Serum and skin concentrations after multiple-dose oral administration of trimethoprim-sulfadiazine in dogs.

Six healthy adult mixed breed dogs were each given 5 oral doses of trimethoprim (TMP)/sulfadiazine (SDZ) at 2 dosage regimens: 5 mg of TMP/kg of body weight and 25 mg of SDZ/kg every 24 hours (experiment 1) and every 12 hours (experiment 2). Serum and skin concentrations of each drug were measured serially throughout each experiment and mean serum concentrations of TMP and SDZ were determined for each drug for 24 hours (experiment 1) and 12 hours (experiment 2) after the last dose was given. In experiment 1, mean serum TMP concentration was 0.67 +/- 0.02 micrograms/ml, and mean skin TMP concentration was 1.54 +/- 0.40 micrograms/g. Mean serum SDZ concentration was 51.1 +/- 12.2 micrograms/ml and mean skin SDZ concentration was 59.3 +/- 9.8 micrograms/g. In experiment 2, mean serum TMP concentration was 1.24 +/- 0.35 micrograms/ml and mean skin TMP concentration was 3.03 +/- 0.54 micrograms/g. Mean serum SDZ concentration was 51.6 +/- 9.3 micrograms/ml and mean skin SDZ concentration was 71.1 +/- 8.2 micrograms/g. After the 5th oral dose in both experiments, mean concentration of TMP and SDZ in serum and skin exceeded reported minimal inhibitory concentrations of TMP/SDZ (less than or equal to 0.25/4.75 micrograms/ml) for coagulase-positive Staphylococcus sp. It was concluded that therapeutically effective concentrations in serum and skin were achieved and maintained when using the manufacturer's recommended dosage of 30 mg of TMP/SDZ/kg (5 mg of TMP/kg and 25 mg of SDZ/kg) every 24 hours.     

Serum and tissue fluid norfloxacin concentrations after oral administration of the drug to healthy dogs

Norfloxacin, a 4-quinolone antibiotic, was administered orally to 4 healthy dogs at dosages of 11 and 22 mg/kg of body weight, every 12 hours for 4 days, with a 4-week interval between dosing regimens. Serum and tissue cage fluid (TCF) norfloxacin concentrations were measured at 0, 0.5, 1, 1.5, 2, 3, 4, 5, 6, 8, 10, and 12 hours after the first and seventh dose of each dosing regimen. When administered at a dosage of 11 mg/kg, the mean peak serum concentration (Cmax) was 1.0 microgram/ml at 1 hour, the time of mean peak concentration (Tmax) after the first dose. After the seventh dose, the Cmax was 1.4 micrograms/ml at Tmax of 1.5 hours. The Tmax for the TCF concentration was 5 hours, with Cmax of 0.3 microgram/ml and 0.7 microgram/ml after the first and seventh dose, respectively. When administered at a dosage of 22 mg/kg, the serum Tmax was 2 hours after the first dose, with Cmax of 2.8 micrograms/ml. After the seventh dose, the serum Tmax was 1.5 hours, with Cmax of 2.8 micrograms/ml. The Tmax for the TCF concentration was 5 hours after the first and seventh doses, with Cmax of 1.2 micrograms/ml and 1.6 micrograms/ml, respectively. After the seventh dose, the serum elimination half-life was 6.3 hours for a dosage of 11 mg/kg and was 6.7 hours for a dosage of 22 mg/kg. For serum concentration, the area under the curve from 0 to 12 hours (AUC0----12) was 8.77 micrograms.h/ml and 18.27 micrograms.h/ml for dosages of 11 mg/kg and 22 mg/kg, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Serum and tissue cage fluid concentrations of ciprofloxacin after oral administration of the drug to healthy dogs

