Effects of diet on pharmacokinetics of phenobarbital in healthy dogs

OBJECTIVE: To determine effects of various diets on the pharmacokinetics of phenobarbital and the interactive effects of changes in body composition and metabolic rate. DESIGN: Prospective study. ANIMALS: 27 healthy sexually intact adult female Beagles. PROCEDURE: Pharmacokinetic studies of phenobarbital were performed before and 2 months after dogs were fed 1 of 3 diets (group 1, maintenance diet; group 2, protein-restricted diet; group 3, fat- and protein-restricted diet) and treated with phenobarbital (approx 3 mg/kg [1.4 mg/lb] of body weight, p.o., q 12 h). Pharmacokinetic studies involved administering phenobarbital (15 mg/kg [6.8 mg/lb], i.v.) and collecting blood samples at specific intervals for 240 hours. Effects of diet and time were determined by repeated-measures ANOVA. RESULTS: Volume of distribution, mean residence time, and half-life (t1/2) of phenobarbital significantly decreased, whereas clearance rate and elimination rate significantly increased with time in all groups. Dietary protein or fat restriction induced significantly greater changes: t1/2 (hours) was lower in groups 2 (mean +/- SD; 25.9 +/- 6.10 hours) and 3 (24.0 +/- 4.70) than in group 1 (32.9 +/- 5.20). Phenobarbital clearance rate (ml/kg/min) was significantly higher in group 3 (0.22 +/- 0.05 ml/kg/min) than in groups 1 (0.17 +/- 0.03) or 2 (0.18 +/- 0.03). Induction of serum alkaline phosphatase activity (U/L) was greater in groups 2 (192.4 +/- 47.5 U/L) and 3 (202.0 +/- 98.2) than in group 1 (125.0 +/- 47.5). CONCLUSIONS AND CLINICAL RELEVANCE: Clinically important differences between diet groups were observed regarding pharmacokinetics of phenobarbital, changes in CBC and serum biochemical variables, and body composition. Drug dosage must be reevaluated if a dog's diet, body weight, or body composition changes during treatment. Changes in blood variables that may indicate liver toxicosis caused by phenobarbital may be amplified by diet-drug interactions.     

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.     

Preliminary study on the pharmacokinetics of phenobarbital in the neonatal foal

Pharmacokinetic characteristics of the anticonvulsant phenobarbital were studied in seven pony and two Thoroughbred foals aged between four and 10 days. A single, 20 mg/kg bodyweight (bwt) dose of phenobarbital was given intravenously over 25 mins and the serum concentrations of the drug were measured using an EMIT AED assay (coefficient of variation 1.37 per cent at 30 micrograms/ml, n = 7). Phenobarbital elimination was found to follow first order kinetics. The mean (+/- sd) peak phenobarbital serum concentration was 18.6 +/- 2.1 micrograms/ml at 1 h after initiation of infusion with a mean (+/- se) half-life of 12.8 +/- 2.1 h. The mean (+/- se) volume of distribution was 0.86 +/- 0.026 litres/kg bwt and mean (+/- se) total body clearance was 0.0564 +/- 0.0065 litres/kg bwt/h. Sedation was noticed 15 to 20 mins after the beginning of infusion and lasted for up to 8 h. All foals could be aroused and could walk although they were ataxic for the first 1 to 2 h. A degree of delayed hyperexcitability occurred 3 to 8 h after infusion. In equine neonatal seizure disorders it is recommended to use a loading dose of 20 mg/kg bwt of phenobarbital, followed by maintenance doses of 9 mg/kg bwt at 8 h. With this regimen, average steady state serum phenobarbital concentrations should range between approximately 11.6 and 53 micrograms/ml. Phenobarbital serum concentrations should be monitored following the loading dose and 24 h after initiating the maintenance doses to check that levels remain within the suggested (human) therapeutic range of 15 to 40 micrograms/ml.     

