Disposition of parathion after dermal application in pigs*

Pharmacokinetic parameters of parathion were studied in pigs after intravenous (i.v,) and dermal administration of unlabelled and ‘“C-parathion. Plasma concentration-time data were subjected to non-compartmental analysis. Intravenous injection studies showed a mean residence time (MRT) of 2.15 h, a body clearance (Cl_B) of 4.4 l/kg/h and a volume of distribution (V_ss) of 9.8 l/kg. Dermal application led to a mean absorption time (MAT) of 78 h. and a bioavailability of 9.9%. Plasma levels of ¹⁴C-parathion (parathion + metabolites) were much higher and more persistent than those of parathion itself. After i.v. administration, recovery of ¹⁴C-parathion from urine plus faeces was almost 100% within 3 d, while it was less than 20% after dermal application. Ten days after dermal application high I4C concentrations remained in the back skin, i.e. the application area. In skin samples from areas where contamination from the application area could not have occurred, the ¹⁴C-parathion concentration was as low as 2 μg/g. It is concluded that in view of the low dermal bioavailability for organophosphorus insecticides it is unlikely that pour-on preparations containing these insecticides reach the ectoparasites through absorption and systemic distribution, but rather that this happens after spreading on the surface of the skin.     

Synthesis and detection of toltrazuril sulfone and its pharmacokinetics in horses following administration in dimethylsulfoxide

Triazine-based antiprotozoal agents are known for their lipophylic characteristics and may therefore be expected to be well absorbed following oral administration. However, although an increase in lipid solubility generally increases the absorption of chemicals, extremely lipid-soluble chemicals may dissolve poorly in gastrointestinal (GI) fluids, and their corresponding absorption and bioavailability would be low. Also, if the compound is administered in solid form and is relatively insoluble in GI fluids, it is likely to have limited contact with the GI mucosa, and therefore, its rate of absorption will be low. Based on the above considerations, we sought a solvent with low or no toxicity that would maintain triazine agents in solution. As the oral route is most preferred for daily drug therapy, such a solvent would allow an increased rate of absorption following oral administration. In present study, it was demonstrated that dimethylsulfoxide (DMSO) increased the oral bioavailability of toltrazuril sulfone (Ponazuril) threefold, relative to oral administrations of toltrazuril sulfone suspended in water. The cross-over study of toltrazuril sulfone formulated in DMSO indicated that the absolute oral bioavailability of toltrazuril sulfone in DMSO is 71%. The high bioavailability of the DMSO-preparation suggests that its daily oral administration will routinely yield effective plasma and cerebral spinal fluid (CSF) concentrations in all horses treated. Also, this improved formulation would allow clinicians to administer loading doses of toltrazuril sulfone in acute cases of Equine Protozoal Myeloencephalitis. Another option would involve administration of toltrazuril sulfone in DMSO mixed with feed (1.23 kg daily dose) meeting the US Food and Drug Administration (FDA) recommendations for the levels of DMSO permissible in pharmaceutical preparations.     

New therapeutic approaches for equine protozoal myeloencephalitis: pharmacokinetics of diclazuril sodium salts in horses

Diclazuril is a triazine-based antiprotozoal agent which may have clinical application in the treatment of equine protozoal myeloencephalomyelitis (EPM). In this study, the use of the sodium salt diclazuril to increase the apparent bioavailability of diclazuril for the treatment and prophylaxis of EPM and various other Apicomplexan mediated diseases is described. In this study, diclazuril sodium salt was synthesized and administered to horses as diclazuril sodium salt formulations. The absorption, distribution, and clearance of diclazuril sodium salt in the horse are described. Diclazuril was rapidly absorbed, with peak plasma concentrations occurring at 8-24 hours following an oral mucosal administration of diclazuril sodium salt. The mean oral bioavailability of diclazuril as Clinacox was 9.5% relative to oral mucosal administration of diclazuril sodium salt. Additionally, diclazuril in DMSO administered orally was 50% less bioavailable than diclazuril sodium salt following an oral mucosal administration. It was also shown that diclazuril sodium salt has the potential to be used as a feed additive for the treatment and prophylaxis of EPM and various other Apicomplexan mediated diseases.     

