Effects of phenobarbital treatment on serum thyroxine and thyroid-stimulating hormone concentrations in epileptic dogs.

OBJECTIVE: To determine whether phenobarbital treatment of epileptic dogs alters serum thyroxine (T4) and thyroid-stimulating hormone (TSH) concentrations. DESIGN: Cross-sectional study. ANIMALS: 78 epileptic dogs receiving phenobarbital (group 1) and 48 untreated epileptic dogs (group 2). PROCEDURE: Serum biochemical analyses, including T4 and TSH concentrations, were performed for all dogs. Additional in vitro analyses were performed on serum from healthy dogs to determine whether phenobarbital in serum interferes with T4 assays or alters free T4 (fT4) concentrations. RESULTS: Mean serum T4 concentration was significantly lower, and mean serum TSH concentration significantly higher, in dogs in group 1, compared with those in group 2. Thirty-one (40%) dogs in group 1 had serum T4 concentrations less than the reference range, compared with 4 (8%) dogs in group 2. All dogs in group 2 with low serum T4 concentrations had recently had seizure activity. Five (7%) dogs in group 1, but none of the dogs in group 2, had serum TSH concentrations greater than the reference range. Associations were not detected between serum T4 concentration and TSH concentration, age, phenobarbital dosage, duration of treatment, serum phenobarbital concentration, or degree of seizure control. Signs of overt hypothyroidism were not evident in dogs with low T4 concentrations. Addition of phenobarbital in vitro to serum did not affect determination of T4 concentration and only minimally affected fT4 concentration. CONCLUSIONS AND CLINICAL RELEVANCE: Clinicians should be aware of the potential for phenobarbital treatment to decrease serum T4 and increase TSH concentrations and should use caution when interpreting results of thyroid tests in dogs receiving phenobarbital.     

Serum total thyroxine, total triiodothyronine, free thyroxine, and thyrotropin concentrations in epileptic dogs treated with anticonvulsants.

OBJECTIVE: To determine whether administration of phenobarbital, potassium bromide, or both drugs concurrently was associated with abnormalities in baseline serum total thyroxine (T4), triiodothyronine (T3), free T4, or thyrotropin (thyroid-stimulating hormone; TSH) concentrations in epileptic dogs. DESIGN: Prospective case series. ANIMALS: 78 dogs with seizure disorders that did not have any evidence of a thyroid disorder (55 treated with phenobarbital alone, 15 treated with phenobarbital and bromide, and 8 treated with bromide alone) and 150 clinically normal dogs that were not receiving any medication. PROCEDURE: Serum total T4, total T3, free T4, and TSH concentrations, as well as serum concentrations of anticonvulsant drugs, were measured in the 78 dogs with seizure disorders. Reference ranges for hormone concentrations were established on the basis of results from the 150 clinically normal dogs. RESULTS: Total and free T4 concentrations were significantly lower in dogs receiving phenobarbital (alone or with bromide), compared with concentrations in clinically normal dogs. Administration of bromide alone was not associated with low total or free T4 concentration. Total T3 and TSH concentrations did not differ among groups of dogs. CLINICAL IMPLICATIONS: Results indicate that serum total and free T4 concentrations may be low (i.e., in the range typical for dogs with hypothyroidism) in dogs treated with phenobarbital. Serum total T3 and TSH concentrations were not changed significantly in association with phenobarbital administration. Bromide treatment was not associated with any significant change in these serum thyroid hormone concentrations.     

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.     