Ciprofloxacin, a fluoroquinolone antimicrobial agent, was administered orally to 4 healthy dogs at dosage of approximately 11 and 23 mg/kg of body weight, every 12 hours for 4 days, with a 4-week interval between dosing regimens. Serum and tissue cage fluid (TCF) concentrations of ciprofloxacin were measured after the first and seventh dose of each dosing regimen. The peak concentration was greatest in the serum after multiple doses of 23 mg/kg (mean +/- SEM; 5.68 +/- 0.54 micrograms/ml) and least in the TCF after a single dose of 11 mg/kg (0.43 +/- 0.54 micrograms/ml). The time to peak concentration was not influenced by multiple dosing or drug dose, but was longer for TCF (6.41 +/- 0.52 hour) than for serum (1.53 +/- 0.52 hour). Accumulation of ciprofloxacin was reflected by the area under the concentration curve from 0 to 12 hours after administration (AUC0----12). The AUC0----12 was greatest in the serum after multiple doses of 23 mg/kg (31.95 +/- 1.90 micrograms.h/ml) and least in the TCF after a single dose of 11 mg/kg (3.87 +/- 1.90 micrograms.h/ml). The elimination half-life was not influenced by multiple dosing or dose concentration, but was greater for TCF (14.59 +/- 1.91 hours) than for serum (5.14 +/- 1.91 hours). The percentage of TCF penetration (AUCTCF/AUCserum) was greater after multiple doses (95.76 +/- 6.79%) than after a single dose (55.55 +/- 6.79%) and was not different between doses of 11 and 23 mg/kg. Both dosing regimens of ciprofloxacin resulted in continuous serum and TCF concentrations greater than 90% of the minimal inhibitory concentration for the aerobic and facultative anaerobic clinical isolates tested, including Pseudomonas aeruginosa.     

Serum concentrations of buprenorphine after oral and parenteral administration in male mice

Buprenorphine is the most commonly used drug for peri-operative pain relief in laboratory rodents. The systemic concentrations of buprenorphine were measured in mice following administration intravenously (IV), subcutaneously (SC), orally by gavage and by voluntary ingestion, to determine the post-administration serum concentration of buprenorphine. Voluntarily ingested buprenorphine resulted in long-lasting high serum concentrations, as did oral gavage administration (24 h serum concentration: 110 ng h/mL for both routes of administration). In contrast, buprenorphine administered parenterally remained in the circulation for a substantially shorter time (24 h serum concentration for IV and SC were 40 ng h/mL and 30 ng h/mL, respectively). This marked difference was probably due to the higher dose used for oral administration, which is regarded necessary for sufficient analgesic effect, and to the slower absorption of the oral boli, as well as saturation of the hepatic buprenorphine metabolising pathways. Voluntary ingestion of buprenorphine was found to constitute a practical way to provide laboratory mice with efficient pain relief.     

Plasma salicylate concentrations in immature dogs following aspirin administration: comparison with adult dogs

Aspirin disposition in immature and adult dogs, assessed by plasma salicylate concentrations following single doses of aspirin given orally (p.o.) and intravenously (i.v.), was compared. Using a cross-over design, four immature (12–16-weeks-old) and eight adult (1– 2-years-old) dogs were given a single dose of aspirin at 17.5 mg/kg body weight i.v. and a single dose of buffered aspirin at 35 mg/kg body weight p.o. Blood was collected from the jugular vein for 24 h following each dose. A fluorescence polarization immunoassay was used for determination of salicylate in plasma. Significant differences in aspirin disposition were identified between the two groups. Immature dogs had significantly shorter salicylate half-life, lower mean residence time, and more rapid salicylate clearance than adult dogs. The difference in volume of distribution between the two groups was not significantly different. Immature dogs had lower mean (± SD) peak plasma salicylate concentrations (64.5 ± 2.38 mg/L) than adult dogs (95.9 ± 12.2 mg/L) following a single oral dose of buffered aspirin at 35 mg/kg body weight. Predicted plasma salicylate concentration-time curves were constructed for various aspirin dosage regimens. This analysis showed that the previously recommended buffered aspirin dose for adult dogs of 25 mg/kg body weight p.o. every 8 h would be ineffective in maintaining plasma salicylate concentrations > 50 mg/L in immature dogs.     

