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.     

Disposition of ampicillin trihydrate in plasma,uterine tissue,lochial fluid,and milk of postpartum dairy cattle

The objective of this study was to determine the disposition of ampicillin in plasma, uterine tissue, lochial fluid, and milk of postpartum dairy cattle. Ampicillin trihydrate was administered by intramuscular (i.m.) injection at a dose of 11 mg/kg of body weight every 24 h (n = 6, total of 3 doses) or every 12 h (n = 6, total of 5 doses) for 3 days. Concentrations of ampicillin were measured in plasma, uterine tissue, lochial fluid, and milk using HPLC with ultraviolet absorption. Quantifiable ampicillin concentrations were found in plasma, milk, and lochial fluid of all cattle within 30 min, 4 h, and 4 h of administration of ampicillin trihydrate, respectively. There was no significant effect of dosing interval (every 12 vs. every 24 h) and no significant interactions between dosing interval and sampling site on the pharmacokinetic variable measured or calculated. Median peak ampicillin concentration at steady‐state was significantly higher in lochial fluid (5.27 μg/mL after q 24 h dosing) than other body fluids or tissues and significantly higher in plasma (3.11 μg/mL) compared to milk (0.49 μg/mL) or endometrial tissue (1.55 μg/mL). Ampicillin trihydrate administered once daily by the i.m. route at the label dose of 11 mg/kg of body weight achieves therapeutic concentrations in the milk, lochial fluid, and endometrial tissue of healthy postpartum dairy cattle.     

Effects of food intake on pharmacokinetics of mosapride in beagle dogs

This study was performed to determine the pharmacokinetic profile of mosapride in fasting and fed states. A single 5‐mg oral dose of mosapride was administered to fasted (n = 15) and fed (n = 12) beagle dogs, and the plasma concentrations of mosapride were measured by liquid chromatography–tandem mass spectrometry. The resultant data were analyzed by noncompartmental analysis (NCA). Mosapride was absorbed in fasted and fed dogs with similar T_max. Both C_max and AUC were significantly higher in the fasting group than in fed dogs, being four times (10.51 μg/mL vs. 2.76 μg/mL) and 3.5 times higher (38.53 h·μg/mL vs. 10.22 h·μg/mL), respectively. These findings suggest that food intake affects the pharmacokinetics of mosapride and that the dosage regimen for this drug need to be reconsidered.     

Oral chloramphenicol dosage regimens in cats

Five adult domestic cats were each given three separate 3-day courses of chloramphenicol, using a different oral-dosage regimen each time. The regimens were: 120 mg/kg/day divided 8-hourly, 60 mg/kg/day divided 8-hourly, and 50 mg per cat every 12 h (25–40 mg/kg/day). The interval between successive courses was 3 weeks. On the third day of each course plasma samples were obtained at fixed intervals after dosing and were assayed chemically for chloramphenicol. The ranges from peak to trough chloramphenicol concentrations with each regimen were (values are means ± SEM): 63.8 ± 4.60 to 43.0 ± 3.32 μg/ml (120 mg/kg/day), 42.0 ± 3.63 to 24.7 ± 1.83 μg/ml (60 mg/kg/day), and 24.3 ± 1.72 to 7.5 ± 0.85 μg/ml (50 mg per cat 12-hourly). Because of these findings, previous toxicity studies, and the proposed therapeutic (effective and safe) concentration for chloramphenicol of 5–15 μg/ml, it is suggested that a regimen of 50 mg per animal every 12 h could be adequate for chloramphenicol therapy in cats of average size (2.5-3.9 kg) and should be evaluated clinically.     

Clinical pharmacokinetics and outcomes of oral fluconazole therapy in dogs and cats with naturally occurring fungal disease

