Plasma Disposition and Faecal Excretion of Netobimin Metabolites and Enantiospecific Disposition of Albendazole Sulphoxide Produced in Ewes

Netobimin (NTB) was administered orally to ewes at 20 mg/kg bodyweight. Blood and faecal samples were collected from 1 to 120 h post-treatment and analysed by high-performance liquid chromatography (HPLC). Using a chiral phase-based HPLC, plasma disposition of albendazole sulphoxide (ABZSO) enantiomers produced was also determined. Neither NTB nor albendazole (ABZ) was present and only ABZSO and albendazole sulphone (ABZSO₂) metabolites were detected in the plasma samples. Maximum plasma concentrations (C<_max) of ABZSO (4.1 ± 0.7 μg/ml) and ABZSO₂ (1.1 ± 0.4 μg/ml) were detected at (t _max) 14.7 and 23.8 h, respectively following oral administration of netobimin. The area under the curve (AUC) of ABZSO (103.8 ± 22.8 (μg h)/ml) was significantly higher than that ABZSO₂(26.3± 10.1 (μg h)/ml) (p<0.01). (−)−ABZSO and (+)-ABZSO enantiomers were never in racemate proportions in plasma. The AUC of (+)-ABZSO (87.8±20.3 (μg h)/ml) was almost 6 times larger than that of (−)−ABZSO (15.5 ±5.1 (μg h)/ml) (p < 0.001). Netobimin was not detected, and ABZ was predominant and its AUC was significantly higher than that of ABZSO and ABZSO₂, following NTB administration in faecal samples (p > 0.01). Unlike in the plasma samples, the proportions of the enantiomers of ABZSO were close to racemic and the ratio of the faecal AUC of (−)−ABZSO (172.22 ±57.6 (μg h)/g) and (+)-ABZSO (187.19 ±63.4 (μg h)/g) was 0.92. It is concluded that NTB is completely converted to ABZ by the gastrointestinal flora and absorbed ABZ is completely metabolized to its sulphoxide and sulphone metabolites by first-pass effects. The specific behaviour of the two enantiomers probably reflects different enantioselectivity of the enzymatic systems of the liver that are responsible for sulphoxidation and sulphonation of ABZ.     

Aspects of the Pharmacokinetics of Albendazole Sulphoxide in Sheep

The plasma disposition kinetics of albendazole sulphoxide (ABZSO), ((+)ABZSO and (–)ABZSO) and its sulphone metabolite (ABZSO₂) were investigated in adult sheep. Six Corriedale sheep received albendazole sulphoxide by intravenous injection at 5 mg/kg live weight. Jugular blood samples were taken serially for 72 h and the plasma was analysed by high-performance liquid chromatography (HPLC) for albendazole (ABZ), ABZ sulphoxide (ABZSO) and albendazole sulphone (ABZSO₂). Albendazole was not detected in the plasma at any time after the treatment, ABZSO and ABZSO₂ being the main metabolites detected between 10 min and 48 h after treatment. A biexponential plasma concentration versus time curve was observed for both ABZSO and ABZSO₂ following the intravenous treatment. The plasma AUC values for ABZSO and ABZSO₂ were 52.0 and 10.8 (g.h)/ml, respectively. The ABZSO₂ metabolite was measurable in plasma between 10 min and 48 h after administration of ABZSO, reaching a peak concentration of 0.38 g/ml at 7.7 h after treatment. Using a chiral phase-based HPLC method, a biexponential plasma concentration versus time curve was observed for both ABZSO enantiomers. The total body clearance was higher for the (–) than for the (+) enantiomer, the values being 270.6 and 147.75 (ml/h)/kg, respectively. The elimination half-life of the (–) enantiomer was shorter than that of the (+) enantiomer, the values being 4.31 and 8.33 h, respectively. The enantiomeric ratio (+)ABZSO/(–)ABZSO at t ₀ was close to unity. However, the ratio in the plasma increased with time.     

