.5, 25, 50, 100 and 150 mg/kg to pigs. At an early stage of the experiment, the animals were anaesthetised by inhalation of enflurane to obtain a more exact relationship between plasma concentration and the renal excretion. SDM and its acetylated conjugate, N4-acetylsulphadimethoxine (N4-SDM) were detected in plasma and urine of all animals, and the recovery of the doses was almost complete in two animals with negligible renal excretion of SDM. The percentages of plasma protein binding of SDM and N4-SDM were almost similar, and ranged from 30 to 95%, depending on the plasma concentration. The metabolic clearance of SDM by acetylation increased when the plasma protein binding decreased. These results suggested that the main elimination route of SDM in pigs is acetylation, and that the plasma protein binding can have a large effect on the elimination of SDM in pigs. The effect of plasma protein binding on the renal clearance of SDM was not so evident, because urine pH had a much greater effect on it. The deacetylation of N4-SDM was detected after 25 mg/kg intravenous administration of N4-SDM, which suggests that the metabolic clearance of SDM is part of an acetylation-deacetylation equilibrium. Saturation of the active tubular reabsorption of SDM and of the active tubular secretion of N4-SDM was also suggested after higher doses of SDM.     

Some pharmacokinetic data about furaltadone and nitrofurazone administered orally to preruminant calves

A single oral dosage of furaltadone and nitrofurazone (14.0 mg/kg) to 5 preruminant calves (in a cross-over trial) revealed mean maximum plasma concentration of 2.5 and 3.5 microgram/ml, respectively, at approximately 3 h after administration. The final elimination half-lives of furaltadone and nitrofurazone were 2.5 and 5 h, respectively. Urinary recovery of these two nitrofurans in 3 calves revealed approximately 2% of the orally administered dose. The renal clearance of the unbound drugs did not differ (for both drugs approximately 0.42 ml/min/kg); furaltadone clearance was strongly related to urine flow.     

Pharmacokinetics and renal clearance of sulfamethazine, sulfamerazine, and sulfadiazine and their N4-acetyl and hydroxy metabolites in horses

Plasma disposition, protein binding, urinary recovery, and renal clearance of sulfamethazine (SMZ), sulfamerazine (SMR), and sulfadiazine (SDZ) and their N4-acetyl and hydroxy derivatives were studied in 4 horses in a crossover trial. The plasma concentration-time curves of the metabolites paralleled those of the parent drug in the elimination phase. Sulfamethazine and SMR were extensively metabolized. In plasma and urine, the main metabolite of the 3 sulfonamides tested was the 5-hydroxypyrimidine derivative, which was highly glucuronidated. Difference in elimination half-life of SMZ, SMR, and SDZ could be related to difference in metabolism and renal clearance values. Metabolism speeds drug elimination, producing compounds with higher renal clearance values than those of the parent drug. Methyl substitution in the pyrimidine side chain increased hydroxylation of the parent drug, but prolonged the persistence of the sulfonamides studied in the body. The high concentration of N4-acetyl and hydroxy metabolites of SMZ and SMR in plasma and urine decreased the potential antibacterial activity of the parent drugs. Sulfadiazine was less metabolized, and microbiologically determined SDZ concentrations in plasma and urine were slightly lower than those measured by high-performance liquid chromatography.     

