Pharmacokinetic studies of flunixin meglumine and phenylbutazone in plasma,exudate and transudate in sheep

Flunixin meglumine (FM, 1.1 mg/kg) and phenylbutazone (PBZ, 4.4 mg/kg) were administered intravenously (i.v.) as a single dose to eight sheep prepared with subcutaneous (s.c.) tissue-cages in which an acute inflammatory reaction was stimulated with carrageenan. Pharmacokinetics of FM, PBZ and its active metabolite oxyphenbutazone (OPBZ) in plasma, exudate and transudate were investigated. Plasma kinetics showed that FM had an elimination half-life (t_½β) of 2.48 ± 0.12 h and an area under the concentration – time curve (AUC) of 30.61 ± 3.41 μg/mL.h. Elimination of PBZ from plasma was slow (t_½β = 17.92 ± 1.74 h, AUC = 968.04 ± μg/mL.h.). Both FM and PBZ distributed well into exudate and transudate although penetration was slow, indicated by maximal drug concentration (C_max) for FM of 1.82 ± 0.22 μg/mL at 5.50 ± 0.73 h (exudate) and 1.58 ± 0.30 μg/mL at 8.00 h (transudate), and C_max for PBZ of 22.32 ± 1.29 μg/mL at 9.50 ± 0.73 h (exudate) and 22.07 ± 1.57 μg/mL at 11.50 ± 1.92 h (transudate), and a high mean tissue-cage fluids:plasma AUC_last ratio obtained in the FM and PBZ groups (80–98%). These values are higher than previous reports in horses and calves using the same or higher dose rates. Elimination of FM and PBZ from exudate and transudate was slower than from plasma. Consequently the drug concentrations in plasma were initially higher and subsequently lower than in exudate and transudate.     

Influence of oxytetracycline on carprofen pharmacodynamics and pharmacokinetics in calves

A tissue cage model of inflammation in calves was used to determine the pharmacokinetic and pharmacodynamic properties of individual carprofen enantiomers, following the administration of the racemate. RS(±) carprofen was administered subcutaneously both alone and in combination with intramuscularly administered oxytetracycline in a four‐period crossover study. Oxytetracycline did not influence the pharmacokinetics of R(?) and S(+) carprofen enantiomers, except for a lower maximum concentration (C_max) of S(+) carprofen in serum after co‐administration with oxytetracycline. S(+) enantiomer means for area under the serum concentration–time curve (AUC_0–96h were 136.9 and 128.3 μg·h/mL and means for the terminal half‐life (T_½k₁₀) were = 12.9 and 17.3 h for carprofen alone and in combination with oxytetracycline, respectively. S(+) carprofen AUC_0–96h in both carprofen treatments and T_½k₁₀ for carprofen alone were lower (P < 0.05) than R(?) carprofen values, indicating a small degree of enantioselectivity in the disposition of the enantiomers. Carprofen inhibition of serum thromboxane B₂ ex vivo was small and significant only at a few sampling times, whereas in vivo exudate prostaglandin (PG)E₂ synthesis inhibition was greater and achieved overall significance between 36 and 72 h (P < 0.05). Inhibition of PGE₂ correlated with mean time to achieve maximum concentrations in exudate of 54 and 42 h for both carprofen treatments for R(?) and S(+) enantiomers, respectively. Carprofen reduction of zymosan‐induced intradermal swelling was not statistically significant. These data provide a basis for the rational use of carprofen with oxytetracycline in calves and indicate that no alteration to carprofen dosage is required when the drugs are co‐administered.     

Disodium-fosfomycin pharmacokinetics and bioavailability in post weaning piglets

Disodium-fosfomycin pharmacokinetics has been studied in different species after oral, intravenous, intramuscular and subcutaneous administration. At present there are neither documented clinical experiences of the use of fosfomycin in pigs nor any published studies in weaning piglets, although it is a period of high incidence of infectious diseases. The pharmacokinetics and the bioavailability of sodium fosfomycin were studied in post weaning piglets after intravenous and intramuscular administration of 15 mg/kg of body weight. Plasma concentrations were measured by a high-performance liquid ms/ms. After IV administration the area under the fosfomycin concentration:time curve in plasma was AUC_(0–12) of 120.00 ± 23.12 μg h/ml and the volume of distribution (Vd) of 273.00 ± 40.70 ml/kg. The elimination was rapid with a plasma clearance of 131.50 ± 30.07 ml/kg/h and a T_1/2 of 1.54 ± 0.40 h. Peak serum concentration (C_max), T_max, AUC_(0–12) and bioavailability for the IM administration were 43.00 ± 4.10 μg/ml, 0.75 ± 0.00 h, 99.00 ± 0.70 μg h/ml and 85.5 ± 9.90% respectively. Different authors have determined a minimum inhibitory concentration (MIC₉₀) ranging from 0.25 μg/ml for Streptococcus sp. and 0.5 μg/ml for Escherichia coli. Considering the above, and according to the values of plasma concentration vs time profiles observed in this study, effective plasma concentrations of fosfomycin for sensitive bacteria can be obtained following IV and IM administration of 15 mg/kg in piglets.     

