Pseudolymphoma in a cat on phenobarbital treatment

A two‐year‐old female spayed domestic shorthair cat was presented with apathy, inappetence and generalised lymphadenomegaly. Anamnestic data included a generalised seizure disorder and phenobarbital treatment started one month before presentation. Routine blood analysis revealed only mild abnormalities and FeLV and FIV tests were negative. Both popliteal lymph nodes were aspirated and cytology was consistent with reactive lymph node hyperplasia. PCR for antigen receptor rearrangement testing diagnosed a polyclonal cell population. In the absence of another cause, lymphadenomegaly was attributed to an adverse drug reaction and phenobarbital was discontinued. The cat's condition improved and lymph node size normalised over the next 10 days. The retrospective diagnosis was phenobarbital‐induced pseudolymphoma.     

Pancytopenia secondary to suspected idiosyncratic phenobarbital reaction in a dog

A 4-year-old neutered male St. Bernard-mastiff crossbred dog showed clinical signs of lethargy and anorexia after being administered phenobarbital for the treatment of idiosyncratic seizures. A complete blood (cell) count revealed pancytopenia. Auto-agglutination and Coombs tests were negative suggesting that an immunemediated cause was unlikely; therefore, an idiosyncratic reaction to phenobarbital was suspected. Supportive care and control of seizures with zonisamide was initiated and clinical signs improved. Blood values were monitored closely and returned to normal after 3 wk.     

Serum triglyceride concentration in dogs with epilepsy treated with phenobarbital or with phenobarbital and bromide

OBJECTIVE: To compare serum triglyceride concentrations obtained after food had been withheld (i.e., fasting concentrations) in dogs with epilepsy that had been treated long term (> or = 3 months) with phenobarbital or with phenobarbital and potassium bromide with concentrations in healthy control dogs. DESIGN: Cross-sectional study. ANIMALS: 57 epileptic dogs that had been treated with phenobarbital (n=28) or with phenobarbital and bromide (29) and 57 healthy, untreated control dogs matched on the basis of age, breed, sex, neuter status, and body condition score. PROCEDURES: Blood samples were collected after food had been withheld for at least 12 hours, and serum biochemical and lipid concentrations were determined. Oral fat tolerance tests were performed in 15 control dogs and 9 dogs with epilepsy treated with phenobarbital alone. RESULTS: 19 of the 57 (33%) epileptic dogs had fasting serum triglyceride concentrations greater than the upper reference limit. Nine (16%) dogs had a history of pancreatitis, and 5 of the 9 had high fasting serum triglyceride concentrations at the time of the study. A significant relationship was found between body condition score and fasting serum triglyceride concentration in all dogs, but serum triglyceride concentration was not significantly associated with phenobarbital dosage or serum phenobarbital concentration. CONCLUSIONS AND CLINICAL RELEVANCE: Results suggested that dogs treated long term with phenobarbital or with phenobarbital and bromide may develop hypertriglyceridemia. Fasting serum triglyceride concentration should be periodically monitored in dogs treated with phenobarbital because hypertriglyceridemia is a risk factor for pancreatitis.     

Pharmacokinetics of phenobarbital in the horse

Pharmacokinetics of phenobarbital was examined in 6 mature horses after 12 mg of phenobarbital/kg of body weight was infused over 20 minutes. Biexponential decrease in serum phenobarbital concentrations was observed with a distribution-phase half-life of 0.101 +/- 0.086 hour (mean +/- SD) and a terminal-phase elimination half-life of 18.3 +/- 3.65 hours. The volume of distribution at steady state was 0.803 +/- 0.070 L/kg. Total body clearance of phenobarbital was 30.8 +/- 6.2 ml/h/kg. The high clearance in the horse seems to explain the markedly shorter half-life of phenobarbital in this species. Seemingly, 6.65 mg of phenobarbital/kg as a 20-minute infusion given every 12 hours would provide approximate peaks of 29 micrograms/ml and troughs of 15 micrograms/ml. A loading dose of 12 mg of phenobarbital/kg would be appropriate for this regimen.     

