Pharmacokinetics of sulfadimethoxine and ormetoprim in a 5:1 ratio following intraperitoneal and oral administration, in the hybrid striped bass (Morone chrysops x Morone saxitalis)

Selected pharmacokinetic parameters for sulfadimethoxine and ormetoprim, administered in a 5:1 ratio, via the oral and intraperitoneal (i.p.) routes were determined in the hybrid striped bass (Morone chrysops x Morone saxitalis). Plasma concentrations of both drugs were determined by high-performance liquid chromatography. A first-order one-compartment model adequately described plasma drug disposition. The elimination half-lives for sulfadimethoxine following i.p. and oral administration were 26 and 10.5 h, respectively. The half-lives for ormetoprim administered via i.p. and oral routes were 7.5 and 3.9 h, respectively. Cmax for sulfadimethoxine via the i.p. and oral routes were calculated to be 27.7 (+/-9.0) microg/mL at 3.6 h and 3.2 (+/-1.2) microg/mL at 1.2 h, respectively. Cmax for ormetoprim via the i.p. route was calculated to be 1.2 (+/-0.5) microg/mL at 9.1 h and 1.58 (+/-0.7) microg/mL at 5.7 h for the oral route. The oral availability of sulfadimethoxine relative to the i.p. route was 4.6%, while the oral availability of ormetoprim relative to the i.p. route was 78.5%. Due to the nonconstant ratio of these drugs in the plasma of the animal, the actual drug ratio to use for determining minimum inhibitory concentration (MIC) is unclear. Using the ratio of the total amount of each drug that is absorbed as a surrogate for the mean actual ratio may be the best alternative to current methods. Using this ratio as determined in these studies, (2.14:1 sulfadimethoxine:ormetoprim) to determine the MICs the single 50 mg/kg oral dose of the 5:1 combination of sulfadimethoxine and ormetoprim appears to provide plasma concentrations high enough to inhibit the growth of Yersinia ruckeri, Edwardsiella tarda, and Escherichia coli.     

The bioavailability, dispostion kinetics and dosage of sulphadimethoxine in dogs.

The disposition kinetics of sulphadimethoxine were studied in six normal beagle dogs after intravenous injection of a single dose (55 mg/kg). The median (range) distribution and elimination half times of the drug were 2.36 (2.06-3.35) hours and 13.10 (9.71-16.50) hours, respectively. Total body clearance of the drug had a median value of 21.7 ml/kg/h and a mean value of 21.4 ml/kg/h. While the overall tissue to plasma level ratio (k12/k21) of the drug was 0.55 after distribution equilibrium had been attained, analogue computer simulated curves showed that at 24 hours the fractions (percentage) of the dose in the central and tissue compartments were 12 and 11%, respectively. The drug was shown, by equilibrium dialysis method, to be highly bound to plasma proteins (greater than 75%) within the usual therapeutic range (50 to 150 mug/ml) of plasma levels. The systemic availability of sulphadimethoxine from the oral suspension was 32.8% (22.5-80.0). Since the absorption half time, 1.87 (0.86-3.22) hours, was considerably shorter than the half-life, 13.10 (9.71-16.50) hours, of the drug, the rate of absorption would have little influence on the dosage regimen. Based on the experimental data obtained, a satisfactory dosage regimen might consist of a priming dose of 55 mg/kg by the intravenous route and maintenance doses of either 27.5 mg/kg of sulphadimethoxine injection given intravenously or 55 mg/kg of the oral suspension administered at 24 hour intervals. The adequacy and duration of therapy will depend upon the clinical response obtained.     