This multi-institutional study was designed to determine the clinical pharmacokinetics of fluconazole and outcomes in client-owned dogs (n = 37) and cats (n = 35) with fungal disease. Fluconazole serum concentrations were measured. Pharmacokinetic analysis was limited to animals at steady state (≥72 hr of treatment). The mean (range) body weight in 31 dogs was 25.6 (2.8–58.2) kg and in 31 cats was 3.9 (2.4–6.1) kg included in pharmacokinetic analyses. The dose, average steady-state serum concentrations (C_SS), and oral clearance in dogs were 14.2 (4.5–21.3) mg/kg/d, 26.8 (3.8–61.5) µg/mL, and 0.63 ml min⁻¹ kg⁻¹, respectively, and in cats were 18.6 (8.2–40.0) mg/kg/d, 32.1 (1.9–103.5) µg/mL, and 0.61 ml min⁻¹ kg⁻¹, respectively. Random inter-animal pharmacokinetic variability was high in both species. Two dogs had near twofold increases in serum fluconazole when generic formulations were changed, suggesting lack of bioequivalence. Median C_SS for dogs and cats achieving clinical remission was 19.4 and 35.8 µg/ml, respectively. Starting oral doses of 10 mg/kg q12h in dogs and 50–100 mg total daily dose in cats are recommended to achieve median C_SS associated with clinical remission. Due to the large pharmacokinetic variability, individualized dose adjustments based on C_SS (therapeutic drug monitoring) and treatment failure should be considered.     

Pharmacokinetics of chloramphenicol following administration of intravenous and subcutaneous chloramphenicol sodium succinate,and subcutaneous chloramphenicol,to koalas (Phascolarctos cinereus)

Clinically normal koalas (n = 19) received a single dose of intravenous (i.v.) chloramphenicol sodium succinate (SS) (25 mg/kg; n = 6), subcutaneous (s.c.) chloramphenicol SS (60 mg/kg; n = 7) or s.c. chloramphenicol base (60 mg/kg; n = 6). Serial plasma samples were collected over 24–48 h, and chloramphenicol concentrations were determined using a validated high‐performance liquid chromatography assay. The median (range) apparent clearance (CL/F) and elimination half‐life (t_1/2) of chloramphenicol after i.v. chloramphenicol SS administration were 0.52 (0.35–0.99) L/h/kg and 1.13 (0.76–1.40) h, respectively. Although the area under the concentration–time curve was comparable for the two s.c. formulations, the absorption rate‐limited disposition of chloramphenicol base resulted in a lower median C_max (2.52; range 0.75–6.80 μg/mL) and longer median t_max (8.00; range 4.00–12.00 h) than chloramphenicol SS (C_max 20.37, range 13.88–25.15 μg/mL; t_max 1.25, range 1.00–2.00 h). When these results were compared with susceptibility data for human Chlamydia isolates, the expected efficacy of the current chloramphenicol dosing regimen used in koalas to treat chlamydiosis remains uncertain and at odds with clinical observations.     

Population pharmacokinetics of rifampin in the treatment of Mycobacterium tuberculosis in Asian elephants

The objective of this study was to develop a population pharmacokinetic model for rifampin in elephants. Rifampin concentration data from three sources were pooled to provide a total of 233 oral concentrations from 37 Asian elephants. The population pharmacokinetic models were created using Monolix (version 4.2). Simulations were conducted using ModelRisk. We examined the influence of age, food, sex, and weight as model covariates. We further optimized the dosing of rifampin based upon simulations using the population pharmacokinetic model. Rifampin pharmacokinetics were best described by a one‐compartment open model including first‐order absorption with a lag time and first‐order elimination. Body weight was a significant covariate for volume of distribution, and food intake was a significant covariate for lag time. The median C_max of 6.07 μg/mL was below the target range of 8–24 μg/mL. Monte Carlo simulations predicted the highest treatable MIC of 0.25 μg/mL with the current initial dosing recommendation of 10 mg/kg, based upon a previously published target AUC_0–24/MIC > 271 (fAUC > 41). Simulations from the population model indicate that the current dose of 10 mg/kg may be adequate for MICs up to 0.25 μg/mL. While the targeted AUC/MIC may be adequate for most MICs, the median C_max for all elephants is below the human and elephant targeted ranges.     

Pharmacokinetics of tobramycin following intravenous,intramuscular, and intra‐articular administration in healthy horses

