The pharmacokinetics of mavacoxib,a long‐acting COX‐2 inhibitor,in young adult laboratory dogs

Cox, S.R., Lesman, S.P., Boucher, J.F., Krautmann, M.J., Hummel, B.D., Savides, M., Marsh, S., Fielder, A., Stegemann, M.R. The pharmacokinetics of mavacoxib, a long‐acting COX‐2 inhibitor, in young adult laboratory dogs. J. vet. Pharmacol. Therap. 33 , 461–470. The pharmacokinetics of mavacoxib were evaluated in an absolute bioavailability study, a dose‐proportionality study and a multi‐dose study in young healthy adult laboratory Beagle dogs and in a multi‐dose safety study in Beagle‐sized laboratory Mongrel dogs. When administered as the commercial tablet formulation at 4 mg/kg body weight (bw) to fasted dogs, the absolute bioavailability (F) of mavacoxib was 46.1%; F increased to 87.4% when mavacoxib was administered with food. Following intravenous administration, the total body plasma clearance of mavacoxib was 2.7 mL·h/kg, and the apparent volume of distribution at steady‐state was 1.6 L/kg. The plasma protein binding of mavacoxib was approximately 98% in various in vitro and ex vivo studies. The dose‐normalized area under the plasma concentration–time curve was similar in Beagle and Beagle‐sized Mongrel dogs when mavacoxib was administered with food. Mavacoxib exhibited dose‐proportional pharmacokinetics for single oral doses of 2–12 mg/kg in Beagle dogs and for multiple oral doses of 5–25 mg/kg in Beagle‐sized Mongrel dogs. Only minor accumulation occurred when mavacoxib was administered at doses of 2–25 mg/kg bw orally to laboratory dogs with a 2‐week interval between the 1st two doses but with a monthly interval thereafter. Across all three Beagle studies (n = 63) the median terminal elimination half‐life (t_½) was 16.6 days, with individual values ranging 7.9–38.8 days. The prolonged t_½ for mavacoxib supports the approved regimen in which doses are separated by 2–4 weeks.     

Pharmacokinetics of oral rufinamide in dogs

Wright, H. M., Chen, A. V., Martinez, S. E., Davies, N. M. Pharmacokinetics of oral rufinamide in dogs. J. vet. Pharmacol. Therap.  35 , 529–533. The objective of this study was to determine the pharmacokinetic properties and short‐term adverse effect profile of single‐dose oral rufinamide in healthy dogs. Six healthy adult dogs were included in the study. The pharmacokinetics of rufinamide were calculated following administration of a single mean oral dose of 20.0 mg/kg (range 18.6–20.8 mg/kg). Plasma rufinamide concentrations were determined using high‐performance liquid chromatography, and pharmacokinetic data were analyzed using commercial software. No adverse effects were observed. The mean terminal half‐life was 9.86 ± 4.77 h. The mean maximum plasma concentration was 19.6 ± 5.8 μg/mL, and the mean time to maximum plasma concentration was 9.33 ± 4.68 h. Mean clearance was 1.45 ± 0.70 L/h. The area under the curve (to infinity) was 411 ± 176 μg·h/mL. Results of this study suggest that rufinamide given orally at 20 mg/kg every 12 h in healthy dogs should result in a plasma concentration and half‐life sufficient to achieve the therapeutic level extrapolated from humans without short‐term adverse effects. Further investigation into the efficacy and long‐term safety of rufinamide in the treatment of canine epilepsy is warranted.     

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.     

Pharmacokinetic properties of toceranib phosphate (Palladia™, SU11654), a novel tyrosine kinase inhibitor,in laboratory dogs and dogs with mast cell tumors