Drug residues in food animals II. Plasma and tissue kinetics of oxytetracycline in young cross-bred swine

Tissue distribution and elimination kinetics of oxytetracycline in sixteen organs and body fluids were determined in young pigs following intravenous and oral administration. Seventeen non-fasted pigs, 8–10 weeks of age, weight range 16.4–34.5 kg were dosed intravenously at a dose rate of 11 mg/kg bodyweight. An additional seventeen weaning pigs, 12–14 weeks of age, weight range 27.2–36.3 kg were dosed orally at a dose rate of 48–65 mg/kg bodyweight. Oxytetracycline was rapidly distributed (half-life, 6.71 ± 1.13 min) in swine. The mean volume of distribution was 1.26 ± 0.18 l/kg and overall body clearance was 3.82 ± 0.59 ml/kg/min. The elimination half-life of oxytetracycline in pigs was 3.87 ± 0.62 h, which is shorter than has been observed in other domestic animal species. Oxytetracycline became rapidly and efficiently involved in enterohepatic cycling, with as much as 70% of a total intravenous dose being available for reabsorption from the gastrointestinal tract within 1 h after administration. This high degree of enterohepatic recycling prolonged the half-life, and the large amount of drug that entered the enteric tract contributed to the high volumes of distribution and high k ₁₂/ k ₂₁ ratios. The excellent tissue penetration of this drug further contributed to the high volume of distribution and high k ₁₂/ k ₂₁ ratios obtained. Relationships between plasma and tissue depletion for several major edible organs were found to be statistically significant. Blood plasma is proposed as a body fluid for monitoring oxytetracycline tissue residues.     

Ruminal excretion of sulfadimethoxine and sulfadimethyloxazole in goats and their influence on some enzyme activities and renal clearances

Five clinically health goats were injected with sulfadimethoxine and sulfadimethyloxazole in a single dose of 100 mg/kg b. wt. by intravenous route. Highest concentration levels of sulfadimethoxine and sulfadimethyloxazole in rumen were detected 1 hour following intravenous injection, then the concentration for both compounds declined at 12 and 8 hours post administration, respectively. In addition, both types of sulfonamide completely disappeared in ruminal fluid samples taken after 24 and 12 hours, respectively. The rate of acetylation for sulfadimethoxine and sulfadimethyloxazole were nearly similar and occurred to a high extent in ruminal fluid (22.95 and 23.72%, respectively). On the other hand, both tested drugs increased significantly the ruminal gas production from the first to eight hours after i.v. injection in goats. Changes in the serum enzyme activities (SGOT, SGPT and alkaline phosphatase) observed with sulfadimethoxine and sulfadimethyloxazole, and represented by a significant decrease in the activity of SGOT and SGPT level, alkaline phosphatase 4 hours sulfadimethoxine and in GOT/GPT ratio 24 and 48 hours after i.v. injection, respectively. The creatinine clearance was significantly decreased after 4 hours following the i.v. administration of sulfadimethoxine and sulfadimethyloxazole in goats.     

Tissue sulfonamide concentration and correlation in turkeys

Nineteen hen turkeys (10 to 12 kg each) were used in a feeding study to determine sulfadimethoxine and sulfaquinoxaline concentrations in blood serum, liver, and skeletal muscle, as well as the respective ratios at selected withdrawal intervals. Two feeds were prepared by use of premixes to achieve 60 mg of sulfadimethoxine/kg and 100 mg of sulfaquinoxaline/kg, respectively. Each of the medicated feeds was given to 9 turkeys for 7 days. The turkeys were then fed nonmedicated feed at intervals from 24 to 56 hours and were slaughtered. One turkey was used as control. The serum/liver and serum/muscle ratios for sulfaquinoxaline were 60 to 70% higher than for sulfadimethoxine. However, the liver/muscle ratio for both sulfonamides was equivalent, approximately 3. Disposition of both sulfonamides approximated first-order pharmacokinetics. The calculated half-life of sulfadimethoxine was half that of sulfaquinoxaline, approximately 16 vs 30 hours. The coefficients of variation in the serum/tissue ratios for both sulfonamides were between 13% and 25% for serum/liver and less than 15% for serum/muscle, indicating excellent potential for using serum as a predictor of actionable concentrations of sulfonamide residues.     