Therapeutic serum concentrations of primidone and its metabolites, phenobarbital and phenylethylmalonamide in epileptic dogs

Fifteen dogs with idiopathic epilepsy were included in a 9-month clinical trial to determine the therapeutic serum concentrations of primidone and its active metabolites, phenobarbital and phenylethylmalonamide. Dogs with a seizure frequency greater than 1/mo or with a record of multiple seizures greater than 1/day were chosen for the study. Each dog was given primidone 3 times daily at dosages intended to maximize seizure control and to minimize undesired side effects. Maintenance period blood samples were taken from fasted dogs 7 hours after dosing in the 3rd, 5th, 7th, and 9th months of the trial to determine therapeutic serum concentrations of primidone and its metabolites. Two blood samples also were taken from all dogs 7 hours after dosing, during an enforced drowsy period, to establish upper limits of desirable serum concentrations of the drug. Seizure frequencies during the trial were controlled in 13 dogs, 7 of which had no seizures during the 9-month trial. The mean percentage reduction in seizure frequency from pretrial frequency was 85%. Two dogs appeared refractory to primidone therapy. Serum phenobarbital was the best metabolite of primidone to use to assess therapeutic serum concentrations. The therapeutic antiepileptic serum concentration of phenobarbital was found to be between 25 and 40 micrograms/ml of serum. Serum phenobarbital concentrations greater than 40 micrograms/ml resulted in side effects in most dogs.     

Changes in serum thyroxine and thyroid-stimulating hormone concentrations in epileptic dogs receiving phenobarbital for one year

A multicentric prospective study was conducted to monitor the effect of phenobarbital on serum total thyroxine (T4) and thyroid-stimulating hormone (TSH) concentrations in epileptic dogs. Serum T4 concentrations were determined for 22 epileptic dogs prior to initiation of phenobarbital therapy (time 0), and 3 weeks, 6 months, and 12 months after the start of phenobarbital. Median T4 concentration was significantly lower at 3 weeks and 6 months compared to time 0. Thirty-two percent of dogs had T4 concentrations below the reference range at 6 and 12 months. Nineteen of the 22 dogs had serum TSH concentrations determined at all sampling times. A significant upward trend in median TSH concentration was found. No associations were found between T4 concentration, dose of phenobarbital, or serum phenobarbital concentration. No signs of overt hypothyroidism were evident in dogs with low T4, with one exception. TSH stimulation tests were performed on six of seven dogs with low T4 concentrations at 12 months, and all but one had normal responses. In conclusion, phenobarbital therapy decreased serum T4 concentration but did not appear to cause clinical signs of hypothyroidism. Serum TSH concentrations and TSH stimulation tests suggest that the hypothalamic-pituitary-thyroid axis is functioning appropriately.     

Hepatotoxicity of phenobarbital in dogs: 18 cases (1985-1989).

The medical records of 18 dogs that had hepatic disease and received phenobarbital as an anticonvulsant for 5 to 82 months were reviewed. Clinical signs included sedation and ataxia in all dogs, 5 dogs were also anorectic, 2 had coagulopathy, 3 were icteric, and 5 had ascites. Serum biochemical analysis revealed serum albumin concentration less than or equal to 2.2. g/dl in 12 dogs, serum alkaline phosphatase activity greater than or equal to 169 U/L in 18 dogs, serum alanine transaminase activity greater than or equal to 57 U/L in 15 dogs, and total bilirubin concentration greater than or equal to 1 mg/dl (in the absence of lipemia) in 7 dogs. Serum phenobarbital concentration was greater than or equal to 40 micrograms/ml in 12 of 17 dogs. Sulfobromophthalein excretion was prolonged in 8 of 10 dogs. Preprandial serum bile acid concentrations were high in 8 of 10 dogs, and 2-hour postprandial serum bile acid concentrations were high in 9 of 10 dogs. Two of 4 dogs tested had resting plasma ammonia concentrations greater than 200 mg/dl. An ammonia tolerance test was performed on 2 other dogs; both had ammonia concentration greater than or equal to 200 mg/dl in the plasma 30 minutes after receiving 100 mg of ammonium chloride/kg of body weight, PO. Nine dogs died, 1 was euthanatized, and necropsies were performed on these 10 dogs. Biopsies and necropsies of 6 dogs revealed chronic hepatic fibrosis with nodular regeneration (cirrhosis). One dog had hepatocellular carcinoma and mild cirrhosis. In 1 dog, after phenobarbital had been withheld, necropsy revealed complete recovery of the previously observed lesions.     