Yancey, M. F., Merritt, D. A., Lesman, S. P., Boucher, J. F., Michels, G. M. Pharmacokinetic properties of toceranib phosphate (Palladia?, SU11654), a novel tyrosine kinase inhibitor, in laboratory dogs and dogs with mast cell tumors. J. vet. Pharmacol. Therap. 33 , 162–171. Toceranib phosphate (Palladia?, SU11654), an oral tyrosine‐kinase inhibitor, is under investigation for the treatment of mast cell tumors in dogs. The pharmacokinetics of toceranib phosphate has been characterized in dogs. Means of the following pharmacokinetic parameters were estimated following a 1.0 mg/kg i.v. dose to laboratory beagles: plasma clearance of 1.45 L/kg/h, volume of distribution of 29.7 L/kg, and terminal half‐life of 17.7 h. Following single oral doses of 3.25 mg/kg administered to laboratory beagles, mean C_max estimates ranged from 68.6 ng/mL to 112 ng/mL with t_max ranging from 5.3 h and 9.3 h postdose. Terminal half‐life was estimated at 31 h. Oral bioavailability was 76.9%. There were no statistically significant (P > 0.05) differences with any pharmacokinetic parameter due to fed/fasted state or with time during 13 weeks of every‐other‐day dosing at 3.25 mg/kg. Toceranib concentrations were proportional with dose over the range of 2.0 to 6.0 mg/kg. The pharmacokinetics of toceranib in client‐owned dogs of a variety of pure and mixed breeds with mast cell tumors was similar to that in healthy laboratory dogs. In summary, toceranib phosphate exhibited moderate clearance, a high volume of distribution, and a moderate elimination half‐life. After a single oral dose at 3.25 mg/kg, the concentration vs. time curve showed broad, sustained exposure with measurable concentrations for more than 48 h. These pharmacokinetic parameters support every‐other‐day administration of toceranib phosphate at an initial dose of 3.25 mg/kg for the treatment of mast cell tumors in dogs.     

Pharmacokinetics of cefpodoxime in plasma and subcutaneous fluid following oral administration of cefpodoxime proxetil in male beagle dogs

Kumar, V., Madabushi, R., Lucchesi, M. B. B., Derendorf, H. Pharmacokinetics of cefpodoxime in plasma and subcutaneous fluid following oral administration of cefpodoxime proxetil in male beagle dogs. J. vet. Pharmacol. Therap. 34 , 130–135. Pharmacokinetics of cefpodoxime in plasma (total concentration) and subcutaneous fluid (free concentration using microdialysis) was investigated in dogs following single oral administration of prodrug cefpodoxime proxetil (equivalent to 5 and 10 mg/kg of cefpodoxime). In a cross over study design, six dogs per dose were utilized after a 1 week washout period. Plasma, microdialysate, and urine samples were collected upto 24 h and analyzed using high performance liquid chromatography. The average maximum concentration (C_max) of cefpodoxime in plasma was 13.66 (±6.30) and 27.14 (±4.56) μg/mL with elimination half‐life (t_1/2) of 3.01 (±0.49) and 4.72 (±1.46) h following 5 and 10 mg/kg dose, respectively. The respective average area under the curve (AUC_0–∞) was 82.94 (±30.17) and 107.71 (±30.79) μg·h/mL. Cefpodoxime was readily distributed to skin and average free C_max in subcutaneous fluid was 1.70 (±0.55) and 3.06 (±0.93) μg/mL at the two doses. Urinary excretion (unchanged cefpodoxime) was the major elimination route. Comparison of subcutaneous fluid concentrations using pharmacokinetic/pharmacodynamic indices of fT_>MIC indicated that at 10 mg/kg dose; cefpodoxime would yield good therapeutic outcome in skin infections for bacteria with MIC₅₀ upto 0.5 μg/mL while higher doses (or more frequent dosing) may be needed for bacteria with higher MICs. High urine concentrations suggested cefpodoxime use for urinary infections in dogs.     

Pharmacokinetics of acetaminophen, codeine, and the codeine metabolites morphine and codeine-6-glucuronide in healthy Greyhound dogs