The objectives of this study were to examine the pharmacokinetics of tobramycin in the horse following intravenous (IV), intramuscular (IM), and intra‐articular (IA) administration. Six mares received 4 mg/kg tobramycin IV, IM, and IV with concurrent IA administration (IV+IA) in a randomized 3‐way crossover design. A washout period of at least 7 days was allotted between experiments. After IV administration, the volume of distribution, clearance, and half‐life were 0.18 ± 0.04 L/kg, 1.18 ± 0.32 mL·kg/min, and 4.61 ± 1.10 h, respectively. Concurrent IA administration could not be demonstrated to influence IV pharmacokinetics. The mean maximum plasma concentration (C_max) after IM administration was 18.24 ± 9.23 μg/mL at 1.0 h (range 1.0–2.0 h), with a mean bioavailability of 81.22 ± 44.05%. Intramuscular administration was well tolerated, despite the high volume of drug administered (50 mL per 500 kg horse). Trough concentrations at 24 h were below 2 μg/mL in all horses after all routes of administration. Specifically, trough concentrations at 24 h were 0.04 ± 0.01 μg/mL for the IV route, 0.04 ± 0.02 μg/mL for the IV/IA route, and 0.02 ± 0.02 for the IM route. An additional six mares received IA administration of 240 mg tobramycin. Synovial fluid concentrations were 3056.47 ± 1310.89 μg/mL at 30 min after administration, and they persisted for up to 48 h with concentrations of 14.80 ± 7.47 μg/mL. Tobramycin IA resulted in a mild chemical synovitis as evidenced by an increase in synovial fluid cell count and total protein, but appeared to be safe for administration. Monte Carlo simulations suggest that tobramycin would be effective against bacteria with a minimum inhibitory concentration (MIC) of 2 μg/mL for IV administration and 1 μg/mL for IM administration based on C_max:MIC of 10.     

Pharmacokinetic evaluation of oral dantrolene in the dog

The pharmacokinetics of dantrolene and its active metabolite, 5‐hydroxydantrolene, after a single oral dose of either 5 or 10 mg/kg of dantrolene was determined. The effects of exposure to dantrolene and 5‐hydroxydantrolene on activated whole‐blood gene expression of the cytokines interleukin‐2 (IL‐2) and interferon‐γ (IFN‐γ) were also investigated. When dantrolene was administered at a 5 mg/kg dose, peak plasma concentration (C_max) was 0.43 μg/mL, terminal half‐life (t_1/2) was 1.26 h, and area under the time–concentration curve (AUC) was 3.87 μg·h/mL. For the 10 mg/kg dose, C_max was 0.65 μg/mL, t_1/2 was 1.21 h, and AUC was 5.94 μg·h/mL. For all calculated parameters, however, there were large standard deviations and wide ranges noted between and within individual dogs: t_1/2, for example, ranged from 0.43 to 6.93 h, C_max ratios ranged from 1.05 to 3.39, and relative bioavailability (rF) values ranged from 0.02 to 1.56. While activated whole‐blood expression of IL‐2 and IFN‐γ as measured by qRT‐PCR was markedly suppressed following exposure to very high concentrations (30 and 50 μg/mL, respectively) of both dantrolene and 5‐hydroxydantrolene, biologically and therapeutically relevant suppression of cytokine expression did not occur at the much lower drug concentrations achieved with oral dantrolene dosing.     

Plasma concentrations of itraconazole following a single oral dose in juvenile California sea lions (Zalophus californianus)

The objective of this study was to establish a single-dose pharmacokinetic profile for orally administered itraconazole in California sea lions (Zalophus californianus). Twenty healthy rehabilitated juvenile California sea lions were included in this study. Itraconazole capsules were administered orally with food at a target dose of 5–10 mg/kg. Blood samples were collected from each animal at 0 hr and at two of the following timepoints: 0.5, 1, 2, 4, 6, 8, 12, 24, 48, and 72 hr. Quantitative analysis of itraconazole in plasma samples was performed by high-performance liquid chromatography. An average maximum concentration of 0.22 µg/ml ± 0.11 was detected 4 hr after administration. The average concentration fell to 0.12 µg/ml ± 0.11 by 6 hr and 0.02 µg/ml ± 0.02 at 12 hr. At no point did concentrations reach 0.5 µg/ml, the concentration commonly accepted for therapeutic efficacy. While this formulation was well tolerated by the sea lions, oral absorption was poor and highly variable among individuals. These data indicate that a single oral dose of itraconazole given as a capsule at 5–10 mg/kg, under the conditions used in this study, does not achieve therapeutic plasma concentrations in California sea lions.     