The effect of supplementary feeds on the bodyweight of yaks in cold season

The present study was conducted to determine the effects of supplementary feeds, oat hay (OH), highland barley straw (HBS) and multi-nutrient blocks supplementation (UMMB) on reducing liveweight losses of both yak cows and calves grazed on low quality pastures during cold season. The trials of OH and HBS supplementation were conducted by using completely random design on 104 yak cows between 6 and 12 years of age as the following treatments: pure grazing (41 animals, body weight 230±67 kg) as control (CK); grazing+1.5 kg DM of OH per head daily (30 animals, body weight 216±28 kg); grazing+1.5 kg DM of HBS per head daily (33 animals, body weight 221±34 kg). The trial of UMMB was conducted on three types of yaks, 1-year calves (8-12 months old, body weight 61.1±6.9 kg), 2-year calves (18-24 months old, 98.0±11.3 kg) and yak cows (164.5±27.1 (S.D.) kg) with 20 animals in control group (CK) and 20 animals in supplement group for each type by using completely random design as the following treatments: pure grazing for CK group; grazing+150, 250 and 500 g UMMB per day averagely for 1-year calf, 2-year calf and cow at night. The results indicate that the animals supplemented with oat hay received body weight gain (32±20.7 g day⁻¹), while those supplemented with highland barley straw still suffered from body weight loss (−56.7±39.3 g day⁻¹); UMMB supplementation can decrease the body weight loss by 109.7%, 86.6% and 63.4% for the 1-year calves, 2-year calves and yak cows, respectively, as compared with pure grazing. Around US$1.60 output can be achieved on the basis of US$1 input for UMMB supplementation in the farming systems of the 1-year calves, 2-year calves and yak cows, while US$1 input can produce US$1.55 and 1.14 output for OH and HBS supplementations, respectively, in yak cows' farming system. It can be preliminary concluded that UMMB supplementation was the most economic way to alleviate body weight loss of grazing yaks over cold season, and the higher productive returns were obtained from OH supplementation for grazing yak cows during winter/spring months.     

Some pharmacokinetic data about furaltadone and nitrofurazone administered orally to preruminant calves

Summary

A single oral dosage of furaltadone and nitrofurazone (14.0 mg/kg) to 5 preruminant calves (in a cross‐over trial) revealed mean maximum plasma concentration of 2.5 and 3.5 pg/ml, respectively, at approximately 3 h after administration. The final elimination half‐lives of furaltadone and nitrofurazone were 2.5 and 5 h, respectively.

Urinary recovery of these two nitrofurans in 3 calves revealed approximately 2% of the orally administered dose. The renal clearance of the unbound drugs did not differ (for both drugs approximately 0.42 ml/min/kg);furaltadone clearance was strongly related to urine flow.     

Pharmacokinetics of quinidine sulfate in dairy cattle

Pharmacokinetic profile and therapeutic range of plasma quinidine concentration were determined in dairy Holstein cows. Plasma half-life of intravenous quinidine was 1.28 +/- 0.492 (0.41-1.65) hr. The pattern of plasma quinidine transition after oral administration varied greatly among individuals. Total body clearance was 58.7 +/- 24.49 ml/min/kg, although renal quinidine clearance was 0.76 +/- 0.441 ml/min/kg. Therefore, the involvement of some extrarenal organ as the main site of excretion was suspected. Seven cows, diagnosed as atrial fibrillation or ventricular premature contraction, were orally administered with quinidine at various dosages. They showed plasma concentration of 2.3 +/- 1.59 mg/l when therapeutic effect was observed. Clinical signs of intoxication were observed at plasma quinidine concentrations over 10 mg/l. These results suggest the difficulty with the maintenance of effective plasma quinidine concentration by an oral or a single intravenous administration, and thus it is concluded that use of quinidine for treatment arrhythmic cows must be carefully done in order to avoid possible intoxication.     

Pharmacokinetics and dosage regimen of 2-pyridine aldoxime in Bubalus bubalis intoxicated with fenitrothion

In the present study, the pharmacokinetics of 2-pyridine aldoxime (2-PAM, 30 mg/kg, i.v.) alone and in conjunction with atropine (0.3 mg/kg; 1/4 i.v., 3/4 i.m.) was investigated in 10 Bubalus bubalis intoxicated with a single oral lethal dose of fenitrothion (435 mg/kg). Based on the kinetic parameters, an appropriate dosage regimen of 2-PAM in B. bubalis was calculated. There was no significant difference between plasma levels and pharmacokinetic parameters of 2-PAM in the two groups of animals, given 2-PAM alone and in conjunction with atropine. The peak plasma concentration of 2-PAM at 1 min was in the range of 189.5-196.6 microg/mL which declined to 9.22-9.98 microg/mL at 4 h. The values of elimination half-life, Vd(area) and total body clearance were 2.41-2.67 h, 0.77-0.95 L/kg and 227.5-245.7 mL/kg/h, respectively. The binding capacity of 2-PAM to plasma proteins of fenitrothion-intoxicated buffalo calves and dissociation rate constant of protein drug complex were 0.015 x 10(-6) mol/g and 2.367 x 10(-6) mol, respectively. Approximately 63% of 2-PAM was bound with plasma proteins. In the treatment of organophosphate insecticide (OPI) toxicity in B. bubalis, an appropriate i.v. dosage regimen of 2-PAM in conjunction with atropine would be 18 mg/kg followed by 15 mg/kg at 4 h interval.     