KuKanich, B. Pharmacokinetics of acetaminophen, codeine, and the codeine metabolites morphine and codeine‐6‐glucuronide in healthy Greyhound dogs. J. vet. Pharmacol. Therap. 33 , 15–21. The purpose of this study was to determine the pharmacokinetics of codeine and the active metabolites morphine and codeine‐6‐glucuronide after i.v. codeine administration and the pharmacokinetics of acetaminophen (APAP), codeine, morphine, and codeine‐6‐glucuronide after oral administration of combination product containing acetaminophen and codeine to dogs. Six healthy Greyhound dogs were administered 0.734 mg/kg codeine i.v. and acetaminophen (10.46 mg/kg mean dose) with codeine (1.43 mg/kg mean dose) orally. Blood samples were collected at predetermined time points for the determination of codeine, morphine, and codeine‐6‐glucuronide plasma concentrations by LC/MS and acetaminophen by HPLC with UV detection. Codeine was rapidly eliminated after i.v. administration (T½ = 1.22 h; clearance = 29.94 mL/min/kg; volume of distribution = 3.17 L/kg) with negligible amounts of morphine present, but large amounts of codeine‐6‐glucuronide (C_max = 735.75 ng/mL) were detected. The oral bioavailability of codeine was 4%, morphine concentrations were negligible, but large amounts of codeine‐6‐glucuronide (C_max = 1952.86 ng/mL) were detected suggesting substantial first pass metabolism. Acetaminophen was rapidly absorbed (C_max = 6.74 μg/mL; T_max = 0.85 h) and eliminated (T½ = 0.96 h). In conclusion, the pharmacokinetics of codeine was similar to other opioids in dogs with a short half‐life, rapid clearance, large volume of distribution, and poor oral bioavailability. High concentrations of codeine‐6‐glucuronide were detected after i.v. and oral administration.     

Pharmacokinetics of meloxicam in adult goats and its analgesic effect in disbudded kids

Ingvast‐Larsson, C., Högberg, M., Mengistu, U., Olsén, L., Bondesson, U., Olsson, K. Pharmacokinetics of meloxicam in adult goats and its analgesic effect in disbudded kids. J. vet. Pharmacol. Therap. 34 , 64–69. The pharmacokinetics and analgesic effect of the nonsteroidal anti‐inflammatory drug meloxicam (0.5 mg/kg) in goats were investigated. In a randomized, cross‐over design the pharmacokinetic parameters were investigated in adult goats (n = 8) after single intravenous and oral administration. The analgesic effect was evaluated in kids using a randomized, placebo controlled and blinded protocol. Kids received meloxicam (n = 6) once daily and their siblings (n = 5) got isotonic NaCl intramuscularly while still anaesthetized after cautery disbudding and injections were repeated on three consecutive days. In the adult goats after intravenous administration the terminal half‐life was 10.9 ± 1.7 h, steady‐state volume of distribution was 0.245 ± 0.06 L/kg, and total body clearance was 17.9 ± 4.3 mL/h/kg. After oral administration bioavailability was 79 ± 19%, C_max was 736 ± 184 ng/mL, T_max was 15 ±5 h, although the terminal half‐life was similar to the intravenous value, 11.8 ± 1.7 h. Signs of pain using a visual analogue scale were smaller in kids treated with meloxicam compared with kids treated with placebo on the first day after disbudding, but subsequently no difference in pain was noticeable. Plasma cortisol and glucose concentrations did not differ between the two groups.     

Pharmacokinetics of amantadine in cats

Siao, K. T., Pypendop, B. H., Stanley, S. D., Ilkiw, J. E. Pharmacokinetics of amantadine in cats. J. vet. Pharmacol. Therap. 34 , 599–604. This study reports the pharmacokinetics of amantadine in cats, after both i.v. and oral administration. Six healthy adult domestic shorthair female cats were used. Amantadine HCl (5 mg/kg, equivalent to 4 mg/kg amantadine base) was administered either intravenously or orally in a crossover randomized design. Blood samples were collected immediately prior to amantadine administration, and at various times up to 1440 min following intravenous, or up to 2880 min following oral administration. Plasma amantadine concentrations were determined by liquid chromatography–mass spectrometry, and plasma amantadine concentration–time data were fitted to compartmental models. A two‐compartment model with elimination from the central compartment best described the disposition of amantadine administered intravenously in cats, and a one‐compartment model best described the disposition of oral amantadine in cats. After i.v. administration, the apparent volume of distribution of the central compartment and apparent volume of distribution at steady‐state [mean ± SEM (range)], and the clearance and terminal half‐life [harmonic mean ± jackknife pseudo‐SD (range)] were 1.5 ± 0.3 (0.7–2.5) L/kg, 4.3 ± 0.2 (3.7–5.0) L/kg, 8.2 ± 2.1 (5.9–11.4) mL·min/kg, and 348 ± 49 (307–465) min, respectively. Systemic availability [mean ± SEM (range)] and terminal half‐life after oral administration [harmonic mean ± jackknife pseudo‐SD (range)] were 130 ± 11 (86–160)% and 324 ± 41 (277–381) min, respectively.     