PK-PD integration and modeling of marbofloxacin in sheep

The fluoroquinolone antimicrobial drug, marbofloxacin, was administered intravenously (IV) and intramuscularly (IM) to sheep at a dose rate of 2 mg kg⁻¹ in a 2-period cross-over study. Using a tissue cage model of inflammation, the pharmacokinetic properties of marbofloxacin were established for serum, inflamed tissue cage fluid (exudate) and non-inflamed tissue cage fluid (transudate). For serum, after IV dosing, mean values for pharmacokinetic parameters were: clearance 0.48 L kg⁻¹ h⁻¹; elimination half-life 3.96 h and volumes of distribution 2.77 and 1.96 L kg⁻¹, respectively, for V_darea and V_ss. After IM dosing mean values for pharmacokinetic variables were: absorption half-time 0.112 h, time of maximum concentration 0.57 h, terminal half-life (T½el) 3.65 h and bioavailability 106%. For exudate, mean T½el values were 12.38 and 13.25 h, respectively, after IV and IM dosing and for transudate means were 13.39 h (IV) and 12.55 h (IM).The in vitro minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC) and ex vivo time-kill curves for marbofloxacin in serum, exudate and transudate were established against a pathogenic strain of Mannheimia haemolytica. Integration of in vivo pharmacokinetic data with MIC determined in vitro provided mean values of area under curve (AUC)/MIC ratio for serum, exudate and transudate of 120.2, 156.0 and 156.6 h after IV dosing and 135.5, 165.3 and 146.2 h after IM dosing, respectively. After IM administration maximum concentration (C_max)/MIC ratios were 21.1, 6.76 and 5.91, respectively, for serum, exudate and transudate. The ex vivo growth inhibition data after IM administration were fitted to the sigmoid E_max (Hill) equation to provide values for serum of AUC_24 h/MIC producing, bactericidal activity (22.51 h) and virtual eradication of bacteria (35.31 h). It is proposed that these findings might be used with MIC₅₀ or MIC₉₀ data to provide a rational approach to the design of dosage schedules which optimise efficacy in respect of bacteriological as well as clinical cures.     

Phenylbutazone and oxyphenbutazone distribution into tissue fluids in the horse

The clinically recommended dose rate of phenylbutazone (4.4 mg/kg) was administered intravenously as a single dose to five Welsh Mountain ponies. Distribution of phenylbutazone and its active metabolite oxyphenbutazone into body fluids was studied by measuring concentrations in plasma, tissue-cage fluid, peritoneal fluid and acute inflammatory exudate harvested from a polyester sponge model of inflammation. The ready penetration of phenylbutazone into inflammatory exudate was demonstrated by the relatively high mean value for C_max of 12.4 μg/ml occurring at a time of 4.6 h and a mean AUQ)_24 of 128 μg-h/ml. A high mean exudate: plasma AUCo_24 ratio of 0.83 was recorded. Plasma: exudate concentration ratios for phenylbutazone were initially greater than and subsequently less than one; the slower clearance from exudate was indicated by approximate t_½β values of 4.8 and 24 h for plasma and exudate, respectively. These findings may help to explain the relatively long duration of action of phenylbutazone, in spite of a plasma elimination half-life of less than 5 h. Lower values of C_max and AUC_0–24 for phenylbutazone passage into peritoneal fluid (6.3 μg/ml and 45 (μh/ml) were recorded, and a limited number of sampling times indicated a similar degree of penetration as into tissue cage fluid. Mean concentrations of oxyphenbutazone in all fluids were lower than phenylbutazone concentrations at all times, but ready penetration of the metabolite into body fluids, especially into inflammatory exudate, occurred suggesting that oxyphenbutazone may contribute to the anti-inflammatory effect. The hyperaemia of acute inflammation and the high protein levels in inflammatory exudate may both assist passage of phenylbutazone and oxyphenbutazone into exudate. The slower clearance of both compounds from exudate, periton?ceal fluid and tissue cage fluid than from plasma is similar to previous reports for other drugs.     