Therapeutic efficacy of phenobarbital and primidone in canine epilepsy: a comparison

The efficacy of phenobarbital and primidone against canine epilepsy was compared in a controlled study. Thirty-five dogs showing generalized tonic-clonic seizures (grand mal), treated for a minimum of 6 months, were included in the study; fifteen of these were treated with phenobarbital, the other twenty with primidone. Both drugs were dosed according to the clinical requirement; the daily doses ranged from 5-17 mg/kg phenobarbital and from 17-70 mg/kg primidone. The plasma concentrations of phenobarbital, or of primidone and its metabolites phenobarbital and phenylethylmalondiamide (PEMA), were routinely monitored. Complete control of tonic-clonic seizures for 6 months, at least, was attained in six out of fifteen dogs of the phenobarbital group, and in five out of twenty dogs in the primidone group. A further six dogs on phenobarbital, and seven dogs on primidone, were classified as 'improved', i.e. the rate of seizures was reduced by at least 50%. The rest of the dogs were not improved by the treatment. The difference between the efficacy of phenobarbital and primidone was not significant, but primidone gave rise to signs of liver toxicity in fourteen out of twenty dogs, as indicated by considerable elevations of liver enzyme values (alanine transferase, glutamate dehydrogenase, alkaline phosphatase). Phenobarbital is, therefore, regarded as the drug of first choice for the treatment of canine epilepsy.     

苯巴比妥多克隆抗体的制备及其免疫学特性鉴定

苯巴比妥（Phenobarbital, PB）具有神经、骨髓、致畸、致癌等毒性作用,其在动物性食品中的残留严重危害着人们的健康,我国和世界上多数国家禁止PB用于食品动物.免疫学分析方法用于PB残留检测以其灵敏、快速、特异、简便等优点替代了传统的理化检验方法,美国雅培公司和德国Dade Behring公司已开发出相关产品.合格的抗体是建立免疫学分析方法的基础,关于PB多克隆抗体（pAb）的制备国内尚未见报道.本研究旨在制备出高价、敏感、特异的PB pAb,为免疫学检测方法的建立奠定基础。     

Pharmacokinetics of phenobarbital in dogs given multiple doses

Studies were conducted to examine the temporal changes in phenobarbital pharmacokinetics during chronic dosing in dogs. Ten dogs were allotted into 2 groups, administered a single oral dose, rested for 35 days, and then given the drug for 90 consecutive days. After single administration of 5.5 mg/kg of body weight or 15 mg/kg, the total body clearance (Clt/F) was 5.58 +/- 1.89 ml/h/kg and 7.28 +/- 1.07 ml/h/kg, respectively. The half-lives (t1/2) for the 2 groups were 88.7 +/- 19.6 hours for the 5.5-mg/kg dose and 99.6 +/- 22.6 hours for the 15-mg/kg dose. Significant differences in Clt/F or t1/2 were not observed between the 2 groups. Multiple-dosing regimens (5.5 mg/kg/day or 11 mg/kg/day) were initiated in the same dogs for 90 days. The Clt/F was significantly (P less than 0.05) greater on days 30, 60, and 90 than the single dose for both groups. After the last dose on day 90, several blood samples were obtained to determine phenobarbital t1/2. On day 90, the t1/2 was significantly (P less than 0.05) shorter and the Clt/F was significantly greater than single-dose values. The Clt/F and t1/2 were 10.2 +/- 1.7 ml/h/kg and 47.3 +/- 10.7 hours for the group given the low dose and 15.6 +/- 2.5 ml/h/kg and 31.1 +/- 4.4 hours for the group given the high dose, respectively. Both Clt/F and t1/2 were significantly (P less than 0.05) different between the 2 groups on day 90.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of phenobarbital on thiopental pharmacokinetics in greyhounds