Total intravenous anesthesia in greyhounds: pharmacokinetics of propofol and fentanyl--a preliminary study

OBJECTIVE: To evaluate concomitant propofol and fentanyl infusions as an anesthetic regime, in Greyhounds. ANIMALS: Eight clinically normal Greyhounds (four male, four female) weighing 25.58 +/- 3.38 kg. DESIGN: Prospective experimental study. METHODS: Dogs were premedicated with acepromazine (0.05 mg/kg) by intramuscular (i.m.) injection. Forty five minutes later anesthesia was induced with a bolus of propofol (4 mg/kg) by intravenous (i.v.) injection and a propofol infusion was begun (time = 0). Five minutes after induction of anesthesia, fentanyl (2 microg/kg) and atropine (40 microg/kg) were administered i.v. and a fentanyl infusion begun. Propofol infusion (0.2 to 0.4 mg/kg/min) lasted for 90 minutes and fentanyl infusion (0.1 to 0.5 microg/kg/min) for 70 minutes. Heart rate, blood pressure, respiratory rate, end-tidal carbon dioxide, body temperature, and depth of anesthesia were recorded. The quality of anesthesia, times to return of spontaneous ventilation, extubation, head lift, and standing were also recorded. Blood samples were collected for propofol and fentanyl analysis at varying times before, during and after anesthesia. RESULTS: Mean heart rate of all dogs varied from 52 to 140 beats/min during the infusion. During the same time period, mean blood pressure ranged from 69 to 100 mm Hg. On clinical assessment, all dogs appeared to be in light surgical anesthesia. Mean times (+/- SEM), after termination of the propofol infusion, to return of spontaneous ventilation, extubation, head lift and standing for all dogs were 26 +/- 7, 30 +/- 7, 59 +/- 12, and 105 +/- 13 minutes, respectively. Five out of eight dogs either whined or paddled their forelimbs in recovery. Whole blood concentration of propofol for all eight dogs ranged from 1.21 to 6.77 microg/mL during the infusion period. Mean residence time (MRTinf) for propofol was 104.7 +/- 6.0 minutes, mean body clearance (Clb) was 53.35 +/- 0.005 mL/kg/min, and volume of distribution at steady state (Vdss) was 3.27 +/- 0.49 L/kg. Plasma concentration of fentanyl for seven dogs during the infusion varied from 1.22 to 4.54 ng/mL. Spontaneous ventilation returned when plasma fentanyl levels were >0.77 and <1.17 ng/mL. MRTinf for fentanyl was 111.3 +/- 5.7 minutes. Mean body clearance was 29.1 +/- 2.2 mL/kg/min and Vdss was 2.21 +/- 0.19 L/kg. CONCLUSION AND CLINICAL RELEVANCE: In Greyhounds which were not undergoing any surgical stimulation, total intravenous anesthesia maintained with propofol and fentanyl infusions induced satisfactory anesthesia, provided atropine was given to counteract bradycardia. Despite some unsatisfactory recoveries the technique is worth investigating further for clinical cases, in this breed and in mixed breed dogs.     

Effects of racing on hematologic and serum biochemical values in greyhounds

Blood samples were collected on nonracing days from 57 racing Greyhounds at 2 weeks, 8 weeks, 13 weeks, and 16 weeks after the beginning of the racing season. Hematologic and biochemical tests were performed to detect marked changes induced by stress of racing. In general, these Greyhounds were healthy. Rhabdomyolysis was detected in one dog. In several other dogs, possible subclinical muscle injury was identified by increased serum creatine kinase activities. Mean serum Ca concentrations tended to decrease during the racing season. None of the tests was a good predictor of racing performance. Mean values for several hematologic and biochemical tests were different from those of other breeds of dogs.     

The pharmacokinetics of levetiracetam in healthy dogs concurrently receiving phenobarbital

Moore, S.A., Muñana, K.R., Papich, M.G., Nettifee‐Osborne, J.A. The pharmacokinetics of levetiracetam in healthy dogs concurrently receiving phenobarbital. J. vet. Pharmacol. Therap. 34 , 31–34. Levetiracetam (LEV) is a commonly used add‐on medication in dogs with refractory epilepsy. The objective of this study was to determine if the pharmacokinetics of LEV are altered by concurrent administration of phenobarbital (PB). Six healthy dogs received a single oral dose of LEV (16.7–27.8 mg/kg). Blood samples were collected at baseline and intermittently for 24 h. The study was repeated after the dogs received oral PB (2.0–3.3 mg/kg) twice daily for 21 days. Plasma LEV levels were evaluated by high pressure liquid chromatography, and data analyzed using a compartmental model. Compared with values determined when LEV was administered alone, concurrent administration of PB resulted in a decrease in LEV peak concentration (C_max) from 32.39 ± 6.76 to 18.22 ± 8.97 (P = 0.0071), a decrease in elimination half‐life (T_1/2) from 3.43 ± 0.47 to 1.73 ± 0.22 (P = 0.0005), and an increase in oral clearance from 124.93 ± 26.93 to 252.99 ± 135.43 ml/h/kg (P < 0.0001). Concurrent PB administration significantly alters the pharmacokinetics of LEV in the dog, indicating that dosage adjustments might be necessary when the drug is administered with PB.     