Pharmacokinetic/pharmacodynamic relationship of marbofloxacin against Pasteurella multocida in a tissue‐cage model in yellow cattle

The fluoroquinolone antimicrobial drug marbofloxacin was administered to yellow cattle intravenously and intramuscularly at a dose of 2 mg/kg of body weight in a two‐period crossover study. The pharmacokinetic properties of marbofloxacin in serum, inflamed tissue‐cage fluid (exudate), and noninflamed tissue‐cage fluid (transudate) were studied by using a tissue‐cage model. The in vitro and ex vivo activities of marbofloxacin in serum, exudate, and transudate against a pathogenic strain of Pasteurella multocida (P. multocida) were determined. Integration of in vivo pharmacokinetic data with the in vitro MIC provided mean values for the area under the curve (AUC)/MIC for serum, exudate, and transudate of 155.75, 153.00, and 138.88, respectively, after intravenous dosing and 160.50, 151.00, and 137.63, respectively, after intramuscular dosing. After intramuscular dosing, the maximum concentration/MIC ratios for serum, exudate, and transudate were 21.13, 9.13, and 8.38, respectively. The ex vivo growth inhibition data after intramuscular dosing were fitted to the inhibitory sigmoid E_max equation to provide the values of AUC/MIC required to produce bacteriostasis, bactericidal activity, and elimination of bacteria. The respective values for serum were 17.25, 31.29, and 109.62, and slightly lower values were obtained for transudate and exudate. It is proposed that these findings might be used with MIC₅₀ or MIC₉₀ data to provide a rational approach to the design of dosage schedules which optimize efficacy in respect of bacteriological as well as clinical cures.     

Pharmacokinetics of enrofloxacin HCl‐2H2O (ENRO‐C), PK/PD,and Monte Carlo modeling vs. Leptospira spp. in cows

The pharmacokinetics, PK/PD ratios, and Monte Carlo modeling of enrofloxacin HCl‐2H₂O (Enro‐C) and its reference preparation (Enro‐R) were determined in cows. Fifty‐four Jersey cows were randomly assigned to six groups receiving a single IM dose of 10, 15, or 20 mg/kg of Enro‐C (Enro‐C₁₀, Enro‐C₁₅, Enro‐C₂₀) or Enro‐R. Serial serum samples were collected and enrofloxacin concentrations quantified. A composite set of minimum inhibitory concentrations (MIC) of Leptospira spp. was utilized to calculate PK/PD ratios: maximum serum concentration/MIC (C_max/MIC₉₀) and area under the serum vs. time concentration of enrofloxacin/MIC (AUC_0‐24/MIC₉₀). Monte Carlo simulations targeted C_max/MIC = 10 and AUC_0‐24/MIC = 125. Mean C_max obtained were 6.17 and 2.46 μg/ml; 8.75 and 3.54 μg/ml; and 13.89 and 4.25 μg/ml, respectively for Enro‐C and Enro‐R. C_max/MIC₉₀ ratios were 6.17 and 2.46, 8.75 and 3.54, and 13.89 and 4.25 for Enro‐C and Enro‐R, respectively. Monte Carlo simulations based on C_max/MIC₉₀ = 10 indicate that only Enro‐C₁₅ and Enro‐C₂₀ may be useful to treat leptospirosis in cows, predicting a success rate ≥95% when MIC₅₀ = 0.5 μg/ml, and ≥80% when MIC₉₀ = 1.0 μg/ml. Although Enro‐C₁₅ and Enro‐C₂₀ may be useful to treat leptospirosis in cattle, clinical trials are necessary to confirm this proposal.     

Pharmacological assessment of netobimin as a potential anthelmintic for use in horses: Plasma disposition, faecal excretion and efficacy

This study aimed to determine the plasma disposition and faecal excretion of netobimin (NTB) and its respective metabolites as well as the efficacy against strongyles in horses following oral administration. Netobimin (10 mg/kg) was administered orally to 8 horses. Blood and faecal samples were collected from 1 to 120 h post-treatment and analysed by high performance liquid chromatography (HPLC). Using a chiral phase-based HPLC, plasma disposition of ABZSO enantiomers produced was also determined. Faecal strongyle egg counts (EPG) were performed by a modified McMaster’s technique before and after the treatment. Neither NTB nor ABZ were present and only albendazole sulphoxide (ABZSO) and sulphone metabolites (ABZSO₂) were detected in the plasma samples. Maximum plasma concentration of ABZSO (0.53 ± 0.14 μg/ml) and ABZSO₂ (0.36 ± 0.09 μg/ml) were observed at (t_max) 10.50 and 19.50 h, respectively following administration of NTB. The area under the curve (AUC) of the two metabolites was similar to each other. Netobimin was not detected, and ABZ was predominant in faecal samples. The maximum plasma concentration (C_max) of (−)ABZSO was significantly higher than (+)ABZSO, but the area under the curves (AUCs) of the enantiomer were not significantly different each other in plasma samples. The enantiomers of ABZSO were close to racemate in the faecal samples analyzed. Netobimin reduced the EPG by 100%, 100%, 77%, 80% and 75% 2, 4, 6, 8 and 10 weeks post-treatment, respectively. The specific behaviour of the two enantiomers probably reflects different enantioselectivity of the enzymatic systems of the liver which are responsible for sulphoxidation and sulphonation of ABZ. Considering the pharmacokinetic and efficacy parameters NTB could be used as an anthelmintic in horses.     