Effects of urine pH modification on pharmacokinetics of phenobarbital in healthy dogs

Although pH modification is one of the effective strategies for dissolving or preventing uroliths, little is known about its effects on the pharmacokinetics of phenobarbital in dogs. Five spayed, female Beagles were fed with a twice‐daily diet that included potassium citrate and ammonium chloride for urine alkalinization and acidification, respectively. After a stabilizing period of 7 days, a single clinical dose of phenobarbital (3 mg/kg) was orally administered, and time‐course changes in its serum and urine concentrations were determined by high‐performance liquid chromatography. Total amounts of unchanged phenobarbital excreted into urine for 216 h were decreased by urine acidification and increased by urine alkalinization. The elimination half‐life of serum phenobarbital in dogs with urine alkalinization was shortened and Cl_R increased when compared with dogs with urine acidification. Other pharmacokinetic parameters, including C_max, T_max, AUC_0–216, Cl/F, and A_e0–216 were not changed by modification of the urine pH. These results suggest that the pH of urine is likely to be a determinant of the pharmacokinetics, especially urine excretion rate, of a clinical dose of oral phenobarbital. It is possible that the serum concentration of phenobarbital might be altered when a pH modifying‐diet is administered for the purpose of dissolving or preventing uroliths.     

Investigation of pharmacokinetic interaction between ivermectin and praziquantel after oral administration in healthy dogs

The purpose of this study was to determine the pharmacokinetic interaction between ivermectin (0.4 mg/kg) and praziquantel (10 mg/kg) administered either alone or co‐administered to dogs after oral treatment. Twelve healthy cross‐bred dogs (weighing 18–21 kg, aged 1–3 years) were allocated randomly into two groups of six dogs (four females, two males) each. In first group, the tablet forms of praziquantel and ivermectin were administered using a crossover design with a 15‐day washout period, respectively. Second group received tablet form of ivermectin plus praziquantel. The plasma concentrations of ivermectin and praziquantel were determined by high‐performance liquid chromatography using a fluorescence and ultraviolet detector, respectively. The pharmacokinetic parameters of ivermectin following oral alone‐administration were as follows: elimination half‐life (t_1/2λz) 110 ± 11.06 hr, area under the plasma concentration–time curve (AUC_0–∞) 7,805 ± 1,768 hr^.ng/ml, maximum concentration (C_max) 137 ± 48.09 ng/ml, and time to reach C_max (T_max) 14.0 ± 4.90 hr. The pharmacokinetic parameters of praziquantel following oral alone‐administration were as follows: t_1/2λz 7.39 ± 3.86 hr, AUC_0–∞ 4,301 ± 1,253 hr^.ng/ml, C_max 897 ± 245 ng/ml, and T_max 5.33 ± 0.82 hr. The pharmacokinetics of ivermectin and praziquantel were not changed, except T_max of praziquantel in the combined group. In conclusion, the combined formulation of ivermectin and praziquantel can be preferred in the treatment and prevention of diseases caused by susceptible parasites in dogs because no pharmacokinetic interaction was determined between them.     

The pharmacokinetics and in vitro cyclooxygenase selectivity of deracoxib in horses

Davis, J. L., Marshall, J. F., Papich, M. G., Blikslager, A. T., Campbell, N. B. The pharmacokinetics and in vitro cyclooxygenase selectivity of deracoxib in horses. J. vet. Pharmacol. Therap. 34 , 12–16. The purpose of this study was to determine the pharmacokinetics of deracoxib following oral administration to horses. In addition, in vitro equine whole blood cyclooxygenase (COX) selectivity assays were performed. Six healthy adult horses were administered deracoxib (2 mg/kg) orally. Plasma samples were collected prior to drug administration (time 0), and 10, 20, 40 min and 1, 1.5, 2, 4, 6, 8, 12, 24, and 48 h after administration for analysis with high pressure liquid chromatography using ultraviolet detection. Following PO administration, deracoxib had a long elimination half‐life (t_1/2k₁₀) of 12.49 ± 1.84 h. The average maximum plasma concentration (C_max) was 0.54 μg/mL, and was reached at 6.33 ± 3.44 h. Bioavailability was not determined because of the lack of an IV formulation. Results of in vitro COX selectivity assays showed that deracoxib was selective for COX‐2 with a COX‐1/COX‐2 ratio of 25.67 and 22.06 for the IC₅₀ and IC₈₀, respectively. Dosing simulations showed that concentrations above the IC₈₀ for COX‐2 would be maintained following 2 mg/kg PO q12h, and above the IC₅₀ following 2 mg/kg PO q24h. This study showed that deracoxib is absorbed in the horse after oral administration, and may offer a useful alternative for anti‐inflammatory treatment of various conditions in the horse.     

