Disposition and safety of zonisamide after intravenous and oral single dose and oral multiple dosing in normal hound dogs

The purpose of this study was to determine an oral dosing regimen of zonisamide in healthy dogs such that therapeutic concentrations would be safely reached and maintained at steady‐state. Adult hound dogs (n = 8) received a single IV (6.9) and an oral (PO) dose (10.3 mg/kg) using a randomized cross‐over design. Zonisamide was then administered at 10.3 mg/kg PO every 12 h for 8 weeks. Zonisamide was quantitated in blood compartments or urine by HPLC and data were subjected to noncompartmental pharmacokinetic analysis. Comparisons were made among blood compartments (one‐way anova ; P ≤ 0.05). Differences among blood compartments occurred in all derived pharmacokinetic paramenters for each route of administration after single and multiple dosing. After single PO dosing, plasma C_max was 14.4 ± 2.3 mcg/mL and elimination half‐life was 17.2 ± 3.6 h. After IV dosing, volume of distribution was 1.1 ± 0.25 L/kg, clearance was 58 ± 11 mL/h/kg and elimination t_1/2 was 12.9 ± 3.6 h. Oral bioavailability was 68 ± 12%; fraction of unbound drug approximated 60%. At steady‐state (4 days), differences occurred for for all parameters except C_max and C_min. Plasma C_max at steady‐state was 56 ± 12 mcg/mL, with 10% fluctuation between C_max and C_min. Plasma t_1/2 (h) was 23.52 ± 5.76 h. Clinical laboratory tests remained normal, with the exception of total T4, which was below normal limits at study end. In conclusion, 10 mg/kg twice daily results in peak plasma zonisamide which exceeds the recommended human therapeutic range (10 to 40 μg/mL) and is associated with suppression of thyroid hormone synthesis. A reasonable b.i.d starting dose for canine epileptics would be 3 mg/kg. Zonisamide monitored in either serum or plasma should be implemented at approximately 7 days.     

The effect of furosemide on left atrial pressure in dogs with mitral valve regurgitation

Background: The effects of furosemide on left atrial pressure (LAP) in dogs with mitral regurgitation (MR) have not been documented in a quantitative manner and between different routes of administration. Objective: To document LAP and echocardiographic parameters in MR dogs administered furosemide IV or PO, in order to document changes in LAP after furosemide treatment. Animals: Five healthy Beagle dogs (3 males and 2 females; aged 2 years) were used. Methods: Experimental, cross‐over, and interventional study. LAP was measured before the administration of furosemide, and 30 minutes, 1, 1.5, 2, 3, 4, 5, 6, 8, 12, and 24 hours after administration. Furosemide 1, 2, or 4 mg/kg IV, PO or placebo was administered. Results: LAP was significantly decreased with all administrations of furosemide but not after placebo (P < .05, respectively). The max reduction was observed 1 hour (1 mg/kg IV, 15.04 ± 7.02 mmHg), 3 hours (2, 4 mg/kg IV, 13.28 ± 8.01, 9.23 ± 4.92 mmHg), 4 hours (1 mg/kg PO, 14.68 ± 11.51 mmHg), and 5 hours (2, 4 mg/kg PO, 13.19 ± 10.52, 10.70 ± 7.69 mmHg). E wave and E/Ea were significantly decreased corresponding to the reduction of LAP after administration of 2 and 4 mg/kg (P < .05, respectively). Conclusions and Clinical Importance: LAP was decreased in proportion to the dosage of furosemide, which did not significantly differ between IV and PO of the same dosages. E wave and E/Ea might be useful for the treatment evaluation of furosemide.     

Estimated plasma bupivacaine concentration after single dose and eight-hour continuous intra-articular infusion of bupivacaine in normal dogs