Pharmacokinetic/pharmacodynamic integration and modelling of amoxicillin for the calf pathogens Mannheimia haemolytica and Pasteurella multocida

The antimicrobial properties of amoxicillin were determined for the bovine respiratory tract pathogens, Mannheima haemolytica and Pasteurella multocida. Minimum inhibitory concentration (MIC), minimum bactericidal concentration (MBC) and time‐kill curves were established. Pharmacokinetic (PK)/pharmacodynamic (PD) modelling of the time‐kill data, based on the sigmoidal E_max equation, generated parameters for three levels of efficacy, namely bacteriostatic, bactericidal (3log₁₀ reduction) and 4log₁₀ reduction in bacterial counts. For these levels, mean AUC_(0–24 h)/MIC serum values for M. haemolytica were 29.1, 57.3 and 71.5 h, respectively, and corresponding values for P. multocida were 28.1, 44.9 and 59.5 h. Amoxicillin PK was determined in calf serum, inflamed (exudate) and noninflamed (transudate) tissue cage fluids, after intramuscular administration of a depot formulation at a dosage of 15 mg/kg. Mean residence times were 16.5 (serum), 29.6 (exudate) and 29.0 h (transudate). Based on serum MICs, integration of in vivo PK and in vitro PD data established maximum concentration (C_max)/MIC ratios of 13.9:1 and 25.2:1, area under concentration–time curve (AUC_0–∞)/MIC ratios of 179 and 325 h and T>MIC of 40.3 and 57.6 h for P. multocida and M. haemolytica, respectively. Monte Carlo simulations for a 90% target attainment rate predicted single dose to achieve bacteriostatic and bactericidal actions over 48 h of 17.7 and 28.3 mg/kg (M. haemolytica) and 17.7 and 34.9 mg/kg (P. multocida).     

Some pharmacokinetic indices of oral fluconazole administration to koalas (Phascolarctos cinereus) infected with cryptococcosis

Three asymptomatic koalas serologically positive for cryptococcosis and two symptomatic koalas were treated with 10 mg/kg fluconazole orally, twice daily for at least 2 weeks. The median plasma C_max and AUC_0‐8 h for asymptomatic animals were 0.9 μg/mL and 4.9 μg/mL·h, respectively; and for symptomatic animals 3.2 μg/mL and 17.3 μg/mL·h, respectively. An additional symptomatic koala was treated with fluconazole (10 mg/kg twice daily) and a subcutaneous amphotericin B infusion twice weekly. After 2 weeks the fluconazole C_max was 3.7 μg/mL and the AUC_0‐8 h was 25.8 μg/mL*h. An additional three koalas were treated with fluconazole 15 mg/kg twice daily for at least 2 weeks, with the same subcutaneous amphotericin protocol co‐administered to two of these koalas (C_max: 5.0 μg/mL; mean AUC_0‐8 h: 18.1 μg/mL*h). For all koalas, the fluconazole plasma C_max failed to reach the MIC₉₀ (16 μg/mL) to inhibit C. gattii. Fluconazole administered orally at either 10 or 15 mg/kg twice daily in conjunction with amphotericin is unlikely to attain therapeutic plasma concentrations. Suggestions to improve treatment of systemic cryptococcosis include testing pathogen susceptibility to fluconazole, monitoring plasma fluconazole concentrations, and administration of 20–25 mg/kg fluconazole orally, twice daily, with an amphotericin subcutaneous infusion twice weekly.     