Gastrointestinal distribution of albendazole metabolites following netobimin administration to cattle: relationship with plasma disposition kinetics

The gastrointestinal (GI) distribution and plasma disposition kinetics of alberidazole (ABZ) metabolites after oral administration of netobirnin (NTB) to cattle were studied. Eight Holstein steers (150–180 kg) were surgically fitted with permanent cannulae in the rumen, abomasum and ileum. After post-surgical recovery, the ariinials were treated orally with a suspension of neto1)imin zwitterion (400 mg/ml) at 20 nig/kg. Jugular blood and ruminal, abomasal arid ileal fluid samples were taken serially over a 96 h period and analysed by HPLC for NTB and its metabolites, including ABZ, ABZ sulphoxide (ABZSO), AH% sulphone (ABZSO?) and amino-albendazole sulphone (NHp4BZSOy). N T B parent drug was only fonnd in the G I tract and for only 12–18 h post-treatment. ABZSO and ABZSOp were the main metabolites found in plasma, being present for 30–36 h. These metabolites were exchanged between plasma and different GI fluids and were greatly concentrated in the abomasum. This phenornenori may account for the presence of ABZ, ABZSO and ABZSO? in the GI tract f'or 72 h post-treatment despite the fact that ABZ was riot detected in plasma and ABZSO and ABZSO.;, were detected for only 30–36 h in plasma. The presence o f ABZ and ABZSO in the abomasum and intestine for this extended period of time is probably relevant for anthelmintic efficacy against GI parasites. The NH₂ ABZSO₂ metabolite was detected in plasma, abomasum and ileum and its disposition kinetics were characterized for the first time.     

Disposition kinetics of albendazole and metabolites in laying hens

Bistoletti, M., Alvarez, L., Lanusse, C., Moreno, L. Disposition kinetics of albendazole and metabolites in laying hens. J. vet. Pharmacol. Therap.  36 , 161–168. An increasing prevalence of roundworm parasites in poultry, particularly in litter‐based housing systems, has been reported. However, few anthelmintic drugs are commercially available for use in avian production systems. The anthelmintic efficacy of albendazole (ABZ) in poultry has been demonstrated well. The goal of this work was to characterize the ABZ and metabolites plasma disposition kinetics after treatment with different administration routes in laying hens. Twenty‐four laying hens Plymouth Rock Barrada were distributed into three groups and treated with ABZ as follows: intravenously at 10 mg/kg (ABZ i.v.); orally at the same dose (ABZ oral); and in medicated feed at 10 mg/kg·day for 7 days (ABZ feed). Blood samples were taken up to 48 h posttreatment (ABZ i.v. and ABZ oral) and up to 10 days poststart feed medication (ABZ feed). The collected plasma samples were analyzed using high‐performance liquid chromatography. ABZ and its albendazole sulphoxide (ABZSO) and ABZSO₂ metabolites were recovered in plasma after ABZ i.v. administration. ABZ parent compound showed an initial concentration of 16.4 ± 2.0 μg/mL, being rapidly metabolized into the ABZSO and ABZSO₂ metabolites. The ABZSO maximum concentration (C_max) (3.10 ± 0.78 μg/mL) was higher than that of ABZSO₂C_max (0.34 ± 0.05 μg/mL). The area under the concentration vs time curve (AUC) for ABZSO (21.9 ± 3.6 μg·h/mL) was higher than that observed for ABZSO₂ and ABZ (7.80 ± 1.02 and 12.0 ± 1.6 μg·h/mL, respectively). The ABZ body clearance (Cl) was 0.88 ± 0.11 L·h/kg with an elimination half‐life (T_1/2el) of 3.47 ± 0.73 h. The T_1/2el for ABZSO and ABZSO₂ were 6.36 ± 1.50 and 5.40 ± 1.90 h, respectively. After ABZ oral administration, low ABZ plasma concentrations were measured between 0.5 and 3 h posttreatment. ABZ was rapidly metabolized to ABZSO (C_max, 1.71 ± 0.62 μg/mL) and ABZSO₂ (C_max, 0.43 ± 0.04 μg/mL). The metabolite systemic exposure (AUC) values were 18.6 ± 2.0 and 10.6 ± 0.9 μg·h/mL for ABZSO and ABZSO₂, respectively. The half‐life values after ABZ oral were similar (5.91 ± 0.60 and 5.57 ± 1.19 h for ABZSO and ABZSO₂, respectively) to those obtained after ABZ i.v. administration. ABZ was not recovered from the bloodstream after ABZ feed administration. AUC values of ABZSO and ABZSO₂ were 61.9 and 92.4 μg·h/mL, respectively. The work reported here provides useful information on the pharmacokinetic behavior of ABZ after both i.v. and oral administrations in hens, which is a useful first step to evaluate its potential as an anthelmintic tool for use in poultry.     