Pharmacokinetics and bioavailability of valnemulin in broiler chickens

Wang, R., Yuan, L.G., He, L.M., Zhu, L.X., Luo, X.Y., Zhang, C.Y., Yu, J.J., Fang, B.H., Liu, Y.H. Pharmacokinetics and bioavailability of valnemulin in broiler chickens. J. vet. Pharmacol. Therap. 34 , 247–251. The objective of this study was to investigate the pharmacokinetics and bioavailability of valnemulin in broiler chickens after intravenous (i.v.), intramuscular (i.m.) and oral administrations of 10 mg/kg body weight (bw). Plasma samples were analyzed by high‐performance liquid chromatography–tandem mass spectrometry (HPLC‐MS/MS). Pharmacokinetic characterization was performed by non‐compartmental analysis using WinNonlin program. After intravenous administration, distribution was wide with the volume of distribution based on terminal phase(V_z) of 4.27 ± 0.99 L /kg. Mean valnemulin t_1/2β(h), Cl_β(L /h /kg), V_ss (L /kg) and AUC_(0–∞)(μg·h /mL) values were 2.85, 0.99, 2.72 and 10.34, respectively. After intramuscular administration, valnemulin was rapidly absorbed with a C_max of 2.2 μg/mL achieved at 0.43 h (t_max), and the absolute bioavailability (F) was 88.81%; and for the oral route the same parameters were 0.66 ± 0.15 μg/mL, 1.54 ± 0.27 h and 74.42%. A multiple‐peak phenomenon was present after oral administration. The plasma profile of valnemulin exhibited a secondary peak during 2–6 h and a tertiary peak at 32 h. The favorable PK behavior, such as the wide distribution, slow elimination and acceptable bioavailability indicated that it is likely to be effective in chickens.     

Pharmacokinetics of cyclophosphamide after oral and intravenous administration to dogs with lymphoma

Background: Cyclophosphamide is an alkylating chemotherapeutic drug administered IV or PO. It is currently assumed that exposure to the active metabolite, 4‐hydroxycyclophosphamide (4‐OHCP), is the same with either route of administration.

Objectives:

To characterize the pharmacokinetics of cyclophosphamide and 4‐OHCP in dogs with lymphoma when administered PO or IV. Animals: Sixteen client‐owned dogs with substage A lymphoma were enrolled in the study. Eight dogs received cyclophosphamide IV and 8 received it PO. Methods: Prospective randomized clinical trial was performed. Blood was collected from each dog at specific time points after administration of cyclophosphamide. The serum was evaluated for the concentration of cyclophosphamide and 4‐OHCP with mass spectrometry and liquid chromatography. Results: Drug exposure to cyclophosphamide measured by area under the curve (AUC)_0–inf is significantly higher after intravenous administration (7.14 ± 3.77 μg/h/mL) compared with exposure after oral administration (P‐value < .05). No difference in drug exposure to 4‐OHCP was detected after IV (1.66 ± 0.36 μg/h/mL) or PO (1.42 ± 0.64 μg/h/mL) administered cyclophosphamide. Conclusions and Clinical Importance: Drug exposure to the active metabolite 4‐OHCP is equivalent after administration of cyclophosphamide either PO or IV.     