Low concentrations of cerebrospinal fluid GABA correlate to a reduced response to phenobarbital therapy in primary canine epilepsy

In this study, we investigated whether pretreatment cerebrospinal fluid (CSF) neurotransmitter concentrations of gamma-aminobutyric acid (GABA) and glutamate (GLU) were correlated with response to phenobarbital treatment in dogs with primary epilepsy. Eleven untreated dogs, 6 males and 5 females, with a median age of onset of seizures of 3 years (range: 0.5-5 years) were selected for therapy based on progressive or serious seizure patterns. The median interval between the first observed seizure and start of phenobarbital therapy was 485 days (range: 101-1,765 days). All dogs were purebred, with the exception of I male dog. Oral phenobarbital was started at 2.5 mg/kg every 12 hours. Trough serum phenobarbital concentrations were measured at 15, 45, 90, 180, 360, 540, and 720 days after the start of treatment. There was no difference in the mean trough serum concentration or in the mean number of seizures recorded between each time period of phenobarbital measurement over the 2-year evaluation. No correlation was found between CSF GLU, GABA, or GLU: GABA ratio and the total number of seizures recorded before or after initiation of phenobarbital therapy. Lower CSF GABA concentration, however, was correlated with a lower seizure frequency difference (the total number of seizures before phenobarbital therapy minus the total number of seizures after phenobarbital therapy for an identical time period of evaluation) and lower percentage reduction in seizures: ([total number of seizures before phenobarbital therapy minus the total number of seizures after phenobarbital therapy] divided by the total number of seizures before phenobarbital therapy) x 100. There was no correlation between CSF GLU and the seizure frequency difference and percentage reduction in seizures. A negative correlation between the CSF GLU:GABA ratio and seizure frequency difference was found. Thus, dogs with an initial lower CSF GABA concentration before phenobarbital therapy did not respond as well as did dogs with a higher CSF GABA concentration.     

Serum salicylate concentrations and endoscopic evaluation of the gastric mucosa in dogs after oral administration of aspirin-containing products

The serum salicylate concentration produced by oral administration of plain aspirin and several aspirin-containing products given at 8-hour intervals for 7 treatments was measured in 36 laboratory-conditioned adult dogs. The dogs were randomly allotted to 6 groups of 6 dogs each: group 1 was given plain aspirin at a dosage of 25 mg/kg of body weight: group 2 was given plain aspirin at a dosage of 10 mg/kg; group 3 was given buffered aspirin at a dosage of 25 mg/kg; group 4 was given enteric-coated aspirin at a dosage of 25 mg/kg; group 5 was given buffered aspirin at a dosage of 25 mg/kg; and, group 6 was given a placebo. Serum salicylate concentration was measured at 2-hour intervals for the first 8 hours, and then at 8-hour intervals for the next 40 hours. Following the last dosing, serum salicylate concentration was measured at 2-hour intervals until 56 hours; the final 2 samples were measured at 64 and 72 hours. The effect of aspirin on the gastric mucosa was studied in 12 dogs, 3 each randomly selected from groups 1, 3, 4, and 5. The gastric mucosa of each dog was examined with a fiberoptic gastroscope 3 days before the beginning of treatment; lesions were not seen. The drugs were administered as described and the gastric mucosa of each dog was reexamined at 72 hours. Administration of the aspirin-containing products at 8-hour intervals resulted in sustained therapeutic serum salicylate concentrations (greater than 5 mg/dl) in all dogs, except those of group 2. The greatest fluctuation in serum salicylate concentration was found in dogs of group 4. Gastric lesions were seen only in the 3 dogs of group 1.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Assessment of the use of plasma and serum chloride concentrations as indirect predictors of serum bromide concentrations in dogs with idiopathic epilepsy