Disposition of sulfadimethoxine in male llamas (Llama glama) after single intravenous and oral administrations.

This study determined the disposition of sulfadimethoxine in six, healthy, adult, gelded male llamas (Llama glama) by using a nonrandomized crossover design with i.v. dosing (58.8 +/- 3.0 mg/kg based on metabolic scaling) followed by oral dosing (59.3 mg/kg +/- 8.3). Blood samples were collected intermittently for a 72-hr period, and serum sulfadimethoxine concentrations were quantified using high-performance liquid chromatography. Serum sulfadimethoxine concentrations across time were subjected to standard pharmacokinetic analysis based on linear regression. Mean maximum serum concentration after oral dosing was 23.6 +/- 14.9 microg/ml, and extrapolated peak concentration after i.v. administration was 246.6 +/- 15.8 microg/ml. Total clearance of sulfadimethoxine was 45.4 +/- 13.9 L/kg. Half-lives after i.v. and oral administration were 541 +/- 111 min and 642.4 +/- 204.8 min, respectively. Oral bioavailability was 52.6 +/- 15%. These data suggest that the oral dose administered to llamas in this study, based on metabolic scaling from cattle, may be inadequate when compared with the reported minimum inhibitory concentration (512 microg/ml) breakpoint for sulfadimethoxine.     

Plasma/muscle ratios of sulfadimethoxine residues in channel catfish (Ictalurus punctatus)

Channel catfish ( n = 84) maintained at a water temperature of 27°C were used in a feeding study to determine the plasma to muscle concentration ratios of sulfadimethoxine (SDM) and 4-N-acetylsulfadimethoxine residues. Sulfadimethoxine medicated feed was provided free choice at 42 mg SDM/kg body weight once daily for 5 days and the plasma and muscle concentrations of SDM were determined at selected withdrawal times (6, 12, 24, 48, 72, and 96 hours) following the last dose. Considerable variation in total SDM tissue concentration among fish within a sampling period was observed. For fish ( n = 12) at six hours post-dose, total SDM concentrations ranged from 1.4–24.8 μg/mL and 0.6–12.6 μg/g, with mean total SDM concentrations of 9.1 μg/mL and 5.3 μg/g for plasma and muscle, respectively. However, a mean plasma:muscle concentration ratio of 1.8:1 ± 0.3:1 was obtained over all concentrations and sampling periods. The plasma:muscle 95% t distribution interval for individual fish was 1.2:1 to 2.4:1. A correlation coefficient of 0.967 was obtained for the relationship between plasma and muscle total SDM concentration among individual fish ( n = 25). Results of this study indicate that plasma total SDM concentration may be used to identify samples containing violative SDM muscle residue. No fish contained total SDM muscle residues greater than the FDA tolerance (0.1 μg/g) by 48 hours following the final dose.     

Pharmacokinetic studies of phenylbutazone in cattle

The disposition kinetics and systemic availability of phenylbutazone were studied in healthy dairy cows. The same dose (6mg/kg) of phenylbutazone was administered by the i.v., i.m. and oral routes. The elimination half time after intravenous administration ranged from 32.4 to 60.8h. The result suggested that the distribution of phenylbutazone in cows can be described by a two-compartment open model. Total body clearance of the drug had a mean value of 0.0016 ml/kg-h. The overall tissue to plasma level ratio (k₁₂/k₂₁-β), after distribution equilibrium had been attained was 0.64. Phenylbutazone was shown, by an equilibrium dialysis method, to be highly bound to plasma proteins (93%) at serum levels of 100 μ/ml. The systemic availability of phenylbutazone was 69% and 89% when administered orally and intramuscularly respectively. Animals receiving half the dose of phenylbutazone (3 mg/kg) intravenously did not differ from cows receiving 6 mg/kg in elimination half-life and other distribution and elimination kinetic parameters. Based on the experimental data obtained, a dosage regimen is proposed, consisting of a priming oral dose of 9 mg/kg and maintenance doses of 4.5 mg/kg of phenylbutazone orally administered at 48 h intervals. The relatively long half-life in cattle, however, complicates the use of phenylbutazone because of the drug residue problem.     