The effects of phenobarbital on the pharmacokinetics of thiopental (15 mg/kg IV) were investigated in 12 trained racing Greyhounds. Phenobarbital (16 mg/kg of body weight, PO, q 24 h), administered for 14 days, reduced the area under the curve of plasma concentration of thiopental vs time from 10,688 micrograms.min/ml to 3,224 micrograms.min/ml. Furthermore, the time to recovery from anesthesia (ie, return to standing position) decreased from 103 minutes to 35.7 minutes after phenobarbital. These effects were attributed to an increase in the metabolic clearance of thiopental, as a result of induction of liver enzyme activity by phenobarbital. These results suggested that hepatic metabolism, in addition to distribution, is a factor that must be considered when assessing the difference in drug disappearance rates between Greyhounds and other breeds of dogs.     

Transient leucopenia, thrombocytopenia and anaemia associated with severe acute phenobarbital intoxication in a dog

A nine-year-old Labrador retriever dog was admitted to the emergency unit of the Hebrew University Veterinary Teaching Hospital with acute-onset tremors and coma. It had recently ingested a large quantity of phenobarbital and had a high serum phenobarbital concentration. On this basis, a diagnosis of acute phenobarbital intoxication was made. Significant leucopenia, thrombocytopenia and mild anaemia developed on the third day after admission. The leucopenia resolved on day 6 and the thrombocytopenia on day 13. The red blood cell count remained low for the next month. The dog was discharged on day 13 at which time it was ambulatory but weak. It was completely recovered clinically eight days later. In summary, high levels of serum phenobarbital as a result of acute intoxication induced pancytopenia, which improved when the serum phenobarbital level was normalised.     

Pharmacokinetics and interactions of digoxin with phenobarbital in dogs

In one experiment, 5 dogs were administered digoxin (0.022 mg/kg of body weight, IV), were rested for 2 weeks, were then given phenobarbital (13.2 mg/kg orally) for 14 days, and then were given digoxin again (0.022 mg/kg, IV). Comparing prephenobarbital (control) digoxin half-lives of 42.4 +/- 8.8 hours and postphenobarbital digoxin half-lives of 18.0 +/- 2.2 hours, the half-life was significantly (P less than 0.05) decreased after phenobarbital administration. Clearance was increased by 84%, and the volume of distribution given was decreased by 34%. In a second experiment, 5 dogs were given digoxin (0.022 mg/kg, orally) daily for 11 days, and the digoxin kinetics were evaluated after the last dosing. The dogs were then rested and given phenobarbital (13.2 mg/kg, orally) once daily for 14 days and digoxin (0.022 mg/kg) once daily for 11 days, and the pharmacokinetics of digoxin was determined on the last day of dosing. Significant differences in steady-state serum concentrations and the pharmacokinetics of digoxin were not found between the control and phenobarbital phases of the experiment. Mean (+/- SD) half-lives of digoxin were 29.0 +/- 7.2 hours before phenobarbital treatment (control) and were 34.8 +/- 7.2 hours after phenobarbital treatment. In comparing results of the single-dose experiment vs the oral multiple-dose experiment, dogs had shorter half-lives for digoxin after multiple dosing. Therefore, if phenobarbital and digoxin are to be chronically coadministered orally, an adjustment in the digoxin dose is not necessary.     

苯巴比妥的毒副作用及其残留检测

本文就苯巴比妥(PB)的化学结构、理化特性、构效关系、毒副作用、在动物体内的代谢残留以及检测方法等进行详尽阐述。     

Efficacy of primidone in dogs with seizures unresponsive to phenobarbital

Fifteen epileptic dogs had been treated with high dosages of phenobarbital but had not achieved adequate control of their seizures. Their treatment was switched to comparable and higher dosages of primidone. Serum concentrations of phenobarbital were measured in all dogs before and after primidone therapy was initiated, to ensure that the primidone dosage achieved comparable or higher values when derived from primidone. Only one dog experienced improvement in seizure control, indicating that there is no advantage to the use of primidone over the use of phenobarbital for the control of seizures in most 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.     

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.