Florfenicol pharmacokinetics in healthy adult alpacas after subcutaneous and intramuscular injection

Holmes, K., Bedenice, D., Papich, M. G. Florfenicol pharmacokinetics in healthy adult alpacas after subcutaneous and intramuscular injection. J. vet. Pharmacol. Therap.  35 , 382–388. A single dose of florfenicol (Nuflor^®) was administered to eight healthy adult alpacas at 20 mg/kg intramuscular (i.m.) and 40 mg/kg subcutaneous (s.c.) using a randomized, cross‐over design, and 28‐day washout period. Subsequently, 40 mg/kg florfenicol was injected s.c. every other day for 10 doses to evaluate long‐term effects. Maximum plasma florfenicol concentrations (C_max, measured via high‐performance liquid chromatography) were achieved rapidly, leading to a higher C_max of 4.31 ± 3.03 μg/mL following administration of 20 mg/kg i.m. than 40 mg/kg s.c. (C_max: 1.95 ± 0.94 μg/mL). Multiple s.c. dosing at 48 h intervals achieved a C_max of 4.48 ± 1.28 μg/mL at steady state. The area under the curve and terminal elimination half‐lives were 51.83 ± 11.72 μg/mL·h and 17.59 ± 11.69 h after single 20 mg/kg i.m. dose, as well as 99.78 ± 23.58 μg/mL·h and 99.67 ± 59.89 h following 40 mg/kg injection of florfenicol s.c., respectively. Florfenicol decreased the following hematological parameters after repeated administration between weeks 0 and 3: total protein (6.38 vs. 5.61 g/dL, P < 0.0001), globulin (2.76 vs. 2.16 g/dL, P < 0.0003), albumin (3.61 vs. 3.48 g/dL, P = 0.0038), white blood cell count (11.89 vs. 9.66 × 10³/μL, P < 0.044), and hematocrit (27.25 vs. 24.88%, P < 0.0349). Significant clinical illness was observed in one alpaca. The lowest effective dose of florfenicol should thus be used in alpacas and limited to treatment of highly susceptible pathogens.     

Pharmacokinetics of pioglitazone in lean and obese cats(1)

Clark, M. H., Hoenig, M., Ferguson, D. C., Dirikolu, L. Pharmacokinetics of pioglitazone in lean and obese cats. J. vet. Pharmacol. Therap.  35 , 428–436. Pioglitazone is a thiazolidinedione insulin sensitizer that has shown efficacy in Type 2 diabetes and nonalcoholic fatty liver disease in humans. It may be useful for treatment of similar conditions in cats. The purpose of this study was to investigate the pharmacokinetics of pioglitazone in lean and obese cats, to provide a foundation for assessment of its effects on insulin sensitivity and lipid metabolism. Pioglitazone was administered intravenously (median 0.2 mg/kg) or orally (3 mg/kg) to 6 healthy lean (3.96 ± 0.56 kg) and 6 obese (6.43 ± 0.48 kg) cats, in a two by two Latin Square design with a 4‐week washout period. Blood samples were collected over 24 h, and pioglitazone concentrations were measured via a validated high‐performance liquid chromatography assay. Pharmacokinetic parameters were determined using two‐compartmental analysis for IV data and noncompartmental analysis for oral data. After oral administration, mean bioavailability was 55%, t_1/2 was 3.5 h, T_max was 3.6 h, C_max was 2131 ng/mL, and AUC_0–∞ was 15 556 ng/mL·h. There were no statistically significant differences in pharmacokinetic parameters between lean and obese cats following either oral or intravenous administration. Systemic exposure to pioglitazone in cats after a 3 mg/kg oral dose approximates that observed in humans with therapeutic doses.     

Pharmacokinetics of a controlled‐release liposome‐encapsulated hydromorphone administered to healthy dogs