Serum digoxin concentrations in dogs before and during concomitant administration of furosemide

Healthy dogs were treated once a day for 16 days with a liquid, oral dosage form of digoxin (0.022 mg/kg). From day 9 to 16 they were also injected intramuscularly with furosemide (4.4 mg/kg). Serum digoxin was measured by a radioimmunoassay technique. Eight hours after the eighth dose of digoxin had been administered, serum digoxin concentration was in the accepted therapeutic range. After 8 days of concomitant administration of digoxin and furosemide, serum digoxin concentration was found to be in the accepted moderate-to-severe toxic range. Clinical signs of digitalis toxicosis were consistently observed during the combined digoxin-plus-furosemide treatment period. There was no significant ( P >0.05) change in the serum concentrations of potassium, sodium, or in osmolality during digoxin treatment alone. Serum creatinine concentrations remained within the accepted normal range for dogs. Serum sodium concentration was significantly ( P <0.05) lower during combined digoxin-plus-furosemide treatment when compared to digoxin treatment only.
Results indicate that an interaction between digoxin and furosemide occurred which led to significantly ( P <0.05) higher concentrations of serum digoxin during combined digoxin and furosemide treatment.     

Serum concentrations of thyroxine and 3,5,3'-triiodothyronine before and after intravenous or intramuscular thyrotropin administration in dogs

Response to thyrotropin (TSH) was evaluated in 2 groups of mixed-breed dogs. Thyrotropin (5 IU) was administered IV to dogs in group 1 (n = 15) and IM to dogs in group 2 (n = 15). Venous blood samples were collected immediately before administration of TSH and at 2-hour intervals for 12 hours thereafter. In group 1, the maximum mean concentration (+/- SD) of thyroxine (T4; 7.76 +/- 2.60 micrograms/dl) and 3,5,3'-triiodothyroxine (T3; 1.56 +/- 0.51 ng/ml) was attained at postinjection hours (PIH) 8 and 6, respectively. However, the mean concentration of T4 at PIH 6 (7.21 +/- 2.39 micrograms/dl) was not different (P greater than 0.05) from the mean concentration at PIH 8. The maximum mean concentration of T4 (10.10 +/- 3.50 micrograms/dl) and T3 (2.22 +/- 1.24 ng/ml) in group 2 was attained at PIH 12 and 10, respectively. Because dogs given TSH by the IM route manifested pain during injection, had variable serum concentrations of T3 after TSH administration, and may require 5 IU to achieve maximal increases in serum T4 concentrations, IV administration of TSH is recommended. The optimal sampling time to observe maximal increases in T3 and T4 after IV administration of TSH was 6 hours. Repeat IV administration of TSH may cause anaphylaxis and, therefore, is not recommended.     

Pharmacokinetics of marbofloxacin in dogs after oral and parenteral administration

Six dogs were treated with a single intravenous (i.v.) dose (2 mg/kg) of marbofloxacin, followed by single oral (p.o.) doses of marbofloxacin at 1, 2 and 4 mg/kg, according to a three-way crossover design. The same experimental design was used for the subcutaneous (s.c.) route. In addition, a long-term trial involving eight dogs given oral doses of marbofloxacin at 2, 4 and 6 mg/kg/day for thirteen weeks was carried out. Plasma and urine samples were collected during the first two trials, plasma and skin samples were collected after the second of these trials. Plasma, urine and skin concentrations of marbofloxacin were determined by a reverse phase liquid chromatographic method. Mean pharmacokinetic parameters after i.v. administration were the following: t1/2β=12.4h; Cl _B= 0.10 L/h.kg; V _area= 1.9 L/kg. The oral bioavailability of marbofloxacin was close to 100% for the three doses. At 2 mg/kg, C _max of 1.4 μg/mL was reached at t _max of 2.5 h. Mean AUC and C _max values had a statistically significant linear relationship with the doses administered. About 40% of the administered dose was excreted in urine as unchanged parent drug. After s.c. administration, the calculated parameters were close to those obtained after oral administration, except t _max (about 1 h) which was shorter. The mean skin to plasma concentration ratio after the long-term trial was 1.6, suggesting good tissue penetration of marbofloxacin.     