Pharmacokinetics of ceftiofur crystalline free acid after single and multiple subcutaneous administrations in healthy alpacas (Vicugna pacos)

Dechant, J. E., Rowe, J. D., Byrne, B. A., Wetzlich, S. E., Kieu, H. T., Tell, L. A. Pharmacokinetics of ceftiofur crystalline free acid after single and multiple subcutaneous administrations in healthy alpacas (Vicugna pacos). J. vet. Pharmacol. Therap.  36 , 122–129. Six adult male alpacas received one subcutaneous administration of ceftiofur crystalline free acid (CCFA) at a dosage of 6.6 mg/kg. After a washout period, the same alpacas received three subcutaneous doses of 6.6 mg/kg CCFA at 5‐day intervals. Blood samples collected from the jugular vein before and at multiple time points after each CCFA administration were assayed for ceftiofur‐ and desfuroylceftiofur‐related metabolite concentrations using high‐performance liquid chromatography. Pharmacokinetic disposition of CCFA was analyzed by a noncompartmental approach. Mean pharmacokinetic parameters (±SD) following single‐dose administration of CCFA were C_max (2.7 ± 0.9 μg/mL); T_max (36 ± 0 h); area under the curve AUC_0→∞ (199.2 ± 42.1 μg·h/mL); terminal phase rate constant λz (0.02 ± 0.003/h); and terminal phase rate constant half‐life t_1/2λz (44.7 h; harmonic). Mean terminal pharmacokinetic parameters (±SD) following three administrations of CCFA were C_max (2.0 ± 0.4 μg/mL); T_max (17.3 ± 16.3 h); AUC_0→∞ (216.8 ± 84.5 μg·h/mL); λz (0.01 ± 0.003/h); and t_1/2λz (65.9 h; harmonic). The terminal phase rate constant and the T_max were significantly different between single and multiple administrations. Local reactions were noted in two alpacas following multiple CCFA administrations.     

Pharmacokinetics and pharmacodynamics of ketoprofen in calves applying PK/PD modelling

The pharmacokinetics (PK) and pharmacodynamics (PD) of ketoprofen (KTP) were studied in calves following intravenous administration of the drug racemate at a dose rate of 3 mg/kg. To evaluate the anti-inflammatory properties of KTP, a model of acute inflammation, consisting of surgically implanted subcutaneous tissue cages stimulated by intracaveal injection of carrageenan, was used. No differences were observed between disposition curves of KTP enantiomers in plasma, exudate or transudate. This indicates that in calves KTP pharmacokinetics is not enantioselective. S(+)- and R(-)- KTP each had a short elimination half-life (t_1/2β of 0.42 ± 0.08 h and 0.42 ± 0.09 h, respectively. The volume of distribution (V_d) was low, values of 0.20 ± 0.06 L/kg and 0.22 ± 0.06 L/kg being obtained for R(-) and S(+)KTP, respectively. Body clearance (CI₈) was high, correlating with the short elimination half-life, 0.3 3 ± 0.03 L/kg/h [R(-)KTP] and 0.32 ± 0.04 L/kg/h [S(+)-KTP]. KTP pharmacodynamics was evaluated by determining the effects on serum thromboxane (TxB₂), exudate prostaglandin (PGE₂), leukotriene (LTB₄) and β-glucuronidase (β-glu) and bradykinin (BK)-induced oedematous swelling. Effect-concentration inter-relationships were analysed by PK/PD modelling. KTP did not affect exudate LTB₄, but inhibition of the other variables was statistically significant. The mean EC₅₀ values for inhibition of serum TxB₂, exudate PGE₂ and β-glu and BK-induced swelling were 0.118, 0.086, 0.06 and 0.00029 μg/mL, respectively. These data indicate that KTP exerted an inhibitory action, not only as expected, on eicosanoid (TxB₂ and PGE₂) synthesis but also on exudate β-glu and BK-induced oedema. The EC₅₀ values for these actions indicate that they are likely to contribute to the overall anti-inflammatory effects of KTP in calves. However, claims that KTP inhibits 5-lipoxygenase and thereby blocks the production of inflammatory mediators such as LTB₄ were not substantiated. PK/PD modelling has proved to be a useful tool for analysing the in vivo pharmacodynamics of KTP and for providing new approaches to elucidating its mechanism(s) of action.     

Enantiospecific pharmacokinetics and pharmacodynamics of ketoprofen in sheep

Pharmacokinetic and pharmacodynamic parameters were established for the enantiomers of the 2-arylpropionic acid (APA) nonsteroidal anti-inflammatory drug (NSAID), ketoprofen (KTP). Each enantiomer was administered separately (1.5 mg/kg) and in a racemic mixture (3 mg/kg) intravenously (i.v.) to a group of eight sheep in a four-way, four-period cross-over study using a tissue cage model of inflammation. Plasma disposition of each KTP enantiomer was similar following separate administration of the pure compounds compared to administration of the racemic mixture. S(+)KTP volume of distribution (Vd(area)) was higher and clearance (ClB) faster than those of R(-)KTP. S(+) and R(-)KTP achieved relatively low concentrations in exudate and transudate. Unidirectional limited chiral inversion of R(-) to S(+)KTP was demonstrated. After R(-)KTP administration S(+)KTP was detected in plasma, but not in either exudate or transudate. Pharmacokinetic/pharmacodynamic (PK/PD) modelling of the data could not be undertaken following R(-)KTP administration because of chiral inversion to S(+)KTP, but the pharmacodynamic parameters, calculated maximum effect (Emax), concentration producing 50% effect (EC50), Hill's coefficient (N), rate constant of elimination of drug effect from the compartment (KeO) and mean equilibration half-life (t1/2KeO) were determined for S(+)KTP after administration of the racemic mixture as well as the pure compound.     

