Pharmacokinetics of antipyrine and sulphadimidine (sulfamethazine) in camels, sheep and goats

The pharmacokinetics of antipyrine and sulphadimidine were studied in male camels, sheep and goats. The two drugs were administered concomitantly. Following intravenous injection of antipyrine (25 mg/kg) and sulphadimidine (sulfamethazine) (100 mg/kg), the pharmacokinetics of the two drugs were adequately described by a one-compartment model. Antipyrine half-life in goats (2.58 h) was shorter than that in sheep (4.04 h) and camels (18.78 h). The plasma clearance was greatest in goats then sheep and then camels. For sulphadimidine, a significantly greater volume of distribution was observed in camels and the greatest plasma clearance and shortest half-life were reported in goats. Sulphadimidine half-life was 2.77 h in goats, 4.72 h in sheep and 7.36 h in camels. The present results suggest that goats have the fastest elimination of these drugs from the circulation, followed by sheep and then camels.     

Pharmacokinetics and tissue residues of josamycin in fowls.

Josamycin is a macrolide antibiotic which is produced by fermentation of cultures of Streptomyces narbonensis. It was once administrated (18 mg/kg b. wt.) in fowls via intravenous, oral and intramuscular routes for determination of blood concentration, kinetic behaviour and bioavailability. Following a single intravenous injection, the blood concentration-time-curve indicated a two compartments open model with an elimination half life value (t1/2 beta) of 1.83 +/- 0.06 hours. Both oral and intramuscular routes showed higher values, i.e. 2.33 +/- 0.13 and 2.85 +/- 0.17 hours. The lower apparent volume of distribution of Josamycin in fowls than one liter/kg elucidate higher distribution in blood than in tissues. Systemic bioavailability after both oral and intramuscular administration, i.e. 33.88 +/- 2.4 and 27.28 +/- 1.46% respectively, showed lower absorption from site of i.m. application. Josamycin was administered (18 mg/kg b. wt.) intramuscularly and orally once daily for 5 consecutive days. The drug peaked in serum 1 hour (intramuscular) and 2 hours (orally) after each dose. The recorded results revealed that serum level of Josamycin was higher after oral application (29.98 +/- 1.92 micrograms/ml) than after i.m. application. The drug persisted in the lung tissues and fat for 72 hours after administration and disappeared from all body tissues 96 hours after the last dose of repeated administration.     

Pharmacokinetics of sulfamethazine in male, female and castrated male swine

The concentration of sulfamethazine in plasma and sulfamethazine and its metabolites in urine were compared in male, female and castrated male swine. A surgical technique for placement of catheters in the urinary bladder was used to facilitate the collection of urine in males and castrated males. The elimination rate of sulfamethazine from plasma and the excretion of parent drug and metabolites into urine did not differ significantly among females, males and castrated male swine.     

磺胺二甲嘧啶在黑鲪体内的药物代谢动力学和残留消除研究

在(14±1)℃水温条件下,对黑鲪单次口灌100 mg/kg体重的磺胺二甲嘧啶,进行药物代谢动力学研究。在(20±2)℃水温条件下,按照《中华人民共和国水产行业标准磺胺类药物水产养殖使用规范》推荐剂量对黑鮶连续5天口灌给予磺胺二甲嘧啶,研究其在黑鮶体内的残留消除规律。血浆、肌肉和肝脏样品采用高效液相色谱检测,DAS2.0药物代谢动力学软件对数据进行处理分析。结果表明磺胺二甲嘧啶在黑鲪血浆、肌肉和肝脏中均符合一室模型,肝脏、血液和肌肉中药物达峰时间分别为6 h,8 h和10 h;峰值浓度分别为26.45μg/g、25.57μg/g和31.15μg/g;连续多次给药后,黑鮶血液、肌肉、肝脏中药物浓度分别在给药后12d、14d、15d后小于最大残留限量要求(0.1mg/kg)。     

Pharmacokinetics and tissue residues of kitasamycin in healthy and diseased broilers

The pharmacokinetics of kitasamycin after intravenous and oral administration in a dose of 300 mg/kg b.wt. was studied in 18 healthy and 18 Salmonella gallinarum naturally infected chickens. The tissue residue of the studied antibiotic was estimated in 36 normal chickens when it was given orally for 7 successive days. Therapeutic level of kitasamycin was achieved after 15 minutes and persisted for 20-22 hours after its oral administration. Higher serum kitasamycin concentrations were recorded in Salmonella gallinarum infected chickens. The elimination half-life of kitasamycin calculated after single intravenous injection was 9.03 hours in diseased chickens corresponding to 3.74 hours in healthy birds. The body clearance was significantly reduced in diseased chickens (23.86 ml/kg/min) when compared to that in normal ones (62.03 ml/kg/min). Kitasamycin treated broilers should not be slaughtered before 3 days from the last dose as it was detected only in bile and caecum at that time but not in edible tissues.     