Pharmacokinetics of cefotaxime and probenecid in sheep with normal and reduced renal function

The pharmacokinetics of cefotaxime and probenecid, given by intravenous injection, were determined in six Merino ewes which had been subjected to a 75% reduction in renal mass. These results were compared with results previously determined in sheep with normal renal function. In the sheep with reduced renal mass, the following significant changes in parameter values for cefotaxime were observed. The elimination rate constant (kel) decreased by 47%, the apparent volume of the central compartment (Vc) decreased by 59%, the steady state volume (Vss) decreased by 50%, and the total body clearance (ClB) decreased by 78%. The rate constant for distribution of drug into tissues (k12) increased 6.9 times, the rate constant for distribution out of tissues (k21) increased 3.7 times, and the area under the plasma concentration-time curve (AUC) increased by a factor of 4.9. The parameter values, determined in sheep with reduced renal mass, for probenecid plasma half-life, Vss and the rate constants k12, k21, and kel were not significantly different from the values obtained previously in sheep with normal renal mass. However, the rate constant for renal excretion of probenecid (ke), renal clearance (ClR), ClB and Vc decreased by 79, 90, 54 and 36%, respectively. The results indicate that reduced renal mass increased the plasma half-life for cefotaxime as well as increasing its diffusion into tissue. In the case of probenecid the overall distribution and elimination kinetics were not altered by reduced renal mass; however, the rate of urinary excretion of the drug was reduced.     

Pharmacokinetics and tissue residue profiles of erythromycin in broiler chickens after different routes of administration

This study investigated the disposition kinetics and plasma availability of erythromycin in broiler chickens after single intravenous (i.v.), intramuscular (i.m.), subcutaneous (s.c.) and oral administrations (p.o.) of 30 mg kg(-1) b. wt. Tissue residue profiles were also studied after multiple intramuscular, subcutaneous, and oral administration of 30 mg kg(-1) b. wt., twice daily for three consecutive days. Plasma and tissue concentrations of erythromycin were determined using microbiological assay methods with Micrococcus luteus as the test organism. Following intravenous injection, plasma concentration-vs-time curves were best described by a two compartment open model. The decline in plasma drug concentration was bi-exponential with half-lives of (t(1/2alpha)) 0.19 h and (t(1/2beta)) 5.3 h for distribution and elimination phases, respectively. After intramuscular, subcutaneous and oral administration erythromycin at the same dose was detected in plasma at 10 min and reached its minimum level 8 h post-administration. The peak plasma concentration (Cmax) were 5.0, 5.3, and 6.9 microg x ml(-1) and were attained at 1.7, 1.4, and 1.3 h (Tmax), respectively. The elimination half-lives (T(1/2el)) were 3.9, 2.6, and 4.1 h and the mean residence times (MRT) were 3.5, 3.2, and 3.6 h, respectively. The systemic bioavailabilities were 92.5, 68.8, and 109.3%, respectively. In vitro protein binding percent of erythromycin in broiler plasma was ranged from 21 to 31%. The limit of quantification (LOQ) for the assay was 0.03 microg x ml(-1) in plasma and tissues. The tissue level concentrations were highest in the liver, and decreased in the following order: plasma > kidney > lung > muscle and heart. No erythromycin residues were detected in tissues and plasma after 24 h except in liver and kidney where it persisted during 48 h following intramuscular and oral administrations.     