Pharmacokinetics of azithromycin in lactating dairy cows with subclinical mastitis caused by Staphylococcus aureus

Lucas, M. F., Errecalde, J. O., Mestorino, N. Pharmacokinetics of azithromycin in lactating dairy cows with subclinical mastitis caused by Staphylococcus aureus. J. vet. Pharmacol. Therap. 33 , 132–140. Azithromycin is a time‐dependent antimicrobial with long persistence. The main characteristics of azithromycin suggest that it could be useful for treating bovine mastitis caused by Staphylococcus aureus. To investigate this possibility, its pharmacokinetic (PK) behavior was studied. Six Holstein lactating cows with subclinical mastitis were administered two 10 mg/kg intramuscular (i.m.) doses of azithromycin, with a 48‐h interval. Milk and plasma concentrations were measured by microbiological assay. The MIC₉₀ was determined in 51 S. aureus isolations to calculate pharmacokinetic/pharmacodynamic (PK/PD) parameters. Milk maximal concentration (C_max) was 7.76 ± 1.76 μg/mL (16.67 h post‐first administration) and 7.82 ± 2.18 μg/mL (14 h post‐2^nd administration). In plasma C_max was 0.18 ± 0.03 μg/mL (2 h post‐1^rst administration) and 0.11 ± 0.03 μg/mL (14 h post‐2^nd administration). Azithromycin was eliminated from the milk with a half‐life (T½λ) of 158.26 ± 137.7 h after 2^nd administration, meanwhile plasma T½λ resulted shorter(13.97 ± 11.1 h). The mean area under the concentration vs. time curve from 0 to 24 h (AUC_0‐24h) was 153.82 ± 34.66 μg·h/mL in milk secretion and 2.61 ± 0.59 μg·h/mL in plasma. Infection presence in the quarters had a significant effect (P < 0.05) on the area under the concentration vs. time curve from 0 to infinity (AUC_0‐∞) and clearance from the mammary gland (Cl_mam/F). Moreover, it had influence on milk bioavailability (F_milk), T½λ, AUC_0‐∞ and mean residence time (MRT) in milk, which values resulted increased in mastitic quarters. In this study, it was determined that the production level and the mammary health status have an influence on PK parameters of azithromycin treatments in bovine mastitis.     

Plasma Disposition and Faecal Excretion of Netobimin Metabolites and Enantiospecific Disposition of Albendazole Sulphoxide Produced in Ewes

Netobimin (NTB) was administered orally to ewes at 20 mg/kg bodyweight. Blood and faecal samples were collected from 1 to 120 h post-treatment and analysed by high-performance liquid chromatography (HPLC). Using a chiral phase-based HPLC, plasma disposition of albendazole sulphoxide (ABZSO) enantiomers produced was also determined. Neither NTB nor albendazole (ABZ) was present and only ABZSO and albendazole sulphone (ABZSO₂) metabolites were detected in the plasma samples. Maximum plasma concentrations (C<_max) of ABZSO (4.1 ± 0.7 μg/ml) and ABZSO₂ (1.1 ± 0.4 μg/ml) were detected at (t _max) 14.7 and 23.8 h, respectively following oral administration of netobimin. The area under the curve (AUC) of ABZSO (103.8 ± 22.8 (μg h)/ml) was significantly higher than that ABZSO₂(26.3± 10.1 (μg h)/ml) (p<0.01). (−)−ABZSO and (+)-ABZSO enantiomers were never in racemate proportions in plasma. The AUC of (+)-ABZSO (87.8±20.3 (μg h)/ml) was almost 6 times larger than that of (−)−ABZSO (15.5 ±5.1 (μg h)/ml) (p < 0.001). Netobimin was not detected, and ABZ was predominant and its AUC was significantly higher than that of ABZSO and ABZSO₂, following NTB administration in faecal samples (p > 0.01). Unlike in the plasma samples, the proportions of the enantiomers of ABZSO were close to racemic and the ratio of the faecal AUC of (−)−ABZSO (172.22 ±57.6 (μg h)/g) and (+)-ABZSO (187.19 ±63.4 (μg h)/g) was 0.92. It is concluded that NTB is completely converted to ABZ by the gastrointestinal flora and absorbed ABZ is completely metabolized to its sulphoxide and sulphone metabolites by first-pass effects. The specific behaviour of the two enantiomers probably reflects different enantioselectivity of the enzymatic systems of the liver that are responsible for sulphoxidation and sulphonation of ABZ.     