Disposition and bioavailability of neomycin in Holstein calves

Pedersoli, W.M., Ravis, W.R., Jackson, J., Shaikh, B. Disposition and bioavailability of neomycin in Holstein calves. J. vet. Pharmacol. Therap. 17 , 5–11.
The disposition and absorption kinetics of neomycin were studied in healthy ruminating dairy calves ( n -6), approximately 3-months-old. The calves were treated with single intravenous (i.v.) (12 mg/kg), intramuscular (i.m.) (24mg/kg), oral (p.o.) (96 mg/kg) and repeated p.o. (96 mg/kg, b.i.d., 15½ days) doses of neomycin. A 3-week rest period was allowed between treatments A and B and B and C Baseline and serial venous blood samples were collected from each calf plasma concentrations of neomycin were determined by a high performance liquid chromatography procedure. The resulting data were evaluated by using compartmental pharmacokinetic models and nonlinear least squares regression analysis. The mean of some selected parameters were t ½λ3 7.48 ± 2.02 h, Cl_t= 0.25 ± 0.04 L/h/kg, V _d(ss)= 1.17 ± 0.23 L/kg, and MRT = 4.63 ± 0.87 h for the i.v. data and t _½= 11.5 ± 3.8 h, MRT _abs= 0.960 ± 1.001 h, F = 127 ± 35.2%, and Cl_t/F = 0.199 ± 0.047 L/h/kg for the i.m. data, respectively. Only one calf absorbed neomycin to any significant degree (F = 0.0042) after a single p.o. dose. Selected mean parameters determined after repeated oral dosing were: F = 0.45 ± 0.45%, C_max= 0.26 ± 0.37 g/ml, and t_max= 2.6 ± 2.9 h. Terminal half-lives determined for the i.v. and i.m. treatments were considerably longer than those reported previously in the literature.     

Bioavailability of detomidine administered sublingually to horses as an oromucosal gel

Kaukinen, H., Aspegrén, J., Hyyppä, S., Tamm, L., Salonen, J. S. Bioavailability of detomidine administered sublingually to horses as an oromucosal gel. J. vet. Pharmacol. Therap. 34 , 76–81. The objective of the study was to determine the absorption, bioavailability and sedative effect of detomidine administered to horses as an oromucosal gel compared to intravenous and intramuscular administration of detomidine injectable solution. The study was open and randomized, with three sequences crossover design. Nine healthy horses were given 40 μg/kg detomidine intravenously, intramuscularly or administered under the tongue with a 7‐day wash‐out period between treatments. Blood samples were collected before and after drug administration for the measurement of detomidine concentrations in serum. The effects of the route of administration on heart rate and rhythm were evaluated and the depth of sedation assessed. Mean (±SD) bioavailability of detomidine was 22% (±5.3%) after sublingual administration and 38.2% (±7.9%) after intramuscular administration. The sedative effects correlated with detomidine concentrations regardless of the route of administration. We conclude that less detomidine is absorbed when given sublingually than when given intramuscularly, because part of it does not reach the circulation. Sublingual administration of detomidine oromucosal gel at 40 μg/kg produces safe sedation in horses. Slow absorption leads to fewer and less pronounced adverse effects than the more rapid absorption after intramuscular injection.     

Effects of ischemia and dimethyl sulfoxide on equine jejunal vascular resistance, oxygen consumption, intraluminal pressure, and potassium loss