Ronidazole pharmacokinetics in cats following delivery of a delayed‐release guar gum formulation

Ronidazole (RDZ) is the only known effective treatment for feline diarrhea caused by Tritrichomonas foetus. This study aimed to develop guar gum‐coated colon‐targeted tablets of RDZ and to determine the pharmacokinetics of this delayed‐release formulation in cats. Guar gum‐coated tablets were administered orally once to five healthy cats (mean dose 32.3 mg/kg). The tablets were then administered once daily for 5 days to four cats (mean dose 34.5 mg/kg), and absorption studies repeated on day 5. Plasma was collected and analyzed for RDZ concentration, and pharmacokinetic noncompartmental and deconvolution analysis were performed on the data. There was negligible RDZ release until after 6 h, and a delayed peak plasma concentration (mean C_max 28.9 μg/mL) at approximately 14.5 h, which coincides with colonic arrival in cats. Maximum input rate (mg/kg per hour) occurred between 6 and 16 h. This delayed release of ronidazole from guar gum‐coated tablets indicates that release of RDZ may be delayed to deliver the medication to a targeted area of the intestine. Repeated dosing with guar gum tablets to steady‐state did not inhibit drug bioavailability or alter the pharmacokinetics. Such targeted RDZ drug delivery may provide improved efficacy and reduce adverse effects in cats.     

Pharmacokinetics of oral terbinafine in adult horses

The primary study objective was to compare the pharmacokinetics of p.o. terbinafine alone to p.o. terbinafine administered with p.o. cimetidine in healthy adult horses. The second objective was to assess the pharmacokinetics of terbinafine when administered per rectum in two different suspensions at 30 mg/kg to adult horses. Six healthy adult horses were included in this crossover study. Plasma terbinafine concentrations were quantified with liquid chromatography and mass spectrometry. The half‐life (geometric mean) was 8.38 and 10.76 h, for p.o. alone and p.o. with cimetidine, respectively. The mean maximum plasma concentrations were 0.291 μg/mL at 1.54 h and 0.418 μg/mL at 1.28 h for p.o. alone and p.o. with cimetidine, respectively. Terbinafine with cimetidine had an average C_MAX 44% higher and the relative F was 153% compared p.o. terbinafine alone, but was not statistically different (P > 0.05). Terbinafine was infrequently detected when administered per rectum in two different suspensions (water or olive oil). Minor adverse effects included oral irritation, fever, and colic. All resolved spontaneously. More pharmacokinetic studies are indicated assessing drug–drug interactions and using multiple dosing intervals to improve our knowledge of effective oral dosing, the potential for drug accumulation, and systemic adverse effect of terbinafine in horses.     

Pharmacokinetic/pharmacodynamic integration and modelling of oxytetracycline for the porcine pneumonia pathogens Actinobacillus pleuropneumoniae and Pasteurella multocida

Pharmacokinetic–pharmacodynamic (PK/PD) integration and modelling were used to predict dosage schedules of oxytetracycline for two pig pneumonia pathogens, Actinobacillus pleuropneumoniae and Pasteurella multocida. Minimum inhibitory concentration (MIC) and mutant prevention concentration (MPC) were determined in broth and porcine serum. PK/PD integration established ratios of average concentration over 48 h (C_av0–48 h)/MIC of 5.87 and 0.27 μg/mL (P. multocida) and 0.70 and 0.85 μg/mL (A. pleuropneumoniae) for broth and serum MICs, respectively. PK/PD modelling of in vitro time–kill curves established broth and serum breakpoint values for area under curve (AUC_0–24 h)/MIC for three levels of inhibition of growth, bacteriostasis and 3 and 4 log₁₀ reductions in bacterial count. Doses were then predicted for each pathogen, based on Monte Carlo simulations, for: (i) bacteriostatic and bactericidal levels of kill; (ii) 50% and 90% target attainment rates (TAR); and (iii) single dosing and daily dosing at steady‐state. For 90% TAR, predicted daily doses at steady‐state for bactericidal actions were 1123 mg/kg (P. multocida) and 43 mg/kg (A. pleuropneumoniae) based on serum MICs. Lower TARs were predicted from broth MIC data; corresponding dose estimates were 95 mg/kg (P. multocida) and 34 mg/kg (A. pleuropneumoniae).     

Pharmacokinetics of a single intramuscular injection of cefquinome in buffalo calves

The objective of this study was to investigate the pharmacokinetics of cefquinome following single intramuscular (IM) administration in six healthy male buffalo calves. Cefquinome was administered intramuscularly (2 mg/kg bodyweight) and blood samples were collected prior to drug administration and up to 24 hr after injection. No adverse effects or changes were observed after the IM injection of cefquinome. Plasma concentrations of cefquinome were determined by high‐performance liquid chromatography. The disposition of plasma cefquinome is characterized by a mono‐compartmental open model. The pharmacokinetic parameters after IM administration (mean ± SE) were C_max 6.93 ± 0.58 μg/ml, T_max 0.5 hr, t_½kα 0.16 ± 0.05 hr, t_½β 3.73 ± 0.10 hr, and AUC 28.40 ± 1.30 μg hr/ml after IM administration. A dosage regimen of 2 mg/kg bodyweight at 24‐hr interval following IM injection of cefquinome would maintain the plasma levels required to be effective against the bacterial pathogens with MIC values ≤0.39 μg/ml. The suggested dosage regimen of cefquinome has to be validated in the disease models before recommending for clinical use in buffalo calves.     