A comparative study of the pharmacokinetics of thiopental in the rabbit, sheep and dog

The central arterial pharmacokinetics of thiopental were studied in six rabbits, six sheep and six dogs after a short infusion at approximately 10 mg/kg min. Thiopental was infused to a defined electro-encephalographic endpoint (EEG burst suppression). The time to reach early burst suppression was longer in the dog (3.9 +/- 0.5 min) compared with the sheep (3.0 +/- 0.6 min) and the rabbit (2.5 +/- 0.5 min). The total dose required to produce the same level of EEG activity was higher in the dog (35.9 +/- 6.8 mg/kg) compared with the sheep (24.3 +/- 5.3 mg/kg) and the rabbit (21.6 +/- 6.8 mg/kg). The plasma concentration-time data for each animal was fitted using non-linear regression to a bi- or tri-exponential function. In all animals, the plasma-time profile was best described as a tri-exponential decay. The initial volume of distribution was similar in all three species (rabbit, 38.6 +/- 10.0 mg/kg; sheep, 44.5 +/- 9.1 ml/kg; dog, 38.1 +/- 18.4 ml/kg). The maximum arterial plasma thiopental concentration achieved at EEG burst suppression was higher in the sheep (221.8 +/- 27.9 micrograms/ml) than the dog (164.7 +/- 29.9 micrograms/ml) or the rabbit (112.3 +/- 15.1 micrograms/ml). Thiopental distribution clearance was slower in the sheep (43.6 +/- 15.1 ml/min/kg) compared with the rabbit (110.5 +/- 18.7 ml/min kg) and the dog (97.2 +/- 47.2 ml/min kg). Elimination half-life was extended in the sheep (251.9 +/- 107.8 min) and dog (182.4 +/- 57.9 min) relative to the rabbit (43.1 +/- 3.4 min).(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasma pharmacokinetics and synovial fluid concentrations after oral administration of single and multiple doses of celecoxib in greyhounds

OBJECTIVE: To determine the plasma pharmacokinetics and synovial fluid concentrations after oral administration of single and multiple doses of celecoxib in Greyhounds. ANIMALS: 7 adult Greyhounds. PROCEDURES: Dogs received celecoxib (median dose, 11.8 mg/kg [range, 11.5 to 13.6 mg/kg], PO, q 24 h) for 10 days. Blood samples were collected prior to administration of celecoxib and serially for 24 hours after the 1st and 10th doses were administered. A synovial joint catheter was placed into a stifle joint in each dog for collection of synovial fluid samples. Concentrations of celecoxib in plasma and synovial fluid were quantified by use of a validated liquid chromatography/mass spectrometry method. Identification of hydroxy- and carboxyl-celecoxib in plasma and synovial fluid was also performed. Pharmacokinetic parameters were determined by use of noncompartmental analysis. RESULTS: Administration of multiple doses of celecoxib resulted in a significant decrease (40%) in median area under the curve (AUC) values and a corresponding decrease in median maximum concentrations (Cmax; 2,620 to 2,032 ng/mL) between the 1st and 10th doses. Synovial fluid concentrations were less than the corresponding plasma concentrations at all times except 24 hours after administration of the 10th dose of celecoxib. CONCLUSIONS AND CLINICAL RELEVANCE: Celecoxib distributes into the synovial fluid of Greyhounds. Although the exact mechanism for the decreases in AUC and Cmax is not known, results suggested that the plasma pharmacokinetics of celecoxib are different after administration of multiple doses in Greyhounds. These findings warrant further investigation on the absorption, distribution, metabolism, and elimination of celecoxib in Greyhounds and other breeds of dogs.     