Physiologic effects of 1 hour of ischemia and 1 hour of reperfusion on equine jejunum and protective effects of systemic administration of dimethyl sulfoxide (DMSO, 1 g/kg of body weight) were investigated in 18 ponies, using neurally intact segments of jejunum perfused at constant flow with heparinized blood. Ponies were allotted to 4 groups: group 1, saline solution administered (control, n = 3); group 2, DMSO administered (DMSO, n = 3); group 3, ischemia induced and saline solution administered (ischemia, n = 6); and group 4, ischemia induced and DMSO administered (ischemia-DMSO, n = 6). Intestinal vascular resistance (R, mm of Hg/ml/min/100 g), oxygen consumption (VO2, ml/min/100 g), frequency and amplitude of rhythmic changes in intraluminal pressure, intestinal compliance (C, ml/mm of Hg), and arteriovenous potassium concentration difference (delta AV [K+], mEq/L) were determined and compared with stable preischemic values within groups. There were no significant changes in any variable in ponies of groups 1 or 2. In ponies of group 3, significant (P less than or equal to 0.05) changes included: an initial increase in R during reperfusion, followed by a decrease to values below preischemic values by 15 minutes of reperfusion; decreased VO2 during the entire reperfusion period; increased amplitude of rhythmic contractions during initial reperfusion; decreased frequency of rhythmic contractions during ischemia; and increased delta AV [K+] during initial reperfusion. Changes in ponies of group 4 were identical to changes in ponies of group 3, with the exception that DMSO administration prevented the decrease in R during reperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics and bioavailability of oral firocoxib in adult,mixed‐breed goats

Pharmacokinetic (PK) studies of oral firocoxib in large animal species have been limited to horses, preruminating calves, and adult camels. The aim of this study was to describe pharmacokinetics and bioavailability of firocoxib in adult goats. Ten healthy adult goats were administered 0.5 mg/kg firocoxib intravenously (i.v.) and per os (p.o.) in a randomized, crossover study. Plasma firocoxib concentrations were measured over a 96‐hr period for each treatment using HPLC and mass spectrometry, and PK analysis was performed. The p.o. formulation reached mean peak plasma concentration of 139 ng/ml (range: 87–196 ng/ml) in 0.77 hr (0.25–2.00 hr), and half‐life was 21.51 hr (10.21–48.32 hr). Mean bioavailability was 71% (51%–82%), indicative of adequate gastrointestinal absorption of firocoxib. There were no negative effects observed in any animal, and all blood work values remained within or very near reference range at the study's conclusion. Results indicate that oral firocoxib is well‐absorbed and rapidly reaches peak plasma concentrations, although the concentration also decreased quickly prior to the terminal phase. The prolonged half‐life may suggest tissue accumulation and higher plasma concentrations over time, depending on dosing schedule. Further studies to determine tissue residue depletion, pharmacodynamics, and therapeutic concentrations of firocoxib in goats are necessary.     

Pharmacokinetics and pharmacodynamics of protamine zinc recombinant human insulin in healthy dogs

Protamine zinc insulins are generally considered to be long acting, with slow absorption from subcutaneous tissue. Protamine zinc recombinant human insulin (PZIR) may be useful to treat diabetic dogs. The purpose of this study was to describe the pharmacokinetics and pharmacodynamics of PZIR in dogs. PZIR was administered subcutaneously to 10 healthy Beagles using an incomplete crossover design, at doses of 0.3 or 0.5 U/kg (each n=5), 0.8 U/kg (n=10), or 0.8 U/kg at three separate sites (n=6). Insulin and glucose concentrations were measured over 24 h. The shapes of insulin and glucose curves were variable among dogs, and the relationship between insulin dose, concentration, and glucose-lowering effect was nonlinear. For single-site 0.8 U/kg, median (range) onset of action was 3.5 h (0.5-10 h), time to glucose nadir was 14 h (5 to >24 h), and duration of action was >24 h (16 to >24 h). Mathematical model predictions of times to 50% and 90% insulin absorption, and fraction of insulin absorbed in 24 h, were not significantly different among protocols. Results confirm the tendency toward a late onset and long duration of action for PZIR in dogs. This insulin may be an alternative treatment option for diabetic dogs.     