Pharmacokinetics of erythromycin after the administration of intravenous and various oral dosage forms to dogs

The purpose of this study was to describe and compare the pharmacokinetic properties of different formulations of erythromycin in dogs. Erythromycin was administered as lactobionate (10 mg/kg, IV), estolate tablets (25 mg/kg p.o.) and ethylsuccinate tablets or suspension (20 mg/kg p.o.). After intravenous (i.v.) administration, the principal pharmacokinetic parameters were (mean ± SD): AUC_(0–∞) 4.20 ± 1.66 μg·h/mL; C_max 6.64 ± 1.38 μg/mL; V_z 4.80 ± 0.91 L/kg; Cl_t 2.64 ± 0.84 L/h·kg; t_½λ 1.35 ± 0.40 h and MRT 1.50 ± 0.47 h. After the administration of estolate tablets and ethylsuccinate suspension, the principal pharmacokinetic parameters were (mean ± SD): C_max, 0.30 ± 0.17 and 0.17 ± 0.09 μg/mL; t_max, 1.75 ± 0.76 and 0.69 ± 0.30 h; t_½λ, 2.92 ± 0.79 and 1.53 ± 1.28 h and MRT, 5.10 ± 1.12 and 2.56 ± 1.77 h, respectively. The administration of erythromycin ethylsuccinate tablets did not produce measurable serum concentrations. Only the i.v. administration rendered serum concentrations above MIC₉₀ = 0.5 μg/mL for 2 h. However, these results should be cautiously interpreted as tissue erythromycin concentrations have not been measured in this study and, it is recognized that they can reach much higher concentrations than in blood, correlating better with clinical efficacy.     

Pharmacokinetic–pharmacodynamic integration and modelling of florfenicol in calves

Florfenicol was administered subcutaneously to 10 calves at a dose of 40 mg/kg. Pharmacokinetic–pharmacodynamic (PK‐PD) integration and modelling of the data were undertaken using a tissue cage model, which allowed comparison of microbial growth inhibition profiles in three fluids, serum, exudate and transudate. Terminal half‐lives were relatively long, so that florfenicol concentrations were well maintained in all three fluids. Minimum inhibitory concentration (MIC) and minimum bactericidal concentration were determined in vitro for six strains each of the calf pneumonia pathogens, Mannhemia haemolytica and Pasteurella multocida. An PK‐PD integration for three serum indices provided mean values for P. multocida and M. haemolytica, respectively, of 12.6 and 10.4 for C_max/MIC, 183 and 152 h for AUC_0–24 h/MIC and 78 and 76 h for T>MIC. Average florfenicol concentrations in serum exceeded 4 × MIC and 1.5 × MIC for the periods 0–24 and 48–72 h, respectively. Ex vivo growth inhibition curves for M. haemolytica and P. multocida demonstrated a rapid (with 8 h of exposure) and marked (6 log₁₀ reduction in bacterial count or greater) killing response, suggesting a concentration‐dependent killing action. During 24‐h incubation periods, inhibition of growth to a bacteriostatic level or greater was maintained in serum samples collected up to 96 h and in transudate and exudate samples harvested up to 120 h. Based on the sigmoidal E_max relationship, PK‐PD modelling of the ex vivo time–kill data provided AUC_0–24 h/MIC serum values for three levels of growth inhibition, bacteriostatic, bactericidal and 4 log₁₀ decrease in bacterial count; mean values were, respectively, 8.2, 26.6 and 39.0 h for M. haemolytica and 7.6, 18.1 and 25.0 h for P. multocida. Similar values were obtained for transudate and exudate. Based on pharmacokinetic and PK‐PD modelled data obtained in this study and scientific literature values for MIC distributions, Monte Carlo simulations over 100 000 trials were undertaken to predict once daily dosages of florfenicol required to provide 50% and 90% target attainment rates for three levels of growth inhibition, namely, bacteriostasis, bactericidal action and 4 log₁₀ reduction in bacterial count.     