Effect of the ionophore antibiotic monensin on the ruminal biotransformation of benzimidazole anthelmintics

The benzimidazole (BZD) anthelmintics, netobimin (NTB) pro-drug and albendazole sulphoxide (ABZSO) are reduced to albendazole (ABZ) by ruminal microflora. The aim of the current work was to evaluate the influence of the ionophore monensin (MON) on the in vitro biotransformation of NTB and ABZSO by sheep ruminal fluid. Ruminal fluid, collected from Corriedale sheep, was preincubated (24 h) either without (control) or with known MON concentrations (0.5, 1.5 and 3.0 microg/mL) at 38 degrees C under a CO2 atmosphere. Afterwards, aliquots from both MON-pretreated and control ruminal fluid samples were incubated (30 and 60 min) with 2 microg/mL of either NTB or ABZSO. Incubated samples were chemically extracted and analysed by High Performance Liquid Chromatography to quantify the metabolites formed. The rate of ABZ production after 30 min of NTB incubation with control ruminal fluid was 0.023 microg/min. Conversely, the rates of ABZ formation were significantly (P<0.05) lower (0.009, 0.011 and 0.013 microg/min) when NTB was incubated with ruminal fluid pretreated with MON (at 0.5, 1.5 and 3.0 microg/mL, respectively). After both incubation periods, the reduction of ABZSO to ABZ was 22 to 70% lower when the ruminal fluid was preincubated with the different MON concentrations. The lower ABZ production observed in the presence of MON may result in a modified availability of this molecule in the gastrointestinal (GI) tract and hence, on its anthelmintic efficacy against GI nematodes.     

Comparative plasma disposition kinetics of albendazole, fenbendazole, oxfendazole and their metabolites in adult sheep

The comparative plasma disposition kinetics of albendazole (ABZ), fenbendazole (FBZ) and oxfendazole (OFZ) following their oral administration (5 mg/kg) to adult sheep was characterized. Jugular blood samples were taken serially over a 144 h period and plasma was analysed by high performance liquid chromatography (HPLC) for ABZ, ABZ sulphoxide (ABZSO) and ABZ sulphone (ABZSO₂) (ABZ treatment), and for FBZ, OFZ and FBZ sulphone (FBZSO₂) (FBZ and OFZ treatments). While the ABZ parent drug was not detected at any time post-treatment, ABZSO and ABZSO₂ were the analytes recovered in plasma, after oral administration of ABZ to sheep. The active ABZSO metabolite was the main analyte recovered in plasma (between 0.25 and 60h post-treatment), accounting for 71 % of the total AUC. FBZ, OFZ and FBZSO₂ were the analytes detected in plasma following the oral administration of both FBZ and OFZ to sheep. Low concentrations of FBZ were found in plasma between 4 (FBZ treatment) or 8 h (OFZ treatment) and 72 h post-treatment. The plasma profile of each analyte followed a similar pattern after both treatments; OFZ being the main component detected in plasma. The plasma disposition of ABZ metabolites was markedly different to that of FBZ derivatives. ABZSO exhibited faster absorption and a higher C_max than OFZ (both treatments). Furthermore, while ABZSO declined relatively rapidly in plasma reaching non-detectable concentrations at 60 h post-ABZ administration, OFZ was found in plasma for up to 120 (FBZ treatment) and 144 h (OFZ treatment). The extended detection of OFZ in plasma in both treatments correlated with the prolonged t_1/2β (18 h) and mean residence time (MRT) (30–33 h) obtained for this metabolite compared to those of ABZSO (t_1/2β= (7.0 h); MRT= 12.5 h). These differences between the disposition of ABZ and FBZ metabolites may account for differences in their patterns of efficacy and tissue residues.     