Objective— To estimate maximum plasma concentration (C_max) and time to maximum plasma (t_max) bupivacaine concentration after intra‐articular administration of bupivacaine for single injection (SI) and injection followed by continuous infusion (CI) in normal dogs. Study Design— Cross‐over design with a 2‐week washout period. Animals— Healthy Coon Hound dogs (n=8). Methods— Using gas chromatography/mass spectrometry, canine plasma bupivacaine concentration was measured before and after SI (1.5 mg/kg) and CI (1.5 mg/kg and 0.3 mg/kg/h). Software was used to establish plasma concentration–time curves and estimate C_max, T_max and other pharmacokinetic variables for comparison of SI and CI. Results— Bupivacaine plasma concentration after SI and CI best fit a 3 exponential model. For SI, mean maximum concentration (C_max, 1.33±0.954 μg/mL) occurred at 11.37±4.546 minutes. For CI, mean C_max (1.13±0.509 μg/mL) occurred at 10.37±4.109 minutes. The area under the concentration–time curve was smaller for SI (143.59±118.390 μg/mL × min) than for CI (626.502±423.653 μg/mL × min, P=.02) and half‐life was shorter for SI (61.33±77.706 minutes) than for CI (245.363±104.415 minutes, P=.01). The highest plasma bupivacaine concentration for any dog was 3.2 μg/mL for SI and 2.3 μg/mL for CI. Conclusion— Intra‐articular bupivacaine administration results in delayed absorption from the stifle into the systemic circulation with mean C_max below that considered toxic and no systemic drug accumulation. Clinical Relevance— Intra‐articular bupivacaine can be administered with small risk of reaching toxic plasma concentrations in dogs, though toxic concentrations may be approached. Caution should be exercised with multimodal bupivacaine administration because plasma drug concentration may rise higher than with single intra‐articular injection.     

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.     

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.     

Drug Residues in Serum of Dogs Receiving Anticancer Chemotherapy

Background: The presence of drug residues in blood samples can represent an occupational hazard. However, studies on cytotoxic drug residues in serum of dogs are lacking in veterinary oncology. Objective: To evaluate possible occupational hazards associated with handling of blood samples from dogs receiving oncolytic drugs 7 days after treatment. Animals: Twenty‐seven client‐owned dogs treated for lymphoma or mast cell tumors with vincristine, vinblastine, cyclophosphamide, or doxorubicin. Methods: Prospective, observational study. Serum samples were either taken 7 days after administration of vincristine, cyclophosphamide, doxorubicin (lymphoma), and vinblastine (mast cell tumor), or 1–2 days after the last concurrent oral administration of cyclophosphamide (mast cell tumor). Additionally, serum was collected within 5 minutes of treatment. Measurement of drug residues in serum was performed by liquid chromatography tandem mass spectrometry (LC/MS/MS). Results: In 33 samples collected within 5 minute of treatment, the median serum concentrations were vincristine: 37 μg/L (range: 11–87 μg/L), vinblastine: 13 μg/L (range: 13–35 μg/L), cyclophosphamide: 2,484 μg/L (range: 1,209–2,778 μg/L), doxorubicin: 404 μg/L (range: 234–528 μg/L). In 81 serum samples collected 7 days after treatment vinblastine (7 μg/L) was detected in 1 sample, and cyclophosphamide (7 and 9 μg/L) in 2 samples collected 1–2 days after oral administration of cyclophosphamide. Medications were not detected in any of the other samples. Conclusions and Clinical Importance: Handling of blood samples from dogs receiving oncolytic chemotherapy 7 days after treatment with vincristine, vinblastine, cyclophosphamide, and doxorubicin should not present a health hazard.     

Pharmacokinetics of tramadol following intravenous and oral administration in male rhesus macaques (Macaca mulatta)

Recently, tramadol and its active metabolite, O‐desmethyltramadol (M1), have been studied as analgesic agents in various traditional veterinary species (e.g., dogs, cats, etc.). This study explores the pharmacokinetics of tramadol and M1 after intravenous (IV) and oral (PO) administration in rhesus macaques (Macaca mulatta), a nontraditional veterinary species. Rhesus macaques are Old World monkeys that are commonly used in biomedical research. Effects of tramadol administration to monkeys are unknown, and research veterinarians may avoid inclusion of this drug into pain management programs due to this limited knowledge. Four healthy, socially housed, adult male rhesus macaques (Macaca mulatta) were used in this study. Blood samples were collected prior to, and up to 10 h post‐tramadol administration. Serum tramadol and M1 were analyzed using liquid chromatography–mass spectrometry. Noncompartmental pharmacokinetic analysis was performed. Tramadol clearance was 24.5 (23.4–32.7) mL/min/kg. Terminal half‐life of tramadol was 111 (106–127) min IV and 133 (84.9–198) min PO. Bioavailability of tramadol was poor [3.47% (2.14–5.96%)]. Maximum serum concentration of M1 was 2.28 (1.88–2.73) ng/mL IV and 11.2 (9.37–14.9) ng/mL PO. Sedation and pruritus were observed after IV administration.     

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.     