Disposition and clinical use of bromide in cats

OBJECTIVE: To establish a dosing regimen for potassium bromide and evaluate use of bromide to treat spontaneous seizures in cats. DESIGN: Prospective and retrospective studies. ANIMALS: 7 healthy adult male cats and records of 17 cats with seizures. PROCEDURE: Seven healthy cats were administered potassium bromide (15 mg/kg [6.8 mg/lb], p.o., q 12 h) until steady-state concentrations were reached. Serum samples for pharmacokinetic analysis were obtained weekly until bromide concentrations were not detectable. Clinical data were obtained from records of 17 treated cats. RESULTS: In the prospective study, maximum serum bromide concentration was 1.1 +/- 0.2 mg/mL at 8 weeks. Mean disappearance half-life was 1.6 +/- 0.2 weeks. Steady state was achieved at a mean of 5.3 +/-1.1 weeks. No adverse effects were detected and bromide was well tolerated. In the retrospective study, administration of bromide (n = 4) or bromide and phenobarbital (3) was associated with eradication of seizures in 7 of 15 cats (serum bromide concentration range, 1.0 to 1.6 mg/mL); however, bromide administration was associated with adverse effects in 8 of 16 cats. Coughing developed in 6 of these cats, leading to euthanasia in 1 cat and discontinuation of bromide administration in 2 cats. CONCLUSIONS AND CLINICAL RELEVANCE: Therapeutic concentrations of bromide are attained within 2 weeks in cats that receive 30 mg/kg/d (13.6 mg/lb/d) orally. Although somewhat effective in seizure control, the incidence of adverse effects may not warrant routine use of bromide for control of seizures in cats.     

Pharmacokinetic and pharmacodynamic integration and modeling of acetylkitasamycin in swine for Clostridium perfringens

The aim of this study was to establish an integrated pharmacokinetic/pharmacodynamic (PK/PD) modeling approach of acetylkitasamycin for designing dosage regimens and decreasing the emergence of drug‐resistant bacteria. After oral administration of acetylkitasamycin to healthy and infected pigs at the dose of 50 mg/kg body weights (bw), a rapid and sensitive LC–MS/MS method was developed and validated for determining the concentration change of the major components of acetylkitasamycin and its possible metabolite kitasamycin in the intestinal samples taken from the T‐shape ileal cannula. The PK parameters, including the integrated peak concentration (C_max), the time when the maximum concentration reached (T_max) and the area under the concentration–time curve (AUC), were calculated by WinNonlin software. The minimum inhibitory concentration (MIC) of 60 C. perfringens strains was determined following CLSI guideline. The in vitro and ex vivo activities of acetylkitasamycin in intestinal tract against a pathogenic strain of C. perfringens type A (CPFK122995) were established by the killing curve. Our PK data showed that the integrated C_max, T_max, and AUC were 14.57–15.81 μg/ml, 0.78–2.52 hR, and 123.84–152.32 μg hr/ml, respectively. The PD data show that MIC₅₀ and MIC₉₀ of the 60 C. perfringens isolates were 3.85 and 26.45 μg/ml, respectively. The ex vivo growth inhibition data were fitted to the inhibitory sigmoid E_max equation to provide the values of AUC/MIC to produce bacteriostasis (4.84 hr), bactericidal activity (15.46 hr), and bacterial eradication (24.99 hr). A dosage regimen of 18.63 mg/kg bw every 12 hr could be sufficient in the prevention of C. perfringens infection. The therapeutic dosage regimen for C. perfringens infection was at the dose of 51.36 mg/kg bw every 12 hr for 3 days. In summary, the dosage regimen for the treatment of C. perfringens in pigs administered with acetylkitasamycin was designed using PK/PD integrate model. The designed dose regimen could to some extent decrease the risk for emergence of macrolide resistance.     