Single and multiple dose pharmacokinetics of a novel mirtazapine transdermal ointment in cats

Single and multiple dose pharmacokinetics (PK) of mirtazapine transdermal ointment applied to the inner ear pinna of cats were assessed. Study 1 was a randomized, cross‐over single dose study (n = 8). Cats were treated once with 0.5 mg/kg of mirtazapine transdermal ointment applied topically to the inner ear pinna (treatment) or administered orally (control) and then crossed over after washout. Plasma was collected predose and at specified intervals over 96 hr following dosing. Study 2 was a multiple dose study (n = 8). Cats were treated daily for 14 days with 0.5 mg/kg of mirtazapine transdermal ointment applied topically to the inner pinna. Plasma was collected on Day 13 predose and at specified intervals over 96 hr following the final dose. In Study 1, single transdermal administration of mirtazapine resulted in mean T_max = 15.9 hr, C_max = 21.5 ng/mL, AUC_0‐24 = 100 ng*hr/mL, AUC_0‐∞ = 260 ng*hr/mL and calculated half‐life = 26.8 hr. Single oral administration of mirtazapine resulted in mean T_max = 1.1 hr, C_max = 83.1 ng/mL, AUC_0‐24 = 377 ng*hr/mL, AUC_0‐∞ = 434 ng*hr/mL and calculated half‐life = 10.1 hr. Mean relative bioavailability (F) of transdermal to oral dosing was 64.9%. In Study 2, daily application of mirtazapine for 14 days resulted in mean T_max = 2.1 hr, C_max = 39.6 ng/mL, AUC_0‐24 = 400 ng*hr/mL, AUC_0‐∞ = 647 ng*hr/mL and calculated half‐life = 20.7 hr. Single and repeat topical doses of a novel mirtazapine transdermal ointment achieve measurable plasma concentrations in cats.     

Pharmacokinetic Parameters of (R)-(−) and (S)-(+)-Flurbiprofen in Dairy Bovines

The aim of the study was to evaluate the pharmacokinetics of flurbiprofen (FBP) in different age groups and physiological status groups in dairy cattle. Ten Argentine Holstein bovines were divided into three different groups: 3 cows in early lactation, 3 cows in gestation and 4 newborn calves. Based on previous experience, all the animals received racemic FBP (50:50) at a dose of 0.5 mg/kg by intravenous administration. Blood samples were taken at predetermined times after administration of flurbiprofen. Plasma enantiomer concentrations were measured by HPLC. Total body clearance (ClB) of (S)-(+)-FBP was higher in calves than in cows (114.5, 136.4, 121.4, 128.9 μg/ml vs 22.0, 24.2, 46.5 μg/ml and 27.6, 25.3, 34.6 μg/ml). In calves the disposition kinetics showed stereoselective behaviour. Area under the concentration–time curve (AUC) was higher and Cl_B and steady-state volume of distribution (V_ss) were lower for (R)-(−)-FBP than for (S)-(+)-FBP. In cows, stereoselectivity was observed in Cl_B and elimination half-life (fract₁2)(frac{t_1}{2}) only in the early lactation group. In this study, enantioselective metabolic behaviour of FBP under the physiological situations studied was found. Hence, it is possible that both enantiomers of flurbiprofen may contribute to the drug's therapeutic effects, but further studies with the administration of separate enantiomers will be required to elucidate their metabolism.     

Characterization of the pharmacokinetic disposition of levofloxacin in stallions after intravenous and intramuscular administration

The target of the present study was to investigate the plasma disposition kinetics of levofloxacin in stallions (n = 6) following a single intravenous (i.v.) bolus or intramuscular (i.m.) injection at a dose rate of 4 mg/kg bwt, using a two‐phase crossover design with 15 days as an interval period. Plasma samples were collected at appropriate times during a 48‐h administration interval, and were analyzed using a microbiological assay method. The plasma levofloxacin disposition was best fitted to a two‐compartment open model after i.v. dosing. The half‐lives of distribution and elimination were 0.21 ± 0.13 and 2.58 ± 0.51 h, respectively. The volume of distribution at steady‐state was 0.81 ± 0.26 L/kg, the total body clearance (Cl_tot) was 0.21 ± 0.18 L/h/kg, and the areas under the concentration–time curves (AUCs) were 18.79 ± 4.57 μg.h/mL. Following i.m. administration, the mean t_1/2el and AUC values were 2.94 ± 0.78 h and 17.21 ± 4.36 μg.h/mL. The bioavailability was high (91.76% ± 12.68%), with a peak plasma mean concentration (C_max) of 2.85 ± 0.89 μg/mL attained at 1.56 ± 0.71 h (T_max). The in vitro protein binding percentage was 27.84%. Calculation of efficacy predictors showed that levofloxacin might have a good therapeutic profile against Gram‐negative and Gram‐positive bacteria, with an MIC ≤ 0.1 μg/mL.