Pharmacokinetics of pentoxifylline in dogs after oral and intravenous administration

OBJECTIVE: To evaluate the pharmacokinetics of pentoxifylline (PTX) and its 5-hydroxyhexyl-metabolite, metabolite 1 (M1), in dogs after IV administration of a single dose and oral administration of multiple doses. ANIMALS: 7 sexually intact, female, mixed-breed dogs. PROCEDURE: A crossover study design was used so that each of the dogs received all treatments in random order. A drug-free period of 5 days was allowed between treatments. Treatments included IV administration of a single dose of PTX (15 mg/kg of body weight), oral administration of PTX with food at a dosage of 15 mg/kg (q 8 h) for 5 days, and oral administration of PTX without food at a dosage of 15 mg/kg (q 8 h) for 5 days. Blood samples were taken at 0.25, 0.5, 1, 1.5, 2, 2.5, and 3 hours after the first and last dose of PTX was administered PO, and at 5, 10, 20, 40, 80, and 160 minutes after PTX was administered IV. RESULTS: PTX was rapidly absorbed and eliminated after oral administration. Mean bioavailability after oral administration ranged from 15 to 32% among treatment groups and was not affected by the presence of food. Higher plasma PTX concentrations and apparent bioavailability were observed after oral administration of the first dose, compared with the last dose during the 5-day treatment regimens. CONCLUSIONS AND CLINICAL RELEVANCE: In dogs, oral administration of 15 mg of PTX/kg results in plasma concentrations similar to those produced by therapeutic doses in humans, and a three-times-a-day dosing regimen is the most appropriate.     

Disposition of clorazepate in dogs after single- and multiple-dose oral administration

Clorazepate dipotassium was administered orally to 8 healthy dogs at a dosage of 2 mg/kg of body weight, q 12 h, for 21 days. Serum disposition of nordiazepam, the principle metabolite of clorazepate, was determined after the first and last dose of clorazepate. Disposition variables were analyzed by use of model-independent pharmacokinetics by the predictive equations method and the trapezoidal rule method. Complete blood counts, serum chemical analyses, and urinalyses were performed before administration of clorazepate and at 10 and 21 days after administration of clorazepate. Maximal nordiazepam concentrations ranged from 446 to 1,542 ng/ml (814 +/- 334 ng/ml), at 59 to 180 minutes (97.9 +/- 42.0 minutes) after a single oral dose of clorazepate. Maximal nordiazepam concentrations ranged from 927 to 1,460 ng/ml (1,308 +/- 187.6 ng/ml), at 120 to 239 minutes (153 +/- 57.9 minutes) after multiple oral doses of clorazepate. Serum disposition was significantly altered after multiple doses of clorazepate. Using data determined by the predictive equations method, the mean residence time after multiple doses (712 +/- 214 minutes) was longer (P less than 0.05) than after a single dose (527 +/- 95.8 minutes). Oral volume of distribution after multiple doses of clorazepate (1.76 +/- 0.647 L/kg) was smaller (P less than 0.02) than after a single dose (3.18 +/- 1.52 L/kg). Oral clearance after multiple doses of clorazepate (3.09 +/- 0.726 ml/min/kg) was less (P less than 0.001) than after a single dose (6.54 +/- 2.15 ml/min/kg). Absorption half-life after multiple doses (72 minutes) was longer (P less than 0.01) than after a single dose (33 minutes).(ABSTRACT TRUNCATED AT 250 WORDS)     

Endoscopy of the gastroduodenal mucosa after carprofen, meloxicam and ketoprofen administration in dogs

Endoscopy was undertaken to examine the gastroduodenal mucosa of 24 healthy dogs after seven days and again after 28 days of oral non-steroidal anti-inflammatory drug (NSAID) administration. The dogs were divided into four groups. One group received ketoprofen (1 mg/kg every 24 hours), one group carprofen (2 mg/kg every 12 hours for seven days followed by 2 mg/kg every 24 hours), a third group meloxicam suspension (0·2 mg/kg every 24 hours), and the last group gelatin (one capsule every 24 hours). Serum biochemical and complete blood count parameters did not change significantly after NSAID administration. Gastroduodenal lesions were observed in 17 dogs, but in all cases these were mild to moderate. The dogs receiving gelatin or carprofen showed the fewest and the least severe lesions, although there was no statistically significant difference between the three test drugs and the control group (P 0–05). None of the dogs showed any clinical signs related to the gastrointestinal lesions.     