Effect of sucralfate on oral minocycline absorption in healthy dogs

Sucralfate and minocycline may be administered concurrently to dogs. The relative bioavailability of tetracyclines may be reduced if administered with sucralfate, but studies confirming these interactions in dogs are not available. This study evaluated the pharmacokinetics of oral minocycline in dogs (M), determined the effects of concurrent administration of sucralfate and minocycline (MS) on minocycline pharmacokinetics, determined the effects of delaying sucralfate administration by 2 h (MS+2) on minocycline pharmacokinetics, and established dosing recommendations based on pharmacodynamic indices. Oral minocycline (300 mg) and sucralfate suspension (1 g) were administered to five greyhounds in a randomized crossover design. Minocycline plasma concentrations were evaluated using liquid chromatography with mass spectrometry. The maximum plasma concentration (C_MAX) and area under the curve (AUC) of minocycline were 1.15 μg/mL and 8.0 h* μg/mL, respectively. The C_MAX and AUC were significantly lower (P < 0.05) in the MS group (C_MAX = 0.33 μg/mL, AUC 3.0 h*μg/mL) compared with M or MS+2 (C_MAX = 0.97 μg/mL, AUC 10.3 h*μg/mL). Delaying sucralfate by 2 h did not decrease oral minocycline absorption, but concurrent administration significantly decreased minocycline absorption. A dose of 7.5 mg/kg p.o. q12 h achieves the pharmacodynamic index for a bacterial minimum inhibitory concentration (MIC) of 0.25 μg/mL (AUC:MIC≥33.9).     

The pharmacokinetics of pimobendan enantiomers after oral and intravenous administration of racemate pimobendan formulations in healthy dogs

Pimobendan is a benzimidazole‐pyridazinone derivative, marketed as a racemic mixture for the management of canine heart failure. Pharmacokinetics of the enantiomers of pimobendan and its oral bioavailability have not been described in dogs. The aim of this study was to describe pharmacokinetics of three formulations of pimobendan in healthy dogs: the licensed capsule product, and novel liquid and intravenous formulations. A three‐period, nested randomized two‐treatment crossover design was used. Pimobendan was administered p.o. at 0.25 and i.v. at 0.125 mg/kg. Blood and plasma samples were analysed by liquid chromatography–mass spectrometry. Noncompartmental modelling was used to describe the pharmacokinetics. Parameters were compared between formulations using a general linear model. Bioequivalence of the oral formulations was tested using CI90 for AUC_(0–∞) and C_max. Bioavailability of pimobendan after oral dosing was 70%. Liquid and capsule formulations were bioequivalent only for AUC. The positive enantiomer of pimobendan (PE) had a larger volume of distribution than the negative enantiomer (NE) (281 ± 48 vs. 215 ± 68 mL/kg; P = 0.003) and a shorter half‐life (21.7 vs. 29.9 min; P = 0.004). The NE was distributed more quickly than the PE into blood cells. Enantiomers of pimobendan have differing absorption, distribution and elimination. The pharmacokinetics of pimobendan in healthy dogs was described.     

Pharmacokinetics of ganciclovir and valganciclovir in the adult horse

Equine herpes myeloencephalopathy, resulting from equine herpes virus type 1 (EHV‐1) infection, is associated with substantial morbidity and mortality in the horse. As compared to other antiviral drugs, such as acyclovir, ganciclovir has enhanced potency against EHV‐1. This study investigated the pharmacokinetics of ganciclovir and its oral prodrug, valganciclovir, in six adult horses in a randomized cross‐over design. Ganciclovir sodium was administered intravenously as a slow bolus at a dose of 2.5 mg/kg, and valganciclovir was administered orally at a dose of 1800 mg per horse. Intravenously administered ganciclovir disposition was best described by a three‐compartment model with a prolonged terminal half‐life of 72 ± 9 h. Following the oral administration of valganciclovir, the mean observed maximum serum ganciclovir concentration was 0.58 ± 0.37 μg/mL, and bioavailability of ganciclovir from oral valganciclovir was 41 ± 20%. Superposition predicted that oral dosing of 1800‐mg valganciclovir two times daily would fail to produce and maintain effective plasma concentrations of ganciclovir. However, superposition suggested that i.v. administration of ganciclovir at 2.5 mg/kg every 8 h for 24 h followed by maintenance dosing of 2.5 mg/kg every 12 h would maintain effective ganciclovir serum concentrations in most horses throughout the dosing interval.