Effects of phenobarbital treatment on 3-methylindole toxicosis in ponies

To study the role of cytochrome P-450-dependent mixed function oxidase reactions in equine 3-methylindole (3MI) toxicosis, ponies were given 20 mg of phenobarbital/kg of body weight at 72, 60, 48, 36, and 24 hours before 100 mg of oral 3MI/kg to induce cytochrome P-450 or no treatment (controls). Maximal 3MI plasma concentration was decreased and clearance was faster in phenobarbital-treated ponies. Plasma 3MI was still detectable 12 and 36 hours after dosing in phenobarbital-treated and control ponies, respectively. Phenobarbital treatment induced a distribution phase with transition from a 1-compartment to a 2-compartment extravascular model. Bronchiolitis occurred in all ponies 72 hours after 3MI, but was more severe in those treated with phenobarbital. Appearance of a distribution phase, increased total body clearance, and more severe bronchiolitis in phenobarbital-treated ponies indicated that mixed function oxidases are involved in metabolism and conversion of 3MI to a toxic metabolite.     

Effects of long-term phenobarbital treatment on the liver in dogs

Long-term administration of phenobarbital has been reported to cause hepatic injury in dogs. Phenobarbital induces hepatic enzymes, and it may be difficult to distinguish the effect of enzyme induction on serum liver enzyme activities from actual hepatic damage. The hepatotoxicity of phenobarbital and the impact of enzyme induction on serum liver enzyme activity were investigated prospectively in 12 normal dogs. Phenobarbital was administered for 29 weeks at 5 mg per kilogram of body weight (range, 4.8— 6.6 mg/kg) PO q12h, resulting in therapeutic serum phenobarbital concentrations (20–40 μg/mL). Serum alkaline phosphatase (ALP), alanine transaminase (ALT), aspartate transaminase (AST), γ-glutamyltransferase (GGT), fasted bile acids (fBA), total bilirubin, and albumin were determined before and during treatment. Lateral abdominal radiographs, abdominal ultrasounds, and histopathologic examinations of liver tissue obtained by ultrasound-guided biopsy were performed before and during treatment. Radiographs revealed a moderate increase in liver size in most dogs. Ultrasonographic examination revealed no change in liver echogenicity or architecture. No evidence of morphologic liver damage was observed histopathologically. ALP and ALT increased significantly ( P < .05), GGT increased transiently, and albumin decreased transiently during the study. There were no significant changes in AST, bilirubin, and fBA. These results suggest that increases in serum ALP, ALT, and GGT may reflect enzyme induction rather than hepatic injury during phenobarbital treatment in dogs. Serum AST, fBA, and bilirubin, and ultrasonographic evaluation of the liver are not affected by the enzyme-inducing effect of phenobarbital and can therefore be helpful to assess liver disease in dogs treated with the drug.     

The prevention of injuries in greyhounds

The analysis of 154 greyhound injuries shows a significant lower incidence of injuries in the case of proper preparing for the race. The prevention of injuries was carried out during the whole training-season. These optimally prepared dogs showed a better race performance and were able to take part in more races.     

Pharmacodynamic properties of succinylcholine in greyhounds

Succinylcholine is a depolarizing neuromuscular blocking drug, which is rapidly hydrolyzed by the enzyme pseudocholinesterase. In Greyhounds, the metabolism of certain drugs is atypical relative to other breeds, and it has been suggested that Greyhounds may be an atypical population, with lower pseudocholinesterase activity, slower hydrolysis of the drug succinylcholine, and a prolonged duration of action of the drug, compared with a mixed-breed control population. Six healthy adult Greyhounds and 6 healthy adult mixed-breed dogs were studied. Blood was drawn from each dog and analyzed for serum cholinesterase activity, and a biochemical profile was done to verify normal liver function. The dogs were anesthetized with methohexital (10 mg/kg) and isoflurane (1.25 minimal alveolar concentration) in 100% oxygen. Ventilation was controlled, fluids were administered IV (lactated Ringer solution, 10 ml/kg/h), and blood gases, blood pressure, and heart rate were monitored. The right hind limb was immobilized and a force transducer was used to monitor twitch strength of the interosseous muscle with supramaximal stimulation of the tibial nerve. Succinylcholine was administered to each dog 3 times at a dosage of 0.3 mg/kg. After drug administration, the time to 50% recovery of twitch strength (single twitch, 1/s), and 50% recovery of train-of-4 was determined. Subsequent doses were administered after complete recovery. The time to 50% recovery after succinylcholine administration in Greyhounds (38 minutes, dose 1, single twitch) was not significantly different than the time to 50% recovery in mixed-breed dogs (29 minutes, dose 1, single twitch), using either monitoring technique. Pseudocholinesterase activity was also not significantly different between the Greyhounds (1,685 mU/ml) and the mixed-breed dogs (1,588 mU/ml).(ABSTRACT TRUNCATED AT 250 WORDS)