BACKGROUND: Bromide (BR) administration causes pseudohyperchloremia when plasma or serum chloride (Cl-) concentrations are determined with commonly available automated analytical assays. In humans receiving BR, it has been previously demonstrated that the plasma Cl- concentration is a useful indirect estimator of the measured BR concentration. OBJECTIVE: The objective of this study was to determine if the magnitude of pseudohyperchloremia seen in epileptic dogs treated with BR could be used as a predictor of the measured serum BR concentration. METHODS: Plasma and serum Cl- concentrations, analyzed by ion-specific electrode (ISE) and colorimetric techniques, and serum BR concentrations, determined using the gold-trichloride assay, were simultaneously determined in 88 blood samples from dogs with idiopathic epilepsy that were treated with BR. RESULTS: For all methods used to quantify Cl- concentrations, there were significant (P < .0001) linear relationships between BR and Cl- concentrations. Linear relationships between BR and Cl- concentrations were significantly different (P < .0001) between blood samples from dogs obtained during routine therapeutic monitoring and those obtained during emergency hospital admissions. Calculated 95% prediction intervals for future values of BR using measured Cl- concentrations contained considerable error. Plasma Cl- values determined with ISE generally provided the best prediction of serum BR concentrations. Agreement between the measured BR and Cl- using all Cl- assay techniques was moderate, but was statistically significant only when Cl- was assayed in plasma using one ISE method. CONCLUSIONS: The pseudohyperchloremia observed in epileptic dogs receiving BR is an inadequate indirect estimator for the measured BR concentration, although in certain clinical situations identified through construction of a clinical decision tree, the measured Cl- value can be used to guide general therapeutic decisions regarding alterations in BR therapy. Optimal tailoring of BR therapy in dogs with idiopathic epilepsy should be based on results of therapeutic monitoring of BR concentrations.     

Serum alkaline phosphatase isoenzyme profiles in phenobarbital-treated epileptic dogs

BACKGROUND: Serum total alkaline phosphatase (AP) activity commonly is high in dogs receiving phenobarbital. Specific isoenzymes responsible for this increase are not well documented. OBJECTIVES: The purposes of this study were 1) to qualitatively and quantitatively describe serum AP isoenzymes in phenobarbital-treated dogs and 2) to monitor changes in serum AP isoenzyme activities associated with phenobarbital treatment over time. METHODS: Serum AP isoenzyme activities were determined in a cross-sectional study of 29 dogs receiving phenobarbital (duration of treatment 2 months to 6.5 years). Additionally, in a prospective study of 23 dogs, serum AP isoenzyme activities were determined before and 3 weeks, 6 months, and 12 months after the start of phenobarbital treatment. Isoenzyme activities were quantitatively determined using wheat germ lectin precipitation and levamisole inhibition, and qualitatively (ie, present or absent) evaluated using cellulose acetate affinity electrophoresis. RESULTS: In phenobarbital-treated dogs with high serum total AP activity in the cross-sectional study, the increase was due predominantly to increased activities of the corticosteroid-induced (C-AP) and liver (L-AP) isoenzymes. Prospectively, serum total AP and L-AP activities were significantly higher at 3 weeks, 6 months, and 12 months after the start of phenobarbital treatment compared with pretreatment values. Serum C-AP and bone isoenzyme (B-AP) activities were significantly higher after 6 and 12 months of treatment. B-AP accounted for only a small amount of the total AP activity. No unusual or previously unidentified AP isoenzymes were identified. CONCLUSIONS: Phenobarbital treatment was associated with increased C-AP and L-AP isoenzyme activities and with a minor increase in B-AP activity. No unique "phenobarbital-induced" isoenzyme was identified. Isoenzyme analysis does not appear to be useful for differentiating between high serum total AP due to phenobarbital therapy and other causes.     

Radioimmunoassay monitoring of thyroid hormone concentrations in dogs on thyroid replacement therapy: 2,674 cases (1985-1987).