Tissue distribution and disposition kinetics of enrofloxacin in healthy and E. coli infected broilers

Concentrations of enrofloxacin equivalent activity were determined by microbiological assay in the plasma of healthy and E. coli-infected broilers following single intravenous and oral administrations at 10 mg/kg. Tissue distribution and residue-depletion following multiple oral doses (10 mg/kg for 3 successive days) were investigated. Pharmacokinetic variables were determined using compartmental and non-compartmental analytical methods. Plasma enrofloxacin concentrations after intravenous dosing to healthy and infected birds were best described by a two-compartments model. Enrofloxacin concentrations in plasma of infected birds were lower than those of healthy ones. The disposition kinetics of intravenously administered drug in healthy and infected birds were somewhat different. The elimination half-life (t1/2 beta) was 4.75 vs. 3.63 h; mean residence time (MRT) was 6.72 vs 4.90 h; apparent volume of the central compartment (Vc) was 1.11 vs 1.57 l/kg; rate constant for transfer from peripheral to central compartment (k21) was 1.15 vs 1.41 h-1 and total body clearance (ClB) was 0.35 vs 0.53 l/h/kg in healthy and infected birds, respectively. After oral administration, the absorption half-life (t1/2abs) in the infected birds was significantly longer than in healthy birds, while elimination half-life (t1/2el) and MRT were significantly shorter. Bioavailability was higher in infected birds (72.50%) as compared to healthy ones (69.78%). Enrofloxacin was detected in the tissues of healthy and infected birds after daily oral dosing of 10 mg/kg for 3 days. It was more concentrated in liver, kidney, and breast muscle. The minimal inhibitory concentration (MIC) of enrofloxacin against E. coli was 0.064 microgram/ml. On the basis of maintaining enrofloxacin plasma concentrations over the MIC, a dose of 10 mg/kg given intravenously every 20.14 hrs or orally every 20.86 hrs should provide tissue concentrations effective against E. coli infection in chickens.     

Influence of a pig respiratory disease on the pharmacokinetic behaviour of amoxicillin after oral ad libitum administration in medicated feed

The pharmacokinetic properties of amoxicillin in healthy and respiratory-diseased pigs were studied, after ad libitum administration of medicated feed. In addition, amoxicillin dose linearity and drug penetration into respiratory tract tissues were evaluated in diseased animals. The respiratory disease involves porcine reproductive and respiratory syndrome virus and bacterial agents such as Pasteurella multocida, Bordetella bronchiseptica and Streptococcus suis. Typical clinical signs and gross lesions of respiratory disease were observed. The plasma pharmacokinetic analysis was performed by means of a noncompartmental approach. After single intravenous bolus administration of amoxicillin to healthy pigs, the steady-state volume of distribution was 0.61 L/kg, the total plasma clearance was 0.83 L/h/kg and the mean residence time was 0.81 h. After oral bolus administration, the mean absorption time was 1.6 h and the peak plasma concentration (3.09 μg/mL) reached at 1.1 h postadministration. The oral bioavailability was 34%. For oral ad libitum administration, plasma concentration-time profiles were related to the feeding behaviour. Plasma concentrations at steady-state were established between 12 and 120 h. The pharmacokinetic parameters calculated (C(maxss) , C(minss) , C(avss) and AUC(24ss) ) showed significantly lower values in healthy pigs compared to diseased animals. This was in accordance with the significantly higher amoxicillin bioavailability (44.7% vs. 14.1%) and longer absorption period observed in diseased pigs. Amoxicillin dose linearity in diseased animals was established in a dose range of 4-18 mg/kg. On the other hand, tissue distribution ratio in diseased animals was 0.65 for bronchial mucosa, 0.48 for lung tissue and 0.38 for lymph nodes. Our results suggest that the pharmacokinetic properties and disposition of amoxicillin can be influenced by the disease state or by related factors such as changes in the gastrointestinal transit.     