Elimination of sulfamethazine residues from swine.

Tissue concentrations of sulfamethazine in swine fed the drug at the rate of 500 g/ton of ration (550 g/1,000 kg) for a 30-day period depleted to 0.1 ppm or less within 4 to 10 days after withdrawal of medicated feed. Depletion from the tissues and plasma of treated pigs showed a linear relationship with time when the concentrations were plotted on a semilogarithmic graph. Six untreated pigs that were placed on bedding in pens formerly occupied by the treated group developed tissue residues at or above 0.1 ppm sulfamethazine; the mean plasma concentration of sulfamethazine reached 2.8 ppm by day 15.     

Pharmacokinetics,tissue residues,and ex vivo pharmacodynamics of tylosin against Mycoplasma anatis in ducks

The pharmacokinetics of tylosin were investigated in 3 groups of ducks (n = 6). They received a single dose of tylosin (50 mg/kg) by intravenous (IV), intramuscular (IM), and oral administrations, respectively. Plasma samples were collected at various time points to 24 hr post-administration to evaluate tylosin concentration over time. Additionally, tylosin residues in tissues and its withdrawal time were assessed using 30 ducks which received tylosin orally (50 mg/kg) once daily for 5 consecutive days. After IV administration, the volume of distribution, elimination half-life, area under the plasma concentration–time curve, and the total body clearance were 7.07 ± 1.98 L/kg, 2.04 hr, 19.47 µg hr/ml, and 2.82 L hr⁻¹ kg⁻¹, respectively. After IM and oral administrations, the maximum plasma concentrations were 3.70 and 2.75 µg/ml achieved at 1 and 2 hr, and the bioavailability was 93.95% and 75.77%, respectively. The calculated withdrawal periods of tylosin were 13, 8, and 5 days for kidney, liver, and muscle, respectively. For the pharmacodynamic profile, the minimum inhibitory concentration for tylosin against M. anatis strain 1,340 was 1 µg/ml. The calculated optimal oral dose of tylosin against M. anatis in ducks based on the ex vivo pharmacokinetic/pharmacodynamic modeling was 61 mg kg⁻¹ day⁻¹.     

Pharmacokinetics of ceftazidime in sheep and its penetration into tissue and peritoneal fluids

Serum, tissue and peritoneal fluid concentrations of ceftazidime were studied in ewes after intravenous, intramuscular and subcutaneous administration at 50 mg kg-1 bodyweight. Tissue and peritoneal cages were implanted in the animals studied. After intravenous bolus administration, the mean serum concentration versus time profile was best described by a two-compartment open model. The distribution rate constant (alpha) was 3.5 +/- 1.1 h-1 and the half-life (t 1/2 alpha) 0.22 +/- 0.09 hour. The elimination rate constant (beta) was 0.43 +/- 0.04 h-1 and half-life (t 1/2 beta) 1.6 +/- 0.2 hours. The area under the curve was 275.7 +/- 84.0 micrograms.ml-1 h. The volume of distribution as steady state was 356.1 +/- 208.0 ml kg-1. The penetration ratio into tissue fluid was 62.6 +/- 15.1 per cent and into peritoneal fluid 61.1 +/- 16.5 per cent. After intramuscular injection, the elimination half-life was 1.7 +/- 0.2 hours, the area under the curve was 228.7 +/- 43.3 micrograms.ml-1 h. and the elimination rate constant was 0.42 +/- 0.05 h-1. The penetration ratio into tissue fluid was 68.5 +/- 37.3 per cent and into peritoneal fluid 73.3 +/- 34.4 per cent. After subcutaneous injection, the elimination half-life was 1.8 +/- 0.5 hours, the area under the curve was 231.8 +/- 65.6 micrograms.ml-1 h. and the elimination constant was 0.41 +/- 0.10 h-1. The penetration ratio into tissue fluid was 47.2 +/- 3.5 per cent and into peritoneal fluid 58.1 +/- 15.6 per cent.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics and tissue residues of moroxydine hydrochloride in gibel carp,Carassius gibelio after oral administration