Estimation of intestinal permeability in healthy dogs using the contrast medium iohexol

Background: Iohexol is a nonradioactive marker that has been used successfully to test intestinal permeability in humans with inflammatory bowel disease. There is evidence in dogs that iohexol shares a similar permeability pathway as ⁵¹chromium‐EDTA, the gold standard marker. Objective: The objective of this study was to determine an optimal oral iohexol dosage for an intestinal permeability serum test (IPST) and to use the test to estimate intestinal permeability in healthy dogs. Methods: Eight clinically healthy dogs free of gastrointestinal, liver, and pancreatic disease were used in the study. Dosages of 0.25, 0.5, 1.0, 2.0, and 4.0 mL/kg of Omnipaque‐350 (iohexol) were administered to 2 dogs at weekly intervals. Iohexol concentration was determined in serum samples obtained hourly for 6 hours after administration by high‐performance liquid chromatography. Using the optimal dosage, iohexol was administered to 8 dogs twice, 6–36 days (mean 10 days) apart, and coefficients of variation (CVs) for iohexol concentration were calculated. Results: A dosage of 2.0 mL/kg was chosen as optimal for the IPST, based on ease of iohexol detection in serum, intestinal contrast, and clinical effects of iohexol. Following administration of this dose to healthy dogs, mean (±SD) serum iohexol concentrations were 8.74±4.38, 11.89±5.67, 12.40±5.47, 9.23±5.54, 7.61±5.13, and 5.27±2.67 μg/mL at 1, 2, 3, 4, 5, and 6 hours after iohexol administration, respectively. CVs between the 2 test days were 28–45%. Conclusions: Using the iohexol dosage established in this study, the iohexol IPST was easy to perform as a marker for intestinal permeability in dogs. Further studies to establish reference intervals and evaluate the diagnostic value of the iohexol IPST in dogs with gastrointestinal disease are warranted.     

Pharmacokinetics of the individual enantiomer S-(+)-ketoprofen after intravenous and oral administration in dogs at two dose levels

The pharmacokinetic of the individual S-(+)-enantiomer of ketoprofen, S-(+)-ketoprofen, after intravenous (IV) and oral (PO) administration was determined in six dogs at 1 and 3 mg/kg. Plasma concentrations were determined by high performance liquid chromatography with ultraviolet detection. The concentration–time curves were analyzed by non-compartmental methods. Steady-state volume of distribution (Vss) and clearance (Cl) of S-(+)-ketoprofen after IV administration were 0.22 ± 0.07 and 0.19 ± 0.03 L/kg, and 0.10 ± 0.02 and 0.09 ± 0.01 L/h/kg, at 1 and 3 mg/kg, respectively. Following PO administration, S-(+)-ketoprofen achieved maximum plasma concentrations of 4.91 ± 0.76 and 12.47 ± 0.62 μg/ml, at two dose levels, respectively. The absolute bioavailability after PO route was 88.66 ± 12.95% and 85.36 ± 13.90%, respectively.     

Pharmacokinetics of acyclovir in adult horses

Objective: To determine the pharmacokinetics of acyclovir administered intravenously (IV) and orally to healthy adult horses. Design: Random cross‐over with an approximate 1‐week washout period between trials. Setting: University veterinary medical teaching hospital. Animals: Six healthy adult research herd horses. Interventions and main results: Acyclovir was administered IV (10 mg/kg in 1 L isotonic crystalloid solution over 60 minutes) and orally (20 mg/kg) to healthy adult horses. Plasma samples were obtained and acyclovir concentrations were determined by high‐pressure liquid chromatography. Peak concentration (mean±SD) for IV acyclovir was 13.74±5.88 μg/mL at the completion of the 1‐hour infusion. The half‐life of the distribution phase (α) was 0.16 hours while the half‐life of the elimination phase (β) was 9.6 hours. The steady‐state volume of distribution was 3.93±1.21 L/kg. We were unable to measure pharmacokinetics after PO acyclovir as plasma concentrations were below the lower limits of detection in all 6 horses. Conclusions: IV administration of acyclovir to healthy adult horses achieves concentrations within the sensitivity range described for equine herpes virus‐type 1. The oral bioavailability of acyclovir in horses is low and additional studies are required.     

Plasma and serum concentrations of cytarabine administered via continuous intravenous infusion to dogs with meningoencephalomyelitis of unknown etiology