Tissue distribution of clenbuterol in the horse

Plasma and tissue concentrations of clenbuterol (CLB) were determined following oral (p.o.) administration of 1.6 microg/kg twice daily (b.i.d.) for 2 weeks. Horses were administered the last dose on morning of day 15, killed at 0.25, 24, 48, and 72 h post-administration. At 0.25 h, the highest tissue concentrations of CLB were found in the liver (16.21 ng/g), lung (6.48 ng/g), left ventricle (4.99 ng/g), kidney (3.35 ng/g), bronchi (2.56 ng/g), right ventricle (2.08 ng/g), and eye fluids (1.09 ng/g) all of which were higher than that of plasma (1.10 ng/mL). The elimination half-lives (t(1/2k)) for CLB in tissues ranged from 21.2 to 56.3 h, the longest were in the eye fluids (56.9 h), spleen (21.2 h), cerebrum (27.1 h), cerebellum (21.5) and cecum (23.7 h). The t(1/2k) for plasma was 10.9 h. Tissue/plasma ratios of liver (14.7), lung (5.9), left ventricle (4.6), kidney (3.1), bronchi, (2.3) and right ventricle (1.9) were high at 0.25 h and remained elevated up to 72 h. Accumulation and sustained high concentration of CLB relative to plasma in these tissues contributed to the prolonged elimination and the ability to quantify CLB in plasma and urine for a prolonged period.     

Mass medication in reducing shipping fever-bovine respiratory disease complex in highly stressed calves

One thousand and eighty-five newly received, stressed calves were used in studies to determine the effectiveness of certain mass medication procedures for reducing morbidity from shipping fever-bovine respiratory disease complex. In two experiments, im injections of oxytetracycline at 11 mg/kg body wt for 3 successive days reduced treatment days/calf purchased 21 (P less then .05) and 31% (P less than .05). Oral administration of 150 mg of sulfadimethoxine/kg body wt reduced treatment days/calf purchased 20 (P less than .05) and 54% (P less than .05) in the same two experiments. When sulfadimethoxine followed oxytetracycline on the third injection day an 81% reduction in treatment days/calf purchased was obtained, indicating an additive effect of the two drugs. The use of long acting oxytetracycline and sustained release sulfadimethoxine at the time of processing resulted in a 90% reduction in treatment days/calf purchased (P less than .01) and required only one handling of the calves for mass medication purposes.     

Distribution of orally administered trimethoprim and sulfadiazine into noninfected subcutaneous tissue chambers in adult ponies

The distribution of trimethoprim (TMP) and sulfadiazine (SDZ) into subcutaneously implanted noninfected tissue chambers was studied in healthy adult ponies. Six ponies were given an oral TMP/SDZ paste formulation at a dose of 5 mg/kg TMP and 25 mg/kg SDZ at 12 h intervals for 2 days in order to reach steady-state concentrations. Plasma concentrations and tissue chamber fluid (TCF) concentrations of both drugs were measured at regular intervals during a period commencing 24 h after the last oral administration. The peak concentration of TMP (mean +/- SD) was 2.92 +/- 0.86 microg/mL for plasma and 1.09 +/- 0.25 microg/mL for TCF. For SDZ, the mean peak concentration was 40.20 +/- 14.74 microg/mL for plasma and 23.48 +/- 5.84 microg/mL for TCF. TMP peak concentrations in plasma were reached at 3.17 +/- 03.48 h and those in TCF at 7.33 +/- 03.72 h. SDZ peak concentrations in plasma were reached at 1.83 +/- 02.04 h and those in TCF at 8.00 +/- 03.10 h. Concentrations of TMP and SDZ in TCF remained above the generally accepted breakpoint for susceptibility (0.5/9.5 for the TMP/SDZ combination) for 12 h. Therefore, in ponies oral administration of TMP/SDZ at a dose rate of 30 mg/kg given twice daily in the form of a paste should be appropriate for effective treatment of infections caused by susceptible bacteria.     