FASTING-INDUCED CHANGES TO THE PHARMACOKINETIC BEHAVIOUR OF ALBENDAZOLE AND ITS METABOLITES IN CALVES

The influence of fasting on the bioavailability and disposition kinetics of albendazole (ABZ) and its metabolites in cattle was investigated. ABZ (10 mg/kg) was given by intraruminal (i.r.) (Experiment 1) and intravenous (i.v.) (Experiment 2) administration to Holstein calves either fed ad libitum (control) or subjected to a 48 h fasting period (fasted group) prior to treatment. The rate of passage of digesta through the gastrointestinal (GI) tract was evaluated by measurement of cobalt faecal excretion following the oral administration of the sodium-cobalt-ethylendiamine-tetracetic acid complex to calves subjected to the feeding conditions above described. Jugular blood and abomasal fluid (via cannula) samples were collected over 120 h post-treatment; samples were analysed by high performance liquid chromatography (HPLC) for ABZ, ABZ sulphoxide (ABZSO) and ABZ sulphone (ABZSO₂). Fasting the animals prior to the i.r. treatment resulted in pronounced modifications to the plasma and abomasal fluid disposition kinetics of ABZ and its metabolites. A greater extent of GI absorption with significantly higher C_max (150%) and AUC (310%) values for ABZSO in plasma, was observed in fasted compared to fed animals following the i.r. administration of ABZ. Extended detection of ABZ metabolites resulting in significantly longer plasma t_½el and MRT was also obtained in fasted compared to fed calves. These results correlated with the substantially enhanced availability of ABZ and its metabolites (AUCs over 200% greater) in the abomasal fluid of the fasted animals. Fasting did not induce changes to the plasma disposition of either ABZ or its metabolites after the i.v. treatment. The digesta passage rate, measured by the amount of cobalt excreted in faeces, was significantly lower in fasted compared to animals fed ad libitum. A delayed GI transit time that decreases the rate of passage of the drug down the digestive tract, may have accounted for enhanced ABZ dissolution and absorption in fasted compared to fed calves. The findings reported in this article show that fasting prior to treatment notably affects the bioavailability and disposition kinetics of ABZ and its metabolites in cattle.     

Pharmacokinetic behaviour of netobimin and its metabolites in sheep

The pharmacokinetics and the profile of urine excretion of netobimin (NTB) and its metabolites were investigated after its intraruminal (i.r.) and subcutaneous (s.c.) administration to sheep at 20 mg/kg. Plasma and urine concentrations of NTB, albendazole (ABZ), albendazole sulphoxide (ABZSO) and albendazole sulphone (ABZSO2) were measured serially over a 120-h period by HPLC. NTB showed a similar pharmacokinetic profile in both treatments, being detected between 0.5 and 12 h post-treatment, but the tmax was achieved significantly earlier (P less than 0.05) after s.c. treatment. ABZ was detected in plasma only after i.r. treatment, resulting in a low area under the curve (AUC). The peak plasma concentration (Cmax) and AUC for ABZSO and ABZSO2 were significantly higher after i.r. administration of NTB. In both treatments, the ABZSO Cmax was reached earlier than the ABZSO2 Cmax. The ratio of AUC ABZSO2:ABZSO was higher following s.c. administration (1.33) than following i.r. administration (0.35). The percentages of total dose excreted in the urine as NTB, ABZ, ABZSO and ABZSO2 were 17.05 (i.r.) and 8.16 (s.c.). There was a less efficient conversion of NTB into ABZ metabolites after s.c. administration. The detection of ABZ in plasma and the high ABZSO AUC obtained after i.r. treatment may be of major importance for anthelmintic efficacy.     