Percutaneous absorption of topical parathion through porcine skin: in vitro studies on the effect of environmental perturbations

Topical use of pesticides in domestic animals such as swine is a common practice: however, the effect of environmental factors on the extent of absorption has not received attention. Since no single factor can exert its effects alone in the natural environment, the interaction of environmental factors on the percutaneous absorption of pesticides must be understood before potential toxicity of dermal absorption of pesticides can be effectively estimated. In the present studies, the effects of air temperature ( Ta) , perfusate temperature (Tp), perfusate flow (F) and relative humidity (%RH) on absorption of parathion were studied in vitro in porcine skin. Parathion absorption was determined by measuring radiolabel appearing in the perfusate over time. Three main environmental parameters were found to have a significant effect on parathion penetration. Increasing T, from 37'C to 42^oC %RH from 60% to 90% or F from 4 ml/h to 8 ml/h each produced a significant increase in penetration. The following significantly positive two-way interactions among test parameters were seen: T, x F and %RH x F at the 4 μg dose, % RH × F at the 40 μg dose and T, × %RH, T, x F and %RH × F at the 400 μg dose. There were no three-way interactions at any of the three doses tested. These results suggest that the factors tested are not independent variables and must be considered interactive when used in assessing pesticide percutaneous absorption.     

Pharmacokinetics of phenytoin (diphenylhydantoin) in horses

The pharmacokinetics of the anti-convulsant phenytoin were investigated in clinically healthy horses after oral (p.o.) and intravenous (i.v.) administration. A single dose of phenytoin (8.8 mg/kg body weight) was given i.v. as a bolus to nine horses and one horse received 13.2 mg/kg. A two-compartment open model was used to describe the disposition of phenytoin. Four of the horses that received an i.v. dose (three at 8.8 mg/kg and one at 13.2 mg/kg) were then given the same dose 3 days later by the oral route. Phenytoin achieved a peak concentration in serum within 1–4 h after p.o. administration and was poorly absorbed with a bioavailability of 34.5 ± 8.6%. Oral dosage regimens were calculated on the basis of a dosing interval of 8 h to provide average serum steady-state concentrations of 5 and 10 μg/ml for phenytoin.     

Pharmacokinetics of cimetidine in dogs after oral administration of cimetidine tablets

Long-term oral treatment with cimetidine is recommended to reduce vomiting in dogs with chronic gastritis. Despite this, few studies have specifically examined the plasma disposition and pharmacokinetics of cimetidine in dogs, particularly following repeated oral administration. The pharmacokinetics of cimetidine following oral administration as tablets was investigated in healthy dogs. Cimetidine was absorbed rapidly post-treatment ( t _max = 0.5 h). A mean absolute bioavailability of 75% was calculated following a single oral administration of 5 mg cimetidine/kg body weight. After intravenous administration, a plasma half-life of 1.6 h was calculated. Repeated oral administration at the recommended dose rate and regime (5 mg/kg body weight three times daily) for 30 consecutive days did not lead to any accumulation of cimetidine in plasma. Food intake concomitant with oral administration of cimetidine delayed ( t _max = 2.25 h) and decreased the rate and extent of absorption ( AUC ) by about 40%. Cimetidine was well absorbed in fasted dogs. Administration of food decreased the bioavailability of cimetidine by 40%. Cimetidine does not accumulate over time in plasma when administered long term to dogs.     

Pharmacokinetics of ceftazidime administered to lactating and non-lactating goats

The aim of this work was to determine the pharmacokinetics of intravenous (i.v.) and intramuscular (i.m.) ceftazidime administered to lactating (LTG; n=6) and non-lactating (NLTG; n=6) healthy Creole goats in 2 trials (T1 and T2). During T1 and T2, goats randomly received a single dose of i.m. or i.v. ceftazidime (10 mg/kg). Serum concentration of iv ceftazidime in NLTG and LTG goats is best described by 2 and 3 compartment models, respectively. The pharmacokinetic parameters of iv and im ceftazidime administered to LTG and NLTG showed statistically significant differences (P < 0.05) in the constants (lamda(z), T1 vs. T2 [i.v.] 0.5 +/- 0.1 vs. 0.3 +/- 0.1/h; T1 vs. T2 [i.m.] 0.5 +/- 0.2 vs. 0.3 +/- 0.1/h) and in the mean times (t(1/2), T1 vs. T2 [i.v.] 1.6 +/- 0.3 vs. 2.3 +/- 0.6 h; T1 vs. T2 [i.m.] 1.6 +/- 0.7 vs. 2.6 +/- 0.9 h) of elimination. The bioavailability of ceftazidime in LTG and NLTG was 113.0 +/- 17.8 and 96.0 +/- 18.0%, respectively. Ceftazidime concentration in milk at 2 h was: i.v. = 1.9 +/- 0.2 and i.m. = 2.4 +/- 0.5 microg/ml; the penetration in milk was i.v. = 18.3 +/- 13.5 and im = 14.3 +/- 10.6%. Ninety-six hours after i.v. and i.m. administration, residues of the drug were not found in milk. In conclusion, ceftazidime, when administered to goats, showed high concentration times in serum, good penetration into milk and a bioavailability that makes it suitable to be used by the i.m. route.     