The objective of this study was to evaluate the plasma and serum concentrations of cytarabine (CA) administered via constant rate infusion (CRI) in dogs with meningoencephalomyelitis of unknown etiology (MUE). Nineteen client‐owned dogs received a CRI of CA at a dose of 25 mg/m²/h for 8 h as treatment for MUE. Dogs were divided into four groups, those receiving CA alone and those receiving CA in conjunction with other drugs. Blood samples were collected at 0, 1, 8, and 12 h after initiating the CRI. Plasma (n = 13) and serum (n = 11) cytarabine concentrations were measured by high‐pressure liquid chromatography. The mean peak concentration (C_MAX) and area under the curve (AUC) after CRI administration were 1.70 ± 0.66 μg/mL and 11.39 ± 3.37 h·μg/mL, respectively, for dogs receiving cytarabine alone, 2.36 ± 0.35 μg/mL and 16.91 + 3.60 h·μg/mL for dogs administered cytarabine and concurrently on other drugs. Mean concentrations for all dogs were above 1.0 μg/mL at both the 1‐ and 8‐h time points. The steady‐state achieved with cytarabine CRI produces a consistent and prolonged exposure in plasma and serum, which is likely to produce equilibrium between blood and the central nervous system in dogs with a clinical diagnosis of MUE. Other medications commonly used to treat MUE do not appear to alter CA concentrations in serum and plasma.     

The pharmacokinetics of midazolam after intravenous,intramuscular, and rectal administration in healthy dogs

Intravenous benzodiazepines are utilized as first‐line drugs to treat prolonged epileptic seizures in dogs and alternative routes of administration are required when venous access is limited. This study compared the pharmacokinetics of midazolam after intravenous (IV), intramuscular (IM), and rectal (PR) administration. Six healthy dogs were administered 0.2 mg/kg midazolam IV, IM, or PR in a randomized, 3‐way crossover design with a 3‐day washout between study periods. Blood samples were collected at baseline and at predetermined intervals until 480 min after administration. Plasma midazolam concentrations were measured by high‐pressure liquid chromatography with UV detection. Rectal administration resulted in erratic systemic availability with undetectable to low plasma concentrations. Arithmetic mean values ± SD for midazolam peak plasma concentrations were 0.86 ± 0.36 μg/mL (C₀) and 0.20 ± 0.06 μg/mL (C_max), following IV and IM administration, respectively. Time to peak concentration (T_max) after IM administration was 7.8 ± 2.4 min with a bioavailability of 50 ± 16%. Findings suggest that IM midazolam might be useful in treating seizures in dogs when venous access is unavailable, but higher doses may be needed to account for intermediate bioavailability. Rectal administration is likely of limited efficacy for treating seizures in dogs.     

Pharmacokinetics and bone tissue concentrations of lincomycin following intravenous and intramuscular administrations to cats

Albarellos, G. A., Montoya, L., Denamiel, G. A. A., Velo, M. C., Landoni, M. F. Pharmacokinetics and bone tissue concentrations of lincomycin following intravenous and intramuscular administrations to cats. J. vet. Pharmacol. Therap.  35 , 534–540. The pharmacokinetic properties and bone concentrations of lincomycin in cats after single intravenous and intramuscular administrations at a dosage rate of 10 mg/kg were investigated. Lincomycin minimum inhibitory concentration (MIC) for some gram‐positive strains isolated from clinical cases was determined. Serum lincomycin disposition was best‐fitted to a bicompartmental and a monocompartmental open models with first‐order elimination after intravenous and intramuscular dosing, respectively. After intravenous administration, distribution was rapid (T_1/2(d) = 0.22 ± 0.09 h) and wide as reflected by the volume of distribution (V_(d(ss))) of 1.24 ± 0.08 L/kg. Plasma clearance was 0.28 ± 0.09 L/h·kg and elimination half‐life (T_1/2) 3.56 ± 0.62 h. Peak serum concentration (C_max), T_max, and bioavailability for the intramuscular administration were 7.97 ± 2.31 μg/mL, 0.12 ± 0.05 h, and 82.55 ± 23.64%, respectively. Thirty to 45 min after intravenous administration, lincomycin bone concentrations were 9.31 ± 1.75 μg/mL. At the same time after intramuscular administration, bone concentrations were 3.53 ± 0.28 μg/mL. The corresponding bone/serum ratios were 0.77 ± 0.04 (intravenous) and 0.69 ± 0.18 (intramuscular). Lincomycin MIC for Staphylococcus spp. ranged from 0.25 to 16 μg/mL and for Streptococcus spp. from 0.25 to 8 μg/mL.     