Pharmacokinetics and body fluid and endometrial concentrations of trimethoprim-sulfamethoxazole in mares

Six healthy adult mares were each given a single IV injection of trimethoprim (TMP)-sulfamethoxazole (SMZ) at a dosage of 2.5 mg of TMP/kg of body weight and 12.5 mg of SMZ/kg. Serum concentrations of each drug were measured serially over a 24-hour period. For TMP, the mean overall elimination rate constant (K) was 0.43/hr and the elimination half-life (t1/2) was 1.9 hours. The apparent volume of distribution (at steady state) was 1.62 L/kg and TMP clearance was 886 ml/hr/kg. For SMZ, K was 0.22/hr and t1/2 was 3.53 hours. The apparent volume of distribution at steady state was 0.33 L/kg and SMZ clearance was 78.2 ml/hr/kg. Each mare was then given 5 consecutive oral doses of TMP-SMZ at a rate of 2.5 mg of TMP/kg and 12.5 mg of SMZ/kg at 12-hour intervals. Trimethoprim and SMZ concentrations were measured in serum, synovial fluid, peritoneal fluid, CSF, urine, and endometrium. Although both mean TMP and SMZ serum concentrations were higher after the 5th dose than after the 1st dose, only the mean TMP concentration was significantly (P less than 0.05) different. After the 5th oral dose, concentrations of TMP and SMZ attained in body fluids (except CSF) and endometrial tissue were equal to or exceeded reported minimum inhibitory concentrations for Corynebacterium pseudotuberculosis, Staphylococcus sp, Streptococcus zooepidemicus, and several obligate anaerobes. Absorption of both drugs was variable after oral administration.     

Pharmacokinetics and urinary excretion of sulphadimidine in buffalo calves

Pharmacokinetics and urinary excretion of sulphadimidine (SDI) were determined in buffalo calves following single oral administration (150 mg/kg). The plasma levels of free sulphadimidine were above minimum effective therapeutic concentration (> 40 micrograms/ml) between 4 and 12 h and the N4-acetylated form of the drug was in the range of 7.2-19.3%. Kinetic evaluation of plasma levels was performed using a two-compartment open model. The absorption and elimination half-lives of SDI were 3.01 and 11.94 h, respectively. Based on this study, an optimal dosage regimen of sulphadimidine in buffalo calves would be 100 mg/kg, followed by 50 mg/kg at 12 h intervals. Sulphadimidine was mainly excreted in the urine as free amine. The percentage of N4-acetyl sulphadimidine in urine was comparatively higher than in plasma.     

Age-dependent pharmacokinetics of oxytetracycline in ruminants

Oxytetracycline (OTC) was administered intravenously (i.v.) to 3-and 12-week-old calves and lactating cows, and both i.v. and intramuscularly (i.m) to 14-week-old calves and non-lactating cows. Concentrations of OTC were determined in plasma and were analysed kinetically. The pharmacokinetic parameters which were derived using the three-compartment open model were inadequate to describe plasma drug levels in six out of the 23 animals treated i.v., and, therefore, model-independent kinetic parameters were utilized for evaluating age-dependent pharmacokinetics of OTC. In the 3-week-old calves, the total body clearance (Cl b ) was 0.0022 ml/min/kg, the total distribution volume (V d area ) was 2.48 l/kg, and the distribution volume of the central compartment (V 1 ) was 0.56 l/kg. Mean values for Cl b , V d area , and V 1 in 3-week-old calves were two-, three- and four-fold greater, respectively, than the corresponding values in cows. Mean values of Cl b and V d area for the 12-and 14-week-old calves were intermediate between the corresponding values in 3-week-old calves and cows. Dose and state of lactation did not affect the model-independent parameters. The i.v. and i.m. data illustrated that the recommended dose levels of OTC in young calves should be twice those employed in cows for obtaining similar plasma OTC concentration-time profiles.