Serum thyroid hormone concentrations in clinically normal dogs after administration of freshly reconstituted vs previously frozen and stored thyrotropin

Concentrations of serum thyroxine (T4) and 3,3',5-triiodothyronine (T3) were determined in 7 clinically healthy adult dogs before and after administration of freshly reconstituted thyrotropin (TSH) and TSH that had been previously reconstituted and frozen for 1, 2, and 3 months. The 4 TSH response tests were performed at 30-day intervals by collecting blood samples for serum T4 and T3 determinations before and 4 and 6 hours after IV administration of TSH (0.1 U/kg of body weight). Baseline serum concentrations of T4 and T3 were similar at each of the 4 sample collection times over the 3-month period of the study. Mean serum concentrations of T4 and T3 increased significantly (P less than 0.01) over baseline values after administration of freshly reconstituted TSH or TSH that had been previously frozen for 1, 2, or 3 months. Significant difference was not found in the mean post-TSH serum T4 or T3 concentration after injection of freshly reconstituted TSH or TSH that had been previously frozen for 1, 2, or 3 months. In 2 of the 7 dogs, mild reactions--mild ataxia and weakness--were observed during the last of the series of TSH response tests (ie, after IV administration of TSH that had been previously frozen for 3 months). Results of this study suggest that for use in dogs, reconstituted TSH stored at -20 C maintains adequate biological activity for at least 3 months. The ability to store reconstituted TSH for a longer period than the recommended 48 hours represents an economic advantage, because it allows clinicians to perform more TSH response tests per vial of TSH.     

Pharmacokinetics of oestriol after repeated oral administration to dogs

The aim of the present study was to investigate the pharmacokinetics of oestriol in plasma in the dog after repeated oral administration of oestriol tablets, a preparation intended for the treatment of urinary incontinence in the bitch. The study was performed in six healthy, entire, adult female beagle dogs. The bitches were treated once daily with two tablets, containing 1 mg oestriol per tablet, for seven consecutive days (days 1-7). Blood samples were taken from the jugular vein before treatment, frequently on days 1, 3 and 7 of the treatment period and daily just before (C(trough)) and 1 h after dosing (C(t=1h)). During the washout period samples were taken at a 24 h interval up to four days post-treatment. Oestriol concentrations were determined in plasma by radioimmunoassay. Pharmacokinetic parameters, AUC, C(max) and t(max), were determined from the plasma concentration-time curves using non-compartmental methods. The between animal variation in C(max) and the AUC was high. Individual values of the C(max) varied from 206 pg/ml (day 1) to 1128 pg/ml (day 7) and the AUC(0-24h) from 789 pg x h/ml (day 1) to 5718 pg x h/ml (day 7). t(max) occurred within 1 h. The mean C(trough) value was slightly above the pre-treatment level ( 38+/-2 pg/ml vs. 18+/-5 pg/ml). Within 48 h after the last treatment the concentrations had returned to the pre-treatment values. C(max) and C(trough) did not increase during the treatment period, indicating that no accumulation occurred. A shoulder in the concentration-time curve around 8-12 h after treatment strongly suggested the existence of enterohepatic recirculation (EHR). The average relative contribution of the EHR to the AUC(0-24h) was estimated to be 22%, 38% and 44% on days 1, 3 and 7, respectively. These mean values were calculated from five animals per time point, because one dog failed to show EHR on days 1 and 3 and was therefore excluded from the calculations.     

Serum concentrations of pepsinogen A in healthy dogs after food deprivation and after feeding