The pharmacokinetics and tissue residues of moroxydine hydrochloride were studied in gibel carp at water temperature of 15 and 25 °C. Samples (blood, skin, muscle, liver, and kidney) were collected over 10 days after the treatment and analyzed by high‐performance liquid chromatography with an ultraviolet detector. The results indicated that the influence of water temperature on the metabolism of the drug was significant. The plasma concentration–time data of moroxydine hydrochloride conformed to single‐compartment open model at the two water temperatures. There were higher absorption rate (t_1/2ka) and longer elimination half‐lives (t_1/2ke) at 15 °C (4.29 and 15.87 h, respectively) compared with those at 25 °C (3.02 and 4.22 h, respectively). The maximum plasma concentration (C_max) and the time‐point of maximum plasma concentration (T_p) were 2.98 μg/mL and 10.35 h at 15 °C and 3.12 μg/mL and 4.03 h at 25 °C, respectively. The distribution volume (V_d/F) of moroxydine hydrochloride was estimated to be 4.55 L/kg at 15 °C and 2.89 L/kg at 25 °C. The total body clearance (CL_b) of moroxydine hydrochloride was determined to be 0.25 and 0.49 L/(h·kg) at 15 °C and 25 °C, respectively; the areas under the concentration–time curve were 75.89 μg·h/mL at 15 °C and 42.33 μg·h/mL at 25 °C. The depletion of moroxydine hydrochloride in gibel carp was slower with a longer half‐life period, especially at lower water temperature that was tested.     

Pharmacokinetics and tissue residues of pefloxacin and its metabolite norfloxacin in broiler chickens

1. The pharmacokinetics of pefloxacin and its active metabolite norfloxacin were investigated in chickens after a single oral administration of pefloxacin at a dosage of 10 mg/kg. To characterise the residue pattern, another group of chickens was given 10 mg of pefloxacin/kg body once daily for 4 d by oral route; the tissue concentrations of pefloxacin and norfloxacin were determined at 1, 5 and 10 d after the last administration of the drug. 2. The concentrations of pefloxacin and norfloxacin in plasma and tissues were determined by HPLC assay. The limit of detection for pefloxacin and norfloxacin was 0.03 microg/ml in plasma or microg/g in tissue. 3. The plasma concentration-time data for pefloxacin and norfloxacin were characteristic of a one-compartment open model. The elimination half-life, maximum plasma drug concentration, time to reach maximum plasma drug concentration and mean residence time of pefloxacin were 8.74 +/- 1.48 h, 3.78 +/- 0.23 microg/ml, 3.33 +/- 0.21 h and 14.32 +/- 1.94 h, respectively, whereas the respective values of these variables for norfloxacin were 5.66 +/- 0.81 h, 0.80 +/- 0.07 microg/ml, 3.67 +/- 0.21 h and 14.44 +/- 0.97 h. 4. Pefloxacin was metabolised to norfloxacin to the extent of 22%. 5. The concentrations of pefloxacin (microg/g) 24 h after the fourth dose of the drug declined in the following order: liver (3.20 +/- 0.40) > muscle (1.42 +/- 0.18) > kidney (0.69 +/- 0.04) > skin and fat (0.06 +/- 0.02). Norfloxacin was also detectable in all the tissues analysed except muscle. No drug and/or its metabolite was detectable in tissues except skin and fat 5 d after the last administration. The concentrations of pefloxacin and norfloxacin in skin and fat 10 d after the last dose of pefloxacin were 0.04 +/- 0.02 and 0.03 +/- 0.01 microg/g, respectively.     

Comparative pharmacokinetics of sulfamethazine in plasma and parotid saliva of sheep

Salivary output in sheep is large enough to be considered a physiologic body fluid compartment. The hypothesis for this work was that pharmacokinetics of sulfamethazine in saliva was similar to that in plasma. A reliable technique was developed to measure parotid salivary output. Mean output of saliva was 3.18 ± 1.04 L from a single parotid gland per day with a mean flow of 2.21 ± 0.43 mL/min. Using concentrations of sulfamethazine in parotid saliva made it possible to calculate the total passage of sulfamethazine to parotid saliva, which was calculated to be 3.5% of the total dose. Pharmacokinetic variables obtained for sulfamethazine in plasma and in saliva were closely related ( AUC 1408 μg.h/mL and AUC 1484 μg.h/mL; V d_area 0.434 L/kg and V d _area 0.374 L/kg; t _½β 4.30 h and 3.46 h, respectively) and no substantial differences were observed. The convenience of using salivary concentrations of sulfamethazine for drug monitoring is discussed.     