Uptake and excretion of organochlorine compounds in neonatal calves

Intestinal absorption mechanisms of young calves change rapidly during the first 24 h postpartum and subsequently effect the absorption efficiencies of a wide range of compounds. This study was conducted to determine absorption efficiencies of (p,p'-dichlorodiphenyl)dichloroethylene (DDE), 2,2',4,4',5,5'-hexachlorobiphenyl (PCB-153), and 1,2,3,4,6,7,8,9-octachlorodibenzo-p-dioxin (OCDD) when administered in colostrum to neonatal calves. Four male Holstein calves were given a single oral dose containing 100 mg each of DDE, PCB-153, and OCDD either 1 h (n = 2) or 65 h (n = 2) postpartum to determine whether time of exposure influenced the rate or extent of absorption. Another male calf received 100 mg each of DDE and OCDD 1 h postpartum. One gram of chromic oxide (Cr2O3) was administered as a digestion marker to dosed calves. Two male calves, receiving only colostrum, served as controls. Serum IgG concentrations indicated that the 1-h calves absorbed 20 to 37% of the ingested IgG and 65-h calves < 2%; therefore, the gut absorption mechanisms had changed by 65 h. Plasma DDE, PCB-153, and OCDD profiles did not differ based on time of exposure, suggesting that their mechanism of absorption was not influenced by the changing gut. Trapezoidal area under the curve to the last time point values indicated that, during the trial, relative plasma organochlorine concentrations amounted to PCB-153 > DDE > OCDD. Tissue concentrations were similar across treatment groups, with DDE and PCB-153 residues concentrating in adipose tissue and OCDD in the liver. Absorption efficiencies, calculated from fecal recoveries, were >97%, >74%, and >72% for DDE, PCB-153, and OCDD, respectively. These doses of DDE, PCB-153, and OCDD (2.5 +/- 0.1 mg/kg) did not produce signs of toxicosis based on detailed clinical observations, serum clinical chemistry, and gross and histological observations at necropsy. The results of this study indicate that DDE, PCB-153, and OCDD were absorbed and distributed similarly in calves exposed 1 or 65 h postpartum and did not induce toxicosis when administered in combination at these concentrations.     

Pharmacokinetics of Ricobendazole After its Intravenous,Intraruminal and Subcutaneous Administration in Sheep

Ricobendazole (RBZ) was administered in sheep at the dose rate of 5 mg/kg by intravenous (i.v.) route as a 10% experimental solution, by the intraruminal (i.r.) route as a 10% experimental suspension, and by the subcutaneous (s.c.) route as a 10% commercial formulation available in Argentina. Blood samples were drawn during a 60 h period. Plasma concentrations of RBZ and its inactive metabolite albendazole sulphone (ABZSO₂) were determined by high-performance liquid chromatography. The pharmacokinetic parameters were determined by compartmental analysis. The fitting of the data was done by weighted least-squares non-linear regression analysis. The pharmacokinetic parameters were estimated for every animal by simultaneous fitting of the plasma concentrations profiles of RBZ obtained after its administration by the three routes. The kinetic analysis of ABZSO₂ was performed by a statistical moment approach. Ricobendazole bioavailability was poor after i.r. administration, whereas high and sustained plasma concentrations and higher bioavailability were obtained after s.c. administration. A simple two-compartment open model explains in a mechanical sense the pharmacokinetic behaviour of RBZ in sheep and allows us to estimate the real first-order constant rate of absorption and the loss of drug from the absorption site after its administration by s.c. and i.r. routes.     