Serum iodothyronine concentrations from 4,064 samples submitted for monitoring of thyroid replacement therapy were evaluated in a retrospective study. After exclusion of samples because of the presence of 3,5,3' triiodothyronine (T3) autoantibodies, insufficient numbers of dogs on some commercial preparations or medication with corticosteroids or synthetic T3 preparations, data from 2,674 dogs remained. Data were analyzed by using information on dose, time after dosing, commercial product, and once-a-day or twice-a-day dosing regimens. Serum total thyroxine (T4) and total T3 and estimates of free T4 and free T3 were significantly high in serum from dogs given higher doses of synthetic L-thyroxine orally. Doubling the oral dosage did not double the serum iodothyronine concentrations, perhaps because of poor absorption or more rapid catabolism of the hormones at higher L-thyroxine doses. Wide variation in the therapeutic hormone concentrations was found. Some dogs given low dosages of L-thyroxine had normal iodothyronine concentrations whereas some others given higher dosages had low normal to low concentrations. Monitoring the serum concentrations is an objective way to ensure adequate concentrations for successful therapy. When a therapeutic trial is used as a diagnostic procedure, one should not rule out hypothyroidism unless a therapeutic monitoring sample has indicated that replacement dose and absorption of the exogenous iodothyronine has been adequate. Thyroid hormone concentrations peaked at 4 to 6 hours after oral administration of L-thyroxine for once-a-day and twice-a-day dosage regimens. Higher concentrations were achieved with once-a-day than with twice-a-day regimens at the same total daily dose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of enrofloxacin on digoxin clearance and steady-state serum concentrations in dogs.

The effect of enrofloxacin on the oral clearance and steady-state concentrations of digoxin in serum was evaluated in dogs. Digoxin was administered orally to six healthy adult Beagle dogs following a multiple-dose regimen of 0.0625 mg every 12 h for 23 days. From days 14 to 23 enrofloxacin was administered orally at a dosage of 2.5 mg/kg every 12 h, with subjects receiving enrofloxacin 2 h prior to digoxin. Trough serum concentrations of digoxin were measured using an immunoassay technique. On days 13 and 22, dogs were catheterized for multiple blood sample collection during the 12 h digoxin dosing interval and serum samples were analyzed for digoxin concentrations. In general, steady-state digoxin concentrations in trough serum were not significantly different during enrofloxacin treatment than before enrofloxacin administration. Similarly, digoxin oral clearance was not significantly different between pre-enrofloxacin and digoxin + enrofloxacin periods. We conclude that enrofloxacin is unlikely to have a significant impact on digoxin disposition in dogs.     

Dosing regimen and hematologic effects of pentoxifylline and its active metabolites in normal dogs

The disposition of pentoxifylline and two of its active metabolites (metabolite 1 [M1] and metabolite 5 [M5]) were studied following i.v. (8 mg/kg) and p.o. (30 mg/kg) administration to eight normal dogs using a randomized crossover design. Blood samples were collected at fixed time intervals after drug administration for determination of drug concentrations, platelet aggregation, and plasma fibrinogen. Complete blood counts, serum chemistry profiles, fibrinogen, and urinalysis were monitored at the beginning and end of each phase of the study (p.o. versus i.v. administration). Pentoxifylline was readily metabolized and bioavailable (50% +/- 26%). Both M1 and M5 were present throughout the study, with M5 predominating. Human drug therapeutic concentrations (1,000 ng/ml) were present for 170 +/- 24 minutes following i.v. administration and 510 +/- 85 minutes after p.o. dosing. These findings suggest that a 12-hour dosing regimen is appropriate. None of the dogs experienced any adverse effects after pentoxifylline administration. The lack of hematologic effects suggests that the immunologic effects of pentoxifylline may be of more importance in dogs.     