Pharmacokinetic/pharmacodynamic modelling of roxithromycin for the inhibitory effect of tumour necrosis factor-alpha and interleukin-6 production in dogs

The objective of the present study was to determine and characterize the relationship between the plasma concentration of roxithromycin, and its inhibitory effect on cytokine production, in order to predict its possible clinical relevance. Six healthy beagle dogs received a single intravenous dose of 20-mg roxithromycin per kg body weight. Blood samples were obtained at different time points. The plasma was analysed with respect to roxithromycin, tumour necrosis factor-alpha (TNF-alpha) and interleukin-6 (IL-6). The concentration-effect relationship was explored by modelling the data using two compartmental model and an indirect response model with an E(max) concentration-effect relationship. The estimated pharmacokinetic parameters (geometric mean) were as follows: V(c) = 2.59 l; k(10) = 0.08/h; k(12) = 0.26/h; k(21) = 0.40/h. The pharmacodynamic parameters (geometric mean) for the inhibitory effect on cytokine production induced by heat-killed Staphylococcus aureus (HKSA) were for TNF-alpha (k(in) = 1.42 microg/h; k(out) = 1.10 microg/h; EC(50) > 5.69 mg/l) and for IL-6 (k(in) = 2.31 microg/h; k(out) = 2.04 microg/h; EC(50) = 21.07 mg/l) production, respectively. The inhibitory effect of roxithromycin on production can be adequately described by the indirect response model with an E(max) concentration-effect relationship.     

Ormetoprim-sulfadimethoxine in cattle: pharmacokinetics, bioavailability, distribution to the tears, and in vitro activity against Moraxella bovis

The pharmacokinetics, bioavailability, and distribution to the tears of ormetoprim (OMP; 5.5 mg/kg of body weight) and sulfadimethoxine (SDM; 27.5 mg/kg of body weight) were determined following IV or oral administration to 6 Holstein steers. After IV administration, the disposition kinetics of both drugs were best described by a 2-compartment open model. Sulfadimethoxine had a moderately rapid distribution phase, followed by a slower elimination phase, with a mean half-life (t 1/2) of 7.91 hours. The mean volume of distribution of SDM was 185 ml/kg, and the mean body clearance was 0.28 ml/min X kg. The concentration of SDM in tears was lower than the corresponding plasma concentration, and the elimination of SDM from tears (t 1/2 = 3.02 hours) was significantly faster than its elimination from plasma (t 1/2 = 7.91 hours). The disposition of OMP administered IV was characterized by a rapid distribution phase, followed by a rapid elimination phase (t 1/2 = 1.37 hours). The high values of the mean volume of distribution (1,450 ml/kg) and mean rate of body clearance (13.71 ml/min X kg) indicated that OMP was widely distributed in the body and was rapidly cleared from the body. Ormetoprim concentrations in tears exceeded corresponding plasma concentrations, and the elimination of OMP from tears was significantly slower (t 1/2 = 1.91 hours) than from plasma (t 1/2 = 1.37 hours). After oral administration of an OMP-SDM combination in bolus form, the absorption of SDM was slow (absorption t 1/2 = 3.32 hours), but complete.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetic interpretation of erythromycin and tylosin activity in serum after intravenous administration of a single dose to cows.

The distribution and elimination kinetics of erythromycin and tylosin, which are macrolide antibiotics, were studied in healthy cows. A single dose (12-5 mg/kg) of drug was administered as an intravenous bolus, and blood samples were collected at precisely timed intervals. The standard cylinder plate bioassay method using Sarcina lutea as test organism was employed to determine antibiotic activity in the serum. The results suggested that these drugs are distributed in at least two kinetically distinct body compartments. By use of established mathematical techniques, values were assigned to the individual rate constants controlling distribution between the central and peripheral compartments and to the rate constant controlling overall elimination (beta) of each drug from the body. The calculated overall tissue to serum drug level ratios (k12/k21) after apparent distribution equilibrium was attained were 2-28 and 2-05 for erythromycin and tylosin, respectively. The half-life (mean+/-SD) of erythromycin was 3-16 h+/-0-44, while that of tylosin was 1-62 h+/-0-17. The total body clearance (ml/kg/min) values were 2-88+/-0-47 for erythromycin and 7-8+/-2-95 for tylosin. Analogue computer simulated curves of the antibiotic levels in the central and tissue compartments as wel as an elimination curve were generated. The tissue level of erythromycin reached a peak of 43 per cent of the dose at 67 min. At 6 h, the percentages of the dose of erythromycin in the central and tissue compartments and eliminated were 6, 19 and 75, respectively. The peak level of tylosin in the tissue compartment (26-5 per cent of the dose) was present at 30 min. At 4 h, 1 and 5 per cent of the dose were contained in the central and peripheral compartments, respectively, while 94 per cent had been eliminated. This single dose study provides information which is essential for the design of a satisfactory dosage regimen.     