Serum and milk concentrations of apramycin in lactating cows, ewes and goats

A 20% solution of apramycin was administered intravenously (j.v.) and intramuscularly (i.m.) to lactating cows with clinically normal and acutely inflamed udders, to lactating ewes with normal or subclinically infected, inflamed udders and i.v. to lactating goats with normal udders. The i.v. disposition kinetics of apramycin was very similar in cows, ewes and goats. The elimination half-life was approximately 2 h and the steady-state volume of distribution was 1.26–1.45 L/kg. The absorption rate of the drug from the i.m. injection site was rapid, the i.m. bioavailability was 60–70% and the mean elimination half-life was 265 min in cows and 145.5 min in ewes. The binding percentage of apramycin to serum protein was low (< 22.5%). Concentrations of apramycin in milk produced by clinically normal mammary glands of cows, ewes and goats were consistently lower than in serum; the kinetic value AUC _milk/ AUC _serum was < 0.32. Drug penetration into the milk from the acutely inflamed quarters of cows was extensive; mastitis milk C _max values were more than tenfold greater than the C _max in normal milk. On the other hand, the drug had limited access to the milk produced by subclinically infected inflamed half-udders of ewes.     

Fate of [14C]coumaphos after dermal application to lactating goats as a pour-on formulation

Two lactating Nubian goats were dermally treated with [14C]coumaphos (O-[3-chloro-4-methyl-2-oxo-2H-benzopyran-7-yl] O,O-diethyl phosphorothioate) as a 4% active ingredient pour-on formulation. Doses were administered, along the dorsal midline from withers to sacrum, at a rate equivalent to 14 mg of coumaphos/kg of body weight. During the 7 days after treatment, an average of less than 0.1, 4.7, and 1% of the administered dose was eliminated in the milk, urine, and feces, respectively. When goats were killed after 7 days, about 45% of the administered radiocarbon remained on the hair and skin, and this consisted almost entirely of intact coumaphos. Residues in selected tissues collected after 7 days were, in every case, less than 1 mg of coumaphos equivalent/kg of tissue, with highest residues in adipose tissue, followed by residues in kidney and liver. In milk, residue amounts plateaued after about 2 days and remained relatively constant at about 0.1 mg of coumaphos equivalent/kg of milk. Residues in adipose tissue and in milk consisted mainly of unmetabolized coumaphos. In urine, most radiocarbon was present as metabolites of coumaphos, but in feces, most radiocarbon was present as the intact parent compound. Coumaphos was absorbed slowly and at a constant rate after dermal application to lactating goats as a pour-on formulation.     

Thiamphenicol pharmacokinetics in sheep

Abdennebi, E.H., Khales, N., Sawchuk, R.J., Stowe, CM. Thiamphenicol pharmacokinetics in sheep. J. vet. Pharmacol. Therap. 17, 12–16.
The pharmacokinetics of thiamphenicol were investigated after intravenous (i-v.). intramuscular (i.m.) and oral (p.o.) administration to sheep. It was found that the drug is almost completely absorbed following intramuscular injection, with a bioavailability of about 8 7.5%. Thiamphenicol appears to be widely distributed into extravascular compartments, yielding a volume of distribution [V(b)] of approximately 1 1/Kg. Elimination from the blood is relatively rapid, with a biological half-life of about 1.5 h. Oral treatment showed that thiamphenicol is absorbed from the gastrointestinal tract yielding very low plasma concentrations which were maintained for at least 24 h. Although only 30% of the oral dose was systemically available, in contrast to chloramphenicol, thiamphenicol is truly absorbed when given orally to adult sheep. One possible reason for this observation is that rumen flora do not biotransform this drug as they do for chloramphenicol. Metabolism investigations are, however, needed to confirm this finding.     