Methimazole-mediated modulation of netobimin biotransformation in sheep: a pharmacokinetic assessment

The effects of modulation of liver microsomal sulphoxidation on the disposition kinetics of netobimin (NTB) metabolites were investigated in sheep. A zwitterion suspension of NTB was given orally at 7.5 mg/kg to sheep either alone (control treatment) or co-administered with methimazole (MTZ) orally (NTB + MTZ oral treatment) or intra-muscularly (NTB + MTZ i.m.) at 3 mg/kg. Blood samples were taken serially over a 72 h period and plasma was analysed by HPLC for NTB and its major metabolites, i.e. albendazole (ABZ), albendazole sulphoxide (ABZSO) and albendazole sulphone (ABZSO2). Only trace amounts of NTB parent drug and ABZ were detected in the earliest samples after either treatment. There were significant modifications to the disposition kinetics of ABZSO in the presence of MTZ. ABZSO elimination half-life increased from 7.27 h (control treatment) to 14.57 h (NTB + MTZ oral) and to 11.39 h (NTB + MTZ i.m.). ABZSO AUCs were significantly higher (P less than 0.05) for the NTB + MTZ oral treatment (+55%) and for the NTB + MTZ i.m. treatment (+61%), compared with the NTB alone treatment. The mean residence times for ABZSO were 12.66 +/- 0.68 h (control treatment), 18.85 +/- 2.35 h (NTB + MTZ oral) and 17.02 +/- 0.90 h (NTB + MTZ i.m.). There were no major changes in the overall pharmacokinetics of ABZSO2 for the concomitant MTZ treatments. However, delayed appearance of this metabolite in the plasma resulted in longer ABZSO2 lag times and a delayed Tmax for treatments with MTZ.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative drug systemic exposure and clinical efficacy against resistant nematodes in lambs treated with different albendazole formulations

Suárez, G., Alvarez, L., Castells, D., Correa, O., Fagiolino, P., Lanusse, C. Comparative drug systemic exposure and clinical efficacy against resistant nematodes in lambs treated with different albendazole formulations. J. vet. Pharmacol. Therap. 34 , 557–564. A pharmaco‐parasitological assessment of four different albendazole (ABZ) formulations was carried out in lambs infected with multiple resistant gastrointestinal (GI) nematodes. The comparative drug systemic exposure profiles (ABZ sulphoxide plasma concentrations) and anthelmintic efficacies (clinical endpoint measured through the faecal nematode eggs reduction counts) were determined for a reference formulation (RF) and three different test (T1, T2, T3) generic ABZ preparations. Fifty (50) Corriedale lambs naturally infected with multiple resistant GI nematodes were allocated into five experimental groups (n = 10). Animals in each group received treatment with either the RF, one of the test ABZ formulations (5 mg/kg by the intraruminal route) or were kept as untreated control. Blood samples were collected over 48 h post‐treatment. ABZ parent drug was not recovered in the bloodstream. The ABZ sulphoxide (ABZSO) and sulphone (ABZSO₂) metabolites were measured in plasma by ultraviolet high‐performance liquid chromatography over 36–48 h post‐treatment. A faecal nematode egg count reduction test (FECRT) was performed at day 10th post‐treatment to lambs from all treated and untreated groups, which indicated the predominance of nematodes with high level of resistance to ABZ. Both ABZSO C_max and AUC_0–LOQ values obtained for the RF (pioneer product) were significantly higher (P < 0.05) than those obtained for the T1 and T3 preparations. Based on the currently available bioequivalence criteria, the test (generic) ABZ formulations under evaluation could not be considered equivalent to the RF regarding the rate (C_max) and extent (AUC_0–LOD) of drug absorption (indirectly estimated through the ABZSO metabolite). A large variation in nematode egg counts did not permit to obtain statistically significant differences among formulations. However, a favourable trend in the efficacy against the most resistant nematodes was observed for the formulations with the highest ABZSO systemic exposure.     