OBJECTIVE: To develop and validate an ELISA for measurement of serum canine pepsinogen A (cPG A) as a diagnostic marker of gastric disorders in dogs and to measure serum cPG A in healthy dogs after food deprivation and after feeding. SAMPLE POPULATION: Sera from 72 healthy dogs. PROCEDURE: A sandwich ELISA was developed and validated. The reference range for serum concentrations of cPG A was determined in 64 healthy dogs. Postprandial changes in serum concentrations of cPG A were evaluated in 8 healthy dogs. RESULTS: Assay sensitivity was 18 microg/L, and the maximum detectable concentration was 1,080 microg/L. The observed-to-expected ratio (O:E) for 3 serial dilutions of 3 serum samples ranged from 69.3 to 104.1%. The O:E for 3 serum samples spiked with 8 concentrations of cPG A ranged from 58.8 to 120.4%. Coefficients of variation for intra- and interassay variability of 3 serum samples ranged from 7.6 to 11.9% and from 10.1 to 13.1%, respectively. Mean +/- SD serum concentration of cPG A in healthy dogs was 63.8 +/- 31.0 microg/L and the reference range was 18 to 129 microg/L. Significant increases in serum concentrations of cPG A were observed between 1 and 7 hours after feeding. CONCLUSIONS AND CLINICAL RELEVANCE: The ELISA for measuring cPG A was sufficiently sensitive, linear, accurate, precise, and reproducible for clinical use. Serum concentrations of cPG A increase substantially after feeding, which should be taken into account when conducting clinical studies.     

Serum concentrations of thyroxine, 3,5,3'-triiodothyronine, thyrotropin, and prolactin in dogs before and after thyrotropin-releasing hormone administration

Serum concentrations of thyrotropin (TSH), prolactin, thyroxine, and 3,5,3'-triiodothyronine in 15 euthyroid dogs and 5 thyroidectomized and propylthiouracil-treated dogs after thyrotropin-releasing hormone (TRH) administration were measured. Although thyroidectomized and propylthiouracil-treated dogs had higher (P less than 0.01) base-line concentrations of TSH in serum than did euthyroid dogs, concentrations of TSH after TRH administration varied at 7.5, 15, and 30 minutes with 14 of 45 samples obtained from healthy dogs having lower TSH concentrations than before TRH challenge. Similarly, concentrations of 3,5,3'-triiodothyronine in the serum of euthyroid dogs 4 hours after TRH administration were similar (P less than 0.05) to concentrations before TRH challenge. Although the mean concentration of thyroxine in serum was elevated (P less than 0.05) 4 hours after administration of TRH to euthyroid animals, as compared with base-line levels, the individual response was variable with concentrations not changing or decreasing in 4 dogs. Therefore, the TRH challenge test as performed in the current investigation was of limited value in evaluating canine pituitary gland function. Although mean concentrations of TSH in serum were higher (P less than 0.05) in euthyroid dogs after TRH administration, the response was too variable among individual animals for accurate evaluation of pituitary gland function. Concentrations of prolactin in the sera of dogs after TRH administration, confirmed previous reports that exogenously administered TRH results in prolactin release from the canine pituitary and indicated that the TRH used was biologically potent.     

Serum cardiac troponin I and cardiac troponin T concentrations in dogs with gastric dilatation-volvulus

OBJECTIVE: To determine whether serum concentrations of cardiac troponin I (cTnI) and cardiac troponin T (cTnT) are increased in dogs with gastric dilatationvolvulus (GDV) and whether concentrations correlate with severity of ECG abnormalities or outcome. DESIGN: Prospective case series. ANIMALS: 85 dogs with GDV. PROCEDURE: Serum cTnl and cTnT concentrations were measured 12 to 24, 48, 72, and 96 hours after surgery. Dogs were grouped on the basis of severity of ECG abnormalities and outcome. RESULTS: cTnl and cTnT were detected in serum from 74 (87%) and 43 (51%) dogs, respectively. Concentrations were significantly different among groups when dogs were grouped on the basis of severity of ECG abnormalities (none or mild vs moderate vs severe). Dogs that died (n = 16) had significantly higher serum cTnI (24.9 ng/ml) and cTnT (0.18 ng/ml) concentrations than did dogs that survived (2.05 and < 0.01 ng/ml, respectively). Myocardial cell injury was confirmed at necropsy in 4 dogs with high serum cardiac troponin concentrations. CONCLUSIONS AND CLINICAL RELEVANCE: Results indicate that concentrations of cTnI and cTnT suggestive of myocardial cell injury can commonly be found in serum from dogs with GDV and that serum cardiac troponin concentrations are associated with severity of ECG abnormalities and outcome.