Relative bioavailability of rafoxanide following intraruminal and intra-abomasal administration in sheep

The bioavailability of rafoxanide was compared after intraruminal and intra-abomasal administration in healthy adult sheep (n = 6) in a single dose, 2 parallel group study at 7.5 mg/kg. Rafoxanide concentrations in plasma were measured by means of HPLC analysis. Primary pharmacokinetic parameters for bioavailability and disposition of rafoxanide in plasma for both routes of administration were determined by non-compartmental and non-linear, 1-compartmental pharmacokinetic analysis, respectively. Significantly (P < or = 0.05) higher peak plasma concentrations (c(max)) of rafoxanide and a more rapid rate of absorption (c. 3.5 times) was observed in sheep after intra-abomasal (i-a) administration compared to intraruminal (i.r.) administration. A significantly (P < or = 0.05) longer lag period (t(lag)) before absorption (6.8 +/- 2.9 h) occurred after i.r. than after i-a treatment (1.9 +/- 0.6 h). There was no significant difference (P > 0.05) in AUC, MRT and in the rates of elimination (k10-HL and t(1/2beta)) between the i.r. and i-a routes of administration. The results of the study demonstrated the important influence of the rumino-reticulum on absorption of rafoxanide in sheep.     

Toltrazuril sulfone sodium salt: synthesis, analytical detection, and pharmacokinetics in the horse

Toltrazuril sulfone (ponazuril) is a triazine-based antiprotozoal agent with clinical application in the treatment of equine protozoal myeloencephalomyelitis (EPM). In this study, we synthesized and determined the bioavailability of a sodium salt formulation of toltrazuril sulfone that can be used for the treatment and prophylaxis of EPM in horses. Toltrazuril sulfone sodium salt was rapidly absorbed, with a mean peak plasma concentration of 2400 ± 169 (SEM) ng/mL occurring at 8 h after oral-mucosal dosing and was about 56% bioavailable compared with the i.v. administration of toltrazuril sulfone in dimethylsulfoxide (DMSO). The relative bioavailability of toltrazuril sulfone suspended in water compared with toltrazuril sulfone sodium salt was 46%, indicating approximately 54% less oral bioavailability of this compound suspended in water. In this study, we also investigated whether this salt formulation of toltrazuril sulfone can be used as a feed additive formulation without significant reduction in oral bioavailability. Our results indicated that toltrazuril sulfone sodium salt is relatively well absorbed when administered with feed with a mean oral bioavailability of 52%. Based on these data, repeated oral administration of toltrazuril sulfone sodium salt with or without feed will yield effective plasma and cerebrospinal fluid (CSF) concentrations of toltrazuril sulfone for the treatment and prophylaxis of EPM and other protozoal diseases of horses and other species. As such, toltrazuril sulfone sodium salt has the potential to be used as feed additive formulations for both the treatment and prophylaxis of EPM and various other apicomplexan diseases.     

Bioavailability of levamisole after intramuscular and oral administration in sheep

AIMS: To determine the bioavailability of levamisole in sheep. METHODS: Levamisole was administered to three groups of six Merino sheep orally and intramuscularly at three dose levels of 5, 7.5 and 10 mg/kg. There was a washout period of 1 week between treatments. Blood samples were collected by jugular venepuncture and plasma was separated immediately by centrifugation and stored at 20 degrees C until analysed. The levamisole concentration in plasma was determined by high performance liquid chromatography with a U.V. detection method. Individual plasma levamisole concentration-time data were analysed using the compartmental method. RESULTS: The values obtained for k(a), C(max), t(max) and F show a moderate rate and extent of absorption after oral administration of levamisole while, after intramuscular administration, these values demonstrate a high rate and extent of absorption of levamisole. The intramuscular bioavailability was higher than the oral bioavailability (rate of absorption three-fold faster, extent of absorption 25-33% higher and C(max) two-fold higher). The Friedman test involving dose and route of administration showed that the route of administration affects k(a), C(max), t(max) and F; significant differences were found in these parameters. CLINICAL RELEVANCE: On the basis of these data, the recommended routes for the administration of levamisole in sheep are oral for gastro-intestinal nematodiasis and intramuscular for extragastric nematodiasis.