Pharmacokinetics and tissue residues of norfloxacin and its N-desethyl- and oxo-metabolites in healthy pigs

The pharmacokinetic properties of norfloxacin were determined in healthy pigs after single intramuscular (i.m.) and intravenous (i.v.) dosage of 8 mg/kg body weight After i.m. and i.v. administration, the plasma concentration-time graph was characteristic of a two-compartment open model. After single i.m. administration, norfloxacin was absorbed rapidly, with a t _max of 1.46 ± 0.06 h. The elimination half-life ( t _1/2β) and the mean residence time of norfloxacin in plasma were 4.99 ± 0.28 and 6.05 ± 0.22 h, respectively, after i.m. administration and 3.65 ± 0.16 and 3.34 ± 0.16 h, respectively, after i.v. administration. Intramuscular bioavailability was found to be 53.7 ± 4.4%. Plasma concentrations greater than 0.2 μg/mL were achieved at 20 min and persisted up to 8 h post-administration. Maximal plasma concentration was 1.11 ± 0.03 μg/mL. Statistically significant differences between the two routes of administration were found for the half-lives of both distribution and elimination phases ( t _1/2α, t _1/2β) and apparent volume of distribution (V_d(area)). In pigs, norfloxacin was mainly converted to desethylenenorfloxacln and oxonorfloxacin. Considerable tissue concentrations of norfloxacin, desethylenenorfloxacin, and oxonorfloxacin were found when norfloxacin was administered intramuscularly (8 mg/kg on 4 consecutive days). The concentration of the parent fluoroquinolone in liver and kidney ranged between 0.015 and 0.017 μg/g on day 12 after the end of dosing.     

Effects of dose and duration of therapy on gentamicin tissue residues in sheep

The effects of different doses and dosage regimens on gentamicin pharmacokinetics and tissue residues were determined. Five groups of 12 sheep each were given gentamicin IM: group I, 2 mg of gentamicin sulfate/kg once; group II, 6 mg/kg once; group III, 18 mg/kg once; group IV, 6 mg/kg every 24 hours for 3 doses; and group V, 2 mg/kg every 8 hours for 9 doses. Serum concentrations were determined serially until sheep were killed and necropsied. Three sheep from each group were killed at 1, 4, 8, and 12 days after the last dose was administered. Renal cortex, renal medulla, liver, spleen, lung, skeletal muscle, and skeletal muscle at the injection site were assayed for gentamicin. An exponential equation was fitted to the serum concentrations, and various pharmacokinetic variables were determined. Serum clearance tended to increase as the single dose increased (P = 0.0588). Steady-state volume of distribution increased as the single dose was increased (P less than 0.05). Renal cortex contained the highest concentration of gentamicin which decreased in a biexponential manner. Concentrations in all tissues, except the injection site, were dependent upon the amount of the total dose, not the size of the injected dose (P less than 0.05). Concentrations at the injection site were up to 29 micrograms/g of tissue at 1 day after the last dose was given and were dependent upon the amount of total dose from multiple injections, not on the amount of each injected dose (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics of cefaronide, ceftriaxone and cefoperazone in sheep

The pharmacokinetics of cefaronide (16 gm/kg dose), ceftriaxone and cefoperazone (47 gm/kg dose), after intravenous (i.v.) administration were determined in six Merino ewes. The mean values for terminal half life, steady state volume of distribution Vd(ss), renal clearance (ClR) and total body clearance (ClB) for cefaronide were 1.5 h, 0.39 l/kg, 0.06 l/h/kg and 0.16 l/h/kg, for ceftriaxone; 1.7 h, 0.30 l/kg, 0.08 l/h/kg, and 0.22 l/h/kg, and 0.7 h, 0.16 l/kg, 0.02 l/h/kg and 0.16 l/h/kg for cefoperazone, respectively. After 5.5 h, approximately 42% cefaronide, and after 8 h, approximately 37% ceftriaxone and 13% cefoperazone, was excreted in urine. The non-renal elimination of ceftriaxone and cefoperazone appeared to be more rapid in sheep than is reported in man. Cefaronide was excreted largely unchanged in the urine of sheep. Therefore, the elimination of cefaronide in sheep was similar to that found in man. Cefaronide was well distributed in sheep, whereas ceftriaxone and cefoperazone appeared to be distributed to a lesser degree. These findings underline the different disposition of drugs in different species.     