Pharmacokinetics of clomipramine in dogs following single-dose intravenous and oral administration

OBJECTIVE: To determine pharmacokinetics of clomipramine and its principle metabolite (desmethylclomipramine) in the plasma of dogs after IV or oral administration of a single dose. ANIMALS: 6 male and 6 female Beagles. PROCEDURES: Clomipramine was administered IV (2 mg/kg), PO (4 mg/kg) after food was withheld for 15 hours, and PO (4 mg/kg) within 25 minutes after dogs were fed. Plasma clomipramine and desmethylclomipramine concentrations were measured by use of a gas chromatography with mass-selection method. RESULTS: Time to peak plasma concentrations of clomipramine and desmethylclomipramine following oral administration was 1.2 hours. For clomipramine, after IV administration, elimination half-life was 5 hours, mean residence time was 3 hours, and plasma clearance was 1.4 L/h/kg. Values for mean residence time and terminal half-life following oral administration were similar to values obtained following IV administration, and systemic bioavailability was approximately 20% for clomipramine and 140% for desmethylclomipramine, indicating fast absorption of clomipramine from the gastrointestinal tract and extensive first-pass metabolism. Administration of clomipramine with food did not alter the area under the concentration versus time curve for desmethylclomipramine but resulted in a 25% increase for clomipramine. Clomipramine and desmethylclomipramine were extensively bound (> 96%) to serum proteins. There were no significant differences in area under the concentration versus time curve between male and female dogs. CONCLUSIONS AND CLINICAL RELEVANCE: Results indicate that there should not be any clinically important differences in efficacy regardless of whether clomipramine is administered with or without food.     

Pharmacokinetics of single-dose intravenous levetiracetam administration in normal dogs

Objective: To determine plasma pharmacokinetics of levetiracetam after a single intravenous dose (60 mg/kg) in normal dogs using a high‐performance liquid chromatography assay validated for canine plasma. Design: Pharmacokinetic study. Setting: A university‐based canine research facility. Animals: Six healthy adult dogs. Interventions: Intravenous drug administration, multiple blood sample procurement. Measurements and main results: There were no obvious adverse effects associated with the intravenous (IV) bolus administration of levetiracetam in any of the dogs. Plasma levetiracetam concentrations remained above or within the reported therapeutic range for humans (5–45 μg/mL) for all dogs, for all time periods evaluated. Mean and median (in parentheses) values for pharmacokinetic parameters included the following: maximum plasma concentration, 254 μg/mL (254 μg/mL); half‐life, 4.0 hours (4.0 hours); volume of distribution at steady state, 0.48 L/kg (0.48 L/kg); clearance, 1.4 mL/kg/min (1.5 mL/kg/min); and median residence time, 6.0 hours (6.0 hours). Conclusions: In normal dogs, a 60 mg/kg IV bolus dose of levetiracetam is well tolerated and achieves plasma drug concentrations within or above the therapeutic range reported for humans for at least 8 hours after administration. Based on the favorable pharmacokinetics and tolerability demonstrated for IV levetiracetam in this study, in addition to previously demonstrated efficacy of oral levetiracetam, IV levetiracetam may be a useful treatment option for emergency management of canine seizure activity.     

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.     

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 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.     

Pharmacokinetics of carprofen in anaesthetized pigs: a preliminary study

ObjectiveTo investigate the pharmacokinetics of carprofen after a single intravenous (IV) dose and multiple oral doses administered to pigs undergoing electroporation of the pancreas.Study designProspective experimental study.AnimalsA group of eight female pigs weighing 31.74 ± 2.24 kg (mean ± standard deviation).MethodsCarprofen 4 mg kg^?1 was administered IV after placement of a central venous catheter during general anaesthesia with isoflurane. Blood samples were collected 30 seconds before and 5, 10, 20, 30 and 60 minutes and 2, 4, 6, 8, 12 and 24 hours after carprofen administration. Subsequently, the same dose of carprofen was administered orally, daily, for 6 consecutive days and blood collected at 36, 48, 60, 72, 96, 120, 144 and 168 hours after initial carprofen administration. Plasma was analysed using liquid chromatography with mass spectrometry. Standard pharmacokinetic parameters were calculated by compartmental analysis of plasma concentration–time curves. Data are presented as mean ± standard error.ResultsThe initial plasma concentration of IV carprofen was estimated at 54.57 ± 3.92 μg mL^?1 and decreased to 8.26 ± 1.07 μg mL^?1 24 hours later. The plasma elimination curve showed a bi-exponential decline: a rapid distribution phase with a distribution half-life of 0.21 ± 0.03 hours and a slower elimination phase with an elimination half-life of 17.31 ± 3.78 hours. The calculated pharmacokinetic parameters were as follows: the area under the plasma concentration–time curve was 357.3 ± 16.73 μg mL^?1 hour, volume of distribution was 0.28 ± 0.07 L kg^?1 and plasma clearance rate was 0.19 ± 0.009 mL minute^?1 kg^?1. The plasma concentration of carprofen, administered orally from days 2 to 7, varied from 9.03 ± 1.87 to 11.49 ± 2.15 μg mL^?1.Conclusions and clinical relevanceCarprofen can be regarded as a long-acting non-steroidal anti-inflammatory drug in pigs.