Pharmacokinetic Behaviour of Albendazole Sulphoxide Enantiomers in Male and Female Sheep

Benzimidazole anthelmintic drugs are widely used in veterinary practice. Albendazole sulphoxide (ABZSO) is a benzimidazole drug with two enantiomers, as a consequence of a chiral centre in the sulphoxide group. The kinetics of these enantiomers were studied in male and female sheep. Plasma samples were obtained from the animals between 0.5 and 72 h after oral administration of 7.5 mg/kg of a racemic formulation of ABZSO (total-ABZSO). After a liquid–liquid extraction, the samples were analysed by HPLC to determine the concentrations of total-ABZSO and of the sulphone metabolite (ABZSO₂). During the chromatographic analysis, the ABZSO peak was collected and reanalysed by an HPLC technique using a Chiral AGP column to quantify the enantiomeric proportion therein. After kinetic analysis, the AUCs obtained for the (+)-ABZSO were 5.8 and 4.0 times higher than those for the (–)-ABZSO in male and female animals, respectively. The mean residence times were 23.4 and 16.1 h for (+)-ABZSO and 22.2 and 17.4 h for (–)-ABZSO for male and female animals, respectively. The only significant difference between the sexes (p<0.05) was in the T _max of the (–)-ABZSO. Comparing both enantiomers within each sex, significant differences were found in all the kinetic parameters. Finally, no kinetic differences were found between sex for total-ABZSO or ABZSO₂.     

Comparative plasma disposition of fenbendazole, oxfendazole and albendazole in dogs

The plasma disposition of fenbendazole (FBZ), oxfendazole (OFZ) and albendazole (ABZ); and the enantiospecific disposition of OFZ, and ABZSO produced were investigated following an oral administration (50 mg/kg) in dogs. Blood samples were collected from 1 to 120 h post-administration. The plasma samples were analysed by high performance liquid chromatography (HPLC). The plasma concentration of FBZ, OFZ, ABZ and their metabolites were significantly different from each other and depended on the drug administered. The sulphone metabolite (FBZSO2) of FBZ was not detected in any plasma samples and the parent molecule ABZ did not reach quantifiable concentrations following FBZ and ABZ administration, respectively. OFZ and its sulphone metabolite attained a significantly higher plasma concentration and remained much longer in plasma compared with FBZ and ABZ and their respective metabolites. The maximum plasma concentrations (Cmax), area under the concentration time curve (AUC) and mean residence time (MRT) of parent OFZ were more than 30, 68 and 2 times those of FBZ, respectively. The same parameters for ABZSO were also significantly greater than those of FBZSO. The ratio for total AUCs of both the parent drug and the metabolites were 1:42:7 for following FBZ, OFZ and ABZ administration, respectively. The enantiomers were never in racemic proportions and (+) enantiomers of both OFZ and ABZSO were predominant in plasma. The AUC of (+) enantiomers of OFZ and ABZSO was, respectively more than three and seven times larger than that of (-) enantiomers of both molecules. It is concluded that the plasma concentration of OFZ was substantially greater compared with FBZ and ABZ. The data on the pharmacokinetic profile of OFZ presented here may contribute to evaluate its potential as an anthelmintic drug for parasite control in dogs.     

Plasma disposition and faecal excretion of oxfendazole, fenbendazole and albendazole following oral administration to donkeys