Pharmacokinetics of cefotaxime in sheep

Five healthy adult Merino ewes were each given 2 g of cefotaxime by the IV, IM, and subcutaneous (SC) routes. The serial plasma samples collected after each treatment were analyzed for cefotaxime by a new high-pressure liquid chromatographic method. Plasma concentration time profiles were characterized by a linear 2-compartment model after IV administration and the following mean values (+/- SD) were found: biological half-life, 23 +/- 8 minutes; apparent volume of distribution, 5.5 +/- 1.3 L; plasma clearance, 0.37 +/- 0.09 L/min; elimination rate constant, 0.066 +/- 0.014 minute-1; rate of diffusion into tissue, 0.013 +/- 0.013 minute-1; and out of tissue, 0.035 +/- 0.017 minute-1. Plasma cefotaxime concentrations in the ewes given the drug by the IV, IM, and SC routes were 113 +/- 32, 71 +/- 20, and 38 +/- 11 micrograms/ml, respectively, at 15 minutes; 2.31 +/- 0.82, 11.3 +/- 6.6, and 16.4 +/- 3.7 micrograms/ml at 120 minutes; and 1.05 +/- 1.22, 9.3 +/- 5.2, and 14.9 +/- 1.27 micrograms/ml at 150 minutes. After cefotaxime was given SC and IM, plasma values were higher for a longer time than they were after the drug was given IV, probably due to a slower release of drug from the former injection sites.     

Pharmacokinetics of probenecid in sheep

Six Merino ewes were given 1 g (27 g/kg) probenecid by the intravenous (i.v.), intramuscular (i.m.) and subcutaneous (s.c.) routes. After i.v. injection, the biological half-life was 1.55 h and apparent volume of distribution at the steady state (Vdss) 0.18 l/kg. Body clearance (ClB) and renal clearance (ClR) were 0.12 l/h/kg and 0.03 l/h/kg, respectively. Approximately 28% of unchanged probenecid was excreted in urine. Plasma probenecid concentrations after i.v., i.m. and s.c. injections were 133, 37, and 31 micrograms/ml, respectively, at 15 min; 76, 36, and 34 micrograms/ml at 1 h; and 43, 23 and 34 micrograms/ml at 2 h. The average bioavailability of probenecid given by i.m. and s.c. injection was 46% and 34%, respectively. However, after 2 h, probenecid plasma concentrations remained higher when it was given subcutaneously than when it was given intramuscularly. Urine output was correlated positively (P less than 0.05) with kel and ClB. Urine pH increased significantly (P less than 0.01) for the first 2 h, and then steadily declined over the subsequent 6 h. The results suggested that probenecid in sheep was rapidly eliminated because it was rapidly excreted in the normal but alkaline urine. Subcutaneous administration of probenecid in animals may be a useful alternative to oral or i.v. administration.     

Pharmacokinetics of parenteral and oral sustained-release morphine sulphate in dogs

The pharmacokinetics of single-dose morphine sulphate (MS) administered intravenously (i.v.) and intramuscularly (i.m.) and of oral sustained-release morphine sulphate (OSRMS) were studied in dogs. Beagles (n = 6) were randomly assigned to six treatment groups using a Latin square design. Treatments included MS 0.5 and 0.8 mg/kg i.v. and i.m. and OSRMS 15 and 30 mg orally (p.o). Serum samples were drawn at intervals up to 420 min following parenteral MS and 720 min following OSRMS. Serum was analysed for morphine concentration using a radioimmunoassay . Pharmacokinetic analysis of the results revealed that MS was eliminated by a first-order process best described by a two-compartment model. For i.v. and i.m. data there were no statistically significant differences (P c 0.0 5) between steady-state volume of distribution, half-life of elimination and plasma clearance. As expected, area under the concentration vs. time curve (AUC) was significantly greater for the 0.8 mg/kg dosage for i.v. and i.m. routes, and time to maximum serum concentration was significantly longer following i.m. administration. For OSRMS there were no significant differences between dosage for any parameter (AUC, C_max. t_max t_½ F) and prolonged absorption of the drug occurred over approximately 6 h. Bioavailability (F) for both oral dosages was approximately 20%. The i.m. route is an effective method for rapid and complete delivery of MS to dogs. OSRMS may be useful in the provision of long-term analgesic therapy in dogs, but further work is required to verify the safety and effectiveness of this preparation.