Efficacy and Toxicity of Tocainide for the Treatment of Ventricular Tachyarrhythmias in Doberman Pinschers With Occult Cardiomyopathy

Tocainide was administered to 23 cardiomyopathic Doberman Pinschers at doses of 15 to 25 mg/kg tid. These doses produced peak (2–hour) serum concentrations of 6.2 to 19.1 mg/L and trough (8–hour) serum concentrations of 2.3 to 11.1 mg/L. Anorexia and gastrointestinal disturbances occurred in 8 dogs (35%) at doses (15.6 to 25.0 mg/kg) that were not different from those (16.0 to 26.0 mg/kg) received by dogs that did not experience toxicity. Doses producing peak serum concentrations that were either greater or less than 14 mg/L were not different. Likewise, doses producing trough values that were either greater or less than 6 mg/L were not different. The mean dose that produced peak serum concentrations of 10 to 13.6 mg/L and trough concentrations of 4.2 to 10.0 mg/L was 17.9 mg/kg, and was associated with anorexia in 4 dogs. Mean peak serum concentrations associated with toxicity (14.4 mg/L) were significantly higher ( P = .02) than dogs not experiencing toxicity (11.8 mg/L). Serious adverse effects occurred in 7 of 12 dogs (58%) receiving tocainide for longer than 4 consecutive months. Progressive corneal endothelial dystrophy occurred in 3 dogs. Although a causal effect could not be proven, 6 dogs experienced renal dysfunction during treatment. Drug doses in these 7 dogs were similar to those received by other dogs. At least a 70% reduction of the total numbers of ventricular premature contractions occurred in 80% of dogs treated, and ventricular tachycardia was eliminated in 90% of affected dogs by the time of the first post-treatment Holter recording. Long-term control of ventricular tachyarrhythmias was difficult to achieve in some dogs when the left ventricular shortening fraction was less than approximately 17%. J Vet Intern Med 1996;10:235–240. Copyright © 1996 by the American College of Veterinary Internal Medicine .     

Comparison of serum and renal gentamicin concentrations with fractional urinary excretion tests as indicators of nephrotoxicity

Gentamicin was given to six sheep at a dosage rate of 80 mg/kg/day divided into three daily doses to cause nephrotoxicity. Peak serum gentamicin concentrations rose significantly throughout dosing (P less than 0.05), but trough serum gentamicin concentrations increased dramatically (P less than 0.01) from initial concentrations of 3.2-9.1 micrograms/ml to final trough concentrations of 31.5-195 micrograms/ml by 6-10 days on gentamicin. The serum gentamicin elimination half-life (t1/2) was doubled in each animal by approximately 6 days on therapy, with the sheep that were the most clinically affected by the nephrotoxic effects of gentamicin showing increases in t1/2 earlier than those sheep that remained less intoxicated. These changes occurred before many other clinical indicators of nephrotoxicity, with only urinary enzyme excretions preceding the changes in gentamicin elimination. Thus, alterations in the elimination of gentamicin may be one of the first clinical indicators of the occurrence of gentamicin-induced nephrotoxicity.     

Short-term influence of prednisone and phenobarbital on thyroid function in euthyroid dogs.

The short-term effects of prednisone and phenobarbital on serum total thyroxine (tT4), free thyroxine (fT4), and thyroid stimulating hormone (TSH) were evaluated in euthyroid dogs. Twenty-six beagles were randomly divided into 3 groups receiving, respectively, a placebo, prednisone (1.2 to 2 mg/kg body weight, per os, every 12 hours for 3 weeks), or phenobarbital (1.8 to 3 mg/kg body weight for 1 week, then 2.7 to 4.5 mg/kg body weight, per os, every 12 hours for 2 weeks). Blood samples taken over a 6-week period were assayed for serum tT4, fT4, and TSH. Phenobarbital therapy in our study did not affect serum tT4, fT4, or TSH concentrations. Prednisone therapy, however, significantly decreased serum tT4 and fT4, but did not affect serum TSH concentrations.     