The purpose of the study was to assess the pharmacokinetics of liposome‐encapsulated (DPPC‐C) hydromorphone administered intravenously (IV) or subcutaneously (SC) to dogs. A total of eight healthy Beagles aged 12.13 ± 1.2 months and weighing 11.72 ± 1.10 kg were used. Dogs randomly received liposome encapsulated hydromorphone, 0.5 mg/kg IV (n = 6), 1.0 mg/kg (n = 6), 2.0 mg/kg (n = 6), or 3.0 mg/kg (n = 7) SC with a 14–28 day washout between trials. Blood was sampled at serial intervals after drug administration. Serum hydromorphone concentrations were measured using liquid chromatography with mass spectrometry. Serum concentrations of hydromorphone decreased rapidly after IV administration of the DPPC‐C formulation (half‐life = 0.52 h, volume of distribution = 12.47 L/kg, serum clearance = 128.97 mL/min/kg). The half‐life of hydromorphone after SC administration of DPPC‐C formulation at 1.0, 2.0, and 3.0 mg/kg was 5.22, 31.48, and 24.05 h, respectively. The maximum serum concentration normalized for dose (C_MAX/D) ranged between 19.41–24.96 ng/mL occurring at 0.18–0.27 h. Serum hydromorphone concentrations fluctuated around 4.0 ng/mL from 6–72 h after 2.0 mg/kg and mean concentrations remained above 4 ng/mL for 96 h after 3.0 mg/kg DPPC‐C hydromorphone. Liposome‐encapsulated hydromorphone (DPPC‐C) administered SC to healthy dogs provided a sustained duration of serum hydromorphone concentrations.     

The pharmacokinetics of nitazoxanide active metabolite (tizoxanide) in goats and its protein binding ability in vitro

Zhao, Z., Xue, F., Zhang, L., Zhang, K., Fei, C., Zheng, W., Wang, X., Wang, M., Zhao, Z., Meng, X. The pharmacokinetics of nitazoxanide active metabolite (tizoxanide) in goats and its protein binding ability in vitro. J. vet. Pharmacol. Therap. 33 , 147–153. The pharmacokinetics of tizoxanide (T), the active metabolite of nitazoxanide (NTZ), and its protein binding ability in goat plasma and in the solutions of albumin and α‐1‐acid‐glycoprotein were investigated. The plasma and protein binding samples were analyzed using a high‐performance liquid chromatography (HPLC) assay with UV detection at 360 nm. The plasma concentration of T was detectable in goats up to 24 h. Plasma concentrations vs. time data of T after 200 mg/kg oral administration of NTZ in goats were adequately described by one‐compartment open model with first order absorption. As to free T, the values of t_1/2Ka, t_1/2Ke, T_max, C_max, AUC, V/F_(c), and Cl_(s) were 2.51 ± 0.41 h, 3.47 ± 0.32 h, 4.90 ± 0.13 h, 2.56 ± 0.25 μg/mL, 27.40 ± 1.54 (μg/mL) × h, 30.17 ± 2.17 L/kg, and 7.34 ± 1.21 L/(kg × h), respectively. After β‐glucuronidase hydrolysis to obtain total T, t_1/2ke, C_max, T_max, AUC increased, while the V/F_(c) and Cl_(s) decreased. Study of the protein binding ability showed that T with 4 μg/mL concentration in goat plasma and in the albumin solution achieved a protein binding percentage of more than 95%, while in the solution of α‐1‐acid‐glycoprotein, the percentage was only about 49%. This result suggested that T might have much more potent binding ability with albumin than with α‐1‐acid‐glycoprotein, resulting from its acidic property.     

Pharmacokinetics and toxicity of ciprofloxacin in adult horses

Yamarik, T. A., Wilson, W. D., Wiebe, V. J., Pusterla, N., Edman, J., Papich, M. G. Pharmacokinetics and toxicity of ciprofloxacin in adult horses. J. vet. Pharmacol. Therap. 33 , 587–594. Using a randomized, cross‐over study design, ciprofloxacin was administered i.g. to eight adult mares at a dose of 20 mg/kg, and to seven of the eight horses at a dose of 5 mg/kg by bolus i.v. injection. The mean C₀ was 20.5 μg/mL (±8.8) immediately after i.v. administration. The C_max was 0.6 μg/mL (±0.36) at T_max 1.46 (±0.66) h after the administration of oral ciprofloxacin. The mean elimination half‐life after i.v. administration was 5.8 (±1.6) h, and after oral administration the terminal half‐life was 3.6 (±1.7) h. The overall mean systemic availability of the oral dose was 10.5 (±2.8)%. Transient adverse effects of mild to moderate severity included agitation, excitement and muscle fasciculation, followed by lethargy, cutaneous edema and loss of appetite developed in all seven horses after i.v. administration. All seven horses developed mild transient diarrhea at 36–48 after i.v. dosing. All eight horses dosed intragastrically experienced adverse events attributable to ciprofloxacin administration. Adverse events included mild transient diarrhea to severe colitis, endotoxemia and laminitis necessitating euthanasia of three horses on humane grounds. The high incidences of adverse events preclude oral and rapid i.v. push administration of ciprofloxacin.     