Fenbendazole (FBZ), oxfendazole (fenbendazole sulphoxide, FBZSO), and albendazole (ABZ) were administered orally to donkeys at 10mg/kg bodyweight. Blood and faecal samples were collected from 1 to 120 h post-treatment. The plasma and faecal samples were analysed by high performance liquid chromatography (HPLC). The parent molecule and its sulphoxide and sulphone (FBZSO(2)) metabolites did not reach detectable concentrations in any plasma samples following FBZ administration. ABZ was also not detected in any plasma samples, but its sulphoxide and sulphone metabolites were detected, demonstrating that ABZ was completely metabolised by first-pass mechanisms in donkeys. Maximum plasma concentrations (C(max)) of FBZSO (0.49microg/mL) and FBZSO(2) (0.60microg/mL) were detected at (t(max)) 5.67 and 8.00h, respectively, following administration of FBZSO. The area under the curve (AUC) of the sulphone metabolite (10.33microg h/mL) was significantly higher than that of the parent drug FBZSO (5.17microg h/mL). C(max) of albendazole sulphoxide (ABZSO) (0.08g/mL) and albendazole sulphone (ABZSO(2)) (0.04microg/mL) were obtained at 5.71 and 8.00h, respectively, following ABZ administration. The AUC of the sulphoxide metabolite (0.84microg h/mL) of ABZ was significantly higher than that of the sulphone metabolite (0.50microg h/mL). The highest dry-faecal concentrations of parent molecules were detected at 32, 34 and 30h for FBZSO, FBZ and ABZ, respectively. The sulphide metabolite was significantly higher than the parent molecule after FBZSO administration. The parent molecule was predominant in the faecal samples following FBZ administration. After ABZ administration, the parent molecule was significantly metabolised, probably by gastrointestinal microflora, to its sulphoxide metabolite (ABZSO) that showed a similar excretion profile to the parent molecule in the faecal samples. The AUC of the parent FBZ was significantly higher than that of FBZSO and ABZ in faeces. It is concluded that the plasma concentration of FBZSO was significantly higher than that of FBZ and ABZ. Although ABZ is not licensed for use in Equidae, its metabolites presented a greater plasma kinetic profile than FBZ which is licensed for use in horses. A higher metabolic capacity, first-pass effects and lower absorption of benzimidazoles in donkeys decrease bioavailability and efficacy compared to ruminants.     

Uptake of albendazole and albendazole sulphoxide by Haemonchus contortus and Fasciola hepatica in sheep

The pattern of in vivo uptake of albendazole (ABZ) and its major metabolite, ABZ-sulphoxide (ABZSO), by Haemonchus contortus and Fasciola hepatica recovered from ABZ-treated sheep, was investigated. Concentration profiles of both compounds were simultaneously measured in target tissues/fluids from the same infected sheep. In addition, the proportion of the (+) and (-) ABZSO enantiomers was determined in plasma, bile and F. hepatica recovered from treated sheep. Sheep naturally infected with H. contortus were intraruminally (i.r.) treated with ABZ (micronized suspension, 7. 5mg/kg) and the plasma concentrations of ABZSO and ABZ-sulphone (ABZSO(2)) determined in addition to the concentration of ABZ and ABZSO in H. contortus, abomasal mucosa and fluid content samples. In addition, F. hepatica artificially infected sheep were treated i.r. with the same ABZ suspension (7.5mg/kg), and samples of blood, bile, liver tissue and adult flukes were collected and analysed by HPLC to determine the concentrations of ABZ and both enantiomers of ABZSO. ABZSO and ABZSO(2) were the analytes recovered in plasma with ABZ and ABZSO present in H. contortus. ABZ was the analyte recovered at the highest concentration in H. contortus and abomasal mucosa, whereas higher concentrations of ABZSO were measured in abomasal fluid content. Only low concentrations of ABZ were detected in F. hepatica and bile, but markedly higher concentrations of ABZ were measured in liver tissue. ABZSO was the main molecule recovered in F. hepatica, plasma and bile samples collected from ABZ-treated sheep. The (+) enantiomer of ABZSO was recovered at a higher proportion in plasma (75%), bile (78%) and F. hepatica (74%) after ABZ administration to infected sheep.     

Pharmacokinetic profiles of netobimin metabolites after oral administration of zwitterion and trisamine formulations of netobimin to cattle