A study of the pharmacokinetics and tissue residues of an oral trimethoprim/sulphadiazine formulation in healthy pigs

Twenty-six healthy female pigs weighing 19.5-33 kg were used in three separate experiments. The animals were fed individually twice a day. Trimethoprim/sulphadiazine (TMP/SDZ) formulation was added to feed in the amount of 6 mg/kg bw (TMP) and 30 mg/kg bw (SDZ). TMP and SDZ concentrations in blood plasma, muscles, liver and kidneys were measured. Pharmacokinetic parameters show that the absorption of TMP from the alimentary tract in pigs is faster than the absorption of SDZ, and the elimination of TMP is slower than that of SDZ. The absorption half-lives were 0.96 (TMP) and 2.24 h (SDZ), whereas elimination half-lives were 5.49 (TMP) and 4.19 h (SDZ). The observed TMP:SDZ ratios in blood plasma after multiple dose administration ranged from 1:11.4 to 1:23.2. One day after administration of the last dose of TMP/SDZ the plasma concentration ratio was 1:15.5, but in muscles, liver and kidneys it was much lower: 1:0.79, 1:0.14 and 1:1.53 respectively. The absolute TMP and SDZ tissue concentrations 1 day after the last multiple dose administration were very low (maximum TMP: 0.29 μg/g in liver; maximum SDZ: 0.23 μg/g in kidneys). Neither drug was detected in any tissue 8 days after the last administration of TMP/SDZ. Based on our results, it was concluded that there is no support for the TMP:SDZ pharmaceutical ratio 1:5 in oral formulations of these compounds for pigs. The administration of oral TMP/SDZ formulations once a day may result in the absolute tissue concentrations of these drugs being too low for antibacterial activity. The withdrawal period for such an oral TMP/SDZ formulation for pigs (according to accepted guidelines in Europe for MRL of TMP < 0.05 mg/kg of tissue) should not be less than 5 days.     

The Plasma Kinetics and Tissue Distribution of Enrofloxacin and its Metabolite Ciprofloxacin in the Muscovy Duck

Intorre, L., Mengozzi, G., Bertini, S., Bagliacca, M., Luchetti, E. and Soldani, G., 1997. The plasma kinetics and tissue distribution of enrofloxacin and its metabolite ciprofloxacin in the Muscovy duck. Veterinary Research Communications, 21 (2), 127-136The disposition and tissue distribution of enrofloxacin and of its main metabolite ciprofloxacin were investigated in ducks after oral or intramuscular administration of a single dose of 10 mg/kg enrofloxacin. Plasma and tissue concentrations were determined by a HPLC method. The peak concentrations of enrofloxacin after intramuscular administration (1.67 µg/ml at 0.9 h) were higher than after an oral dose (0.99 µg/ml at 1.38 h). The relative bioavailability of enrofloxacin after administration directly into the crop was 68%, while the metabolic conversion of enrofloxacin to ciprofloxacin was quite low (<10%) with both routes of administration. High tissue concentrations and high tissue:plasma concentration ratios were demonstrated for enrofloxacin and ciprofloxacin 24 h after treatment. It was concluded that a dose of 10 mg/kg per day provides serum and tissue concentrations sufficiently high to be effective in the control of many infectious diseases of ducks.