The Effect of Angiotensin‐Converting Enzyme Inhibitors of Left Atrial Pressure in Dogs with Mitral Valve Regurgitation

Background: Despite many epidemiological reports concerning the efficacy of angiotensin‐converting enzyme (ACE) inhibitors in dogs with mitral regurgitation (MR), the hemodynamic effects of ACE inhibitor administration have not been fully evaluated. Objectives: To document left atrial pressure (LAP) in dogs with MR administered ACE inhibitors, in order to obtain interesting information about daily LAP changes with administration of ACE inhibitors. Animals: Five healthy Beagle dogs weighing 9.8 to 14.2 kg (2 males and 3 females; aged 2 years). Methods: Experimental, crossover, and interventional study. Chordae tendineae rupture was induced, and a radiotelemetry transmitter catheter was inserted into the left atrium. LAP was recorded for 72 consecutive hours during which each of 3 ACE inhibitors—enalapril (0.5 mg/kg/d), temocapril (0.1 mg/kg/d), and alacepril (3.0 mg/kg/d)—were administered in a crossover study. Results: Averaged diurnal LAP was significantly, but slightly reduced by alacepril (P= .03, 19.03 ± 3.01–18.24 ± 3.07 mmHg). The nightly drops in LAP caused by alacepril and enalapril were significantly higher than the daily drops (P= .03, ?0.98 ± 0.19 to ?0.07 ± 0.25 mmHg, and P= .03, ?0.54 ± 0.21–0.02 ± 0.17 mmHg, respectively), despite the fact that the oral administrations were given in the morning. Systolic blood pressure (122.7 ± 14.4–117.4 ± 13.1 mmHg, P= .04) and systemic vascular resistance (5800 ± 2685–5144 ± 2077 dyne × s/cm⁵, P= .03) were decreased by ACE inhibitors. Conclusions and Clinical Importance: ACE inhibitors decrease LAP minimally, despite reductions in left ventricular afterload. ACE inhibitors should not be used to decrease LAP.     

Pharmacokinetics of midazolam administered concurrently with ketamine after intravenous bolus or infusion in dogs

Brown, S.A., Jacobson, J.D., Hartsfield, S.M. Pharmacokinetics of midazolam administered concurrently with ketamine after intravenous bolus or infusion in dogs. J. vet. Pharmacol. Therap. 16 , 419–425. Midazolam, a water-soluble benzodiazepine tranquilizer, has been considered by some veterinary anaesthesiologists to be suitable as a combination anaesthetic agent when administered concurrently with ketamine because of its water solubility and miscibility with ketamine. However, the pharmacokinetics of midazolam have not been extensively described in the dog. Twelve clinically healthy mixed breed dogs (22.2–33.4 kg) were divided into two groups at random and were administered ketamine (10 mg/kg) and midazolam (0.5 mg/kg) either as an intravenous bolus over 30 s (group 1) or as an i.v. infusion in 0.9% NaCl (2 ml/kg) over 15 min. Blood samples were obtained immediately before the drugs were injected and periodically for 6 h afterwards. Serum concentrations were determined using gas chromatography with electron-capture detection. Serum concentrations were best described using a two-compartment open model and indicated a t_½α of 1.8 min and t_½β.p of 27.8 min after i.v. bolus, and t_½α f 1–35 min and t_½β of 31.6 min after i.v. infusion. The calculated pharmacokinetic coefficient B was significantly smaller after i.v. infusion (429 ± 244 ng/ml) than after i.v. bolus (888 ± 130 ng/ml, P = 0.004). Furthermore, AUC was significantly smaller after i.v. infusion (29 800 ±6120 ng/h/ml) than after i.v. bolus (42 500 ± 8460 ng/h/ml, P < 0.05), resulting in a larger Cl_B after i.v. infusion (17.4 ± 4.00 ml/min/kg than after i.v. bolus (12.1 ± 2.24 ml/min/kg, P < 0.05). No other pharmacokinetic value was significantly affected by rate of intravenous administration.