Pharmacokinetics and toxicity of bromide following high-dose oral potassium bromide administration in healthy Beagles

The pharmacokinetics of a multidose regimen of potassium bromide (KBr) administration in normal dogs was examined. KBr was administered at 30 mg/kg p.o. q 12 h for a period of 115 days. Serum, urine, and cerebrospinal fluid (CSF) bromide (BR) concentrations were measured at the onset of dosing, during the accumulation phase, at steady-state, and after a subsequent dose adjustment. Median elimination half-life and steady-state serum concentration were 15.2 days and 245 mg/dL, respectively. Apparent total body clearance was 16.4 mL/day/kg and volume of distribution was 0.40 L/kg. The CSF:serum BR ratio at steady-state was 0.77. Dogs showed no neurologic deficits during maintenance dosing but significant latency shifts in waves I and V of the brainstem auditory evoked response were evident. Following a subsequent dose adjustment, serum BR concentrations of approximately 400 mg/dL were associated with caudal paresis in two dogs. Estimated half-life during the accumulation phase was shorter than elimination half-lives reported in other studies and was likely related to dietary chloride content. The range of steady-state concentrations achieved suggests individual differences in clearance and bioavailability between dogs. The described protocol reliably produced serum BR concentrations that are required by many epileptic patients for satisfactory seizure control.     

Prospective clinical evaluation of serum cardiac troponin T in dogs admitted to a veterinary teaching hospital

The purpose of this study was to measure serum cardiac troponin T (cTnT) with a commercially available human enzyme-linked immunoassay (ELISA) test in various groups of dogs, including those undergoing doxorubicin chemotherapy. Serum samples were obtained from 6 groups of dogs: (1) normal adult dogs (n = 15); (2) dogs with asymptomatic dilated cardiomyopathy (n = 5); (3) dogs with congestive heart failure (n = 10); (4) dogs with untreated neoplasia (n = 20); (5) dogs with skeletal muscle trauma (n = 10); and (6) dogs with neoplasia receiving doxorubicin chemotherapy (n = 4). One serum sample was obtained from each of the normal dogs, those with asymptomatic cardiomyopathy, those with congestive heart failure, and those with untreated neoplasia. Serum samples were obtained serially from the dogs that were undergoing doxorubicin chemotherapy; samples were collected before doxorubicin (30 mg/m2) administration and then 1, 5, 7, and 14 days after administration throughout 6 cycles for a cumulative total dose of 180 mg/m2. All normal dogs, dogs with untreated neoplasia, and dogs with asymptomatic dilated cardiomyopathy had cTnT concentrations below the lower limits of detection for the assay used (<0.05 ng/mL). Detectable concentrations of cTnT were found in 3 dogs with congestive heart failure and in 2 dogs with skeletal muscle trauma. Detectable concentrations also were found in both dogs that had received 180 mg/m2 of doxorubicin. We conclude that dogs with congestive heart failure and those with skeletal muscle trauma and dogs with neoplasia receiving high-dose doxorubicin chemotherapy may have increased serum cTnT concentration, which may be suggestive of myocardial damage.     

Steady-state pharmacokinetics of oral sustained-release morphine sulphate in dogs

The pharmacokinetics of steady-state oral sustained-release morphine sulphate (OSRMS) were studied in dogs. Beagles ( n = 6) were randomly assigned to one of two treatment groups. Treatments included 15 mg OSRMS every 8 h for 4 days, or 15 mg OSRMS every 12 h for 4 days. Serum samples, drawn at intervals for the final 24 h of drug administration were analysed for morphine concentration using radioimmunoassay. Pharmacokinetic analysis revealed that there were no significant differences between trough serum concentrations for the concentration–time curves within either treatment group, indicating that steady-state pharmacokinetics had been achieved. There were no significant differences in time to maximum serum concentration among the three sections of the concentration–time curve for the 8-h group or between the two sections of the curve for the 12-h group. Area under the concentration–time curve and maximum serum concentrations were significantly greater for the section of the curve following dosing at 7:30 h than following dosing at 19:30 h in the 12-h treatment group. This chronopharmacokinetic variability was not present in the 8-h treatment group. OSRMS provides sustained periods of elevated serum concentrations following administration every 8 or 12 h at a clinically applicable dosage. The clinical implications of the chronopharmacokinetic variability seen with 12-hourly administration are not known. This formulation has potential for the treatment of chronic pain in dogs, but further studies of efficacy and safety following long-term administration are required.