Pharmacokinetic profiles of the major metabolites of netobimin were investigated in calves after oral administration of the compound (20 mg/kg) as a zwitterion suspension and trisamine salt solution in a two-way cross-over design. Blood samples were taken serially over a 72-h period and plasma was analysed by HPLC for netobimin (NTB) and its metabolites, including albendazole (ABZ), albendazole sulphoxide (ABZSO) and albendazole sulphone (ABZSO2). NTB was occasionally detected in plasma between 0.5 and 1.0 h post-treatment. ABZ was not detectable at any time. ABZSO was detected from 0.5-0.75 h up to 32 h post-administration, with a Cmax for the zwitterion suspension of 1.21 +/- 0.13 micrograms/ml and AUC of 18.55 +/- 1.45 micrograms.h/ml, respectively, which were significantly higher (P less than 0.01) than the Cmax (0.67 +/- 0.12 micrograms/ml) and AUC (8.57 +/- 0.91 micrograms.h/ml) for the trisamine solution. ABZSO2 was detected in plasma between 0.75 and 48 h post-administration. The zwitterion suspension resulted in a Cmax (2.91 +/- 0.10 micrograms/ml) and AUC (51.67 +/- 1.95 micrograms.h/ml) for ABZSO2, which were significantly higher (P less than 0.01) than those obtained for the trisamine solution (Cmax = 1.67 +/- 0.11 micrograms/ml and AUC = 22.77 +/- 1.09 micrograms.h/ml). The ratio of AUC for ABZSO2/ABZSO was 2.92 +/- 0.26 (zwitterion) and 2.80 +/- 0.20 (trisamine). The MRT for ABZSO2 was significantly longer (P less than 0.01) after treatment with the zwitterion suspension than after treatment with the trisamine solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Albendazole sulphoxide kinetic disposition after treatment with different formulations in dogs

Dib, A., Palma, S., Suárez, G., Farías, C., Cabrera, P., Castro, S., Allemandi, D., Moreno, L., Lanusse, C., Sánchez Bruni, S. Albendazole sulphoxide kinetic disposition after treatment with different formulations in dogs. J. vet. Pharmacol. Therap. 34 , 136–141. New therapeutic strategies based on the search of alternative formulations of albendazole (ABZ) and albendazole sulphoxide (ABZSO) are under current development to optimize posology and antiparasite efficacy in dogs. In an incomplete block design, nine dogs were randomly divided into three groups (n = 6). Treatments were carried out in two phases as follows. Phase I: Group I (treatment A), animals received ABZ at 25 mg/kg of conventional formulation. Group II (treatment B), dogs received 25 mg/kg of a modified poloxamer‐ABZ formulation. Group III (treatment C), animals were treated with ABZSO in equimolar amount to ABZ doses. After 21 days of wash‐out period the experiment was repeated (Phase II). Blood samples were collected over 24 h and subsequently analysed by high performance liquid chromatography. ABZSO and ABZSO₂ were the analytes recovered in plasma. Significant higher (P < 0.001) ABZSO area under the concentration–time curve (+500%) and C_max (+487%) values were obtained for the treatment C in comparison with treatments A and B. However, no statistical differences on pharmacokinetic parameters were found between formulations A and B. In conclusion, the enhanced plasma concentration profile obtained for the ABZSO formulation used in treatment C may contribute to optimize the anthelmintic control in dogs.     

Effects of feeding on the plasma disposition kinetics of the anthelmintic albendazole in laying hens

1. To optimise the use of albendazole (ABZ) as an anthelmintic in hens, the effects of fasting and type of diet on the plasma kinetics of ABZ and its metabolites were evaluated.

2. Twenty-four hens were distributed into 4 groups: In experiment I the Fed group were fed ad libitum, while the Fasted group was fasted over a 12-h period. In experiment II the Pelleted group was fed with pelleted commercial food, while the Grain group was fed with cereal grains. All the groups were treated with ABZ by oral route. Blood samples were taken and plasma analysed by HPLC.

3. ABZ and its metabolites albendazole-sulphoxide (ABZSO) and albendazole-sulphone (ABZSO₂) were recovered in plasma in all the groups. The 12-h fasting period did not modify the disposition kinetics of ABZ in hens. The type of feed affected ABZ kinetics. ABZSO concentration profile was higher and detected for longer in the Grain group compared to the Pelleted group. Statistical differences were not found for AUC_0-∞ values, whereas the T_1/2for and T_1/2el were different between groups.

4. Factors affecting ABZ kinetic behaviour should be taken into account to optimise its use to ensure the sustainability of the limited available anthelmintic therapeutic tools in avian parasite control.     

Pharmacokinetics of albendazole sulfoxide enantiomers administered in racemic form and separately in rats

The pharmacokinetic behaviour of albendazole sulfoxide (ABZSO) enantiomers was studied in rats after the oral administration of 10 mg/kg of rac-ABZSO, 5 mg/kg of (-)-ABZSO or 5 mg/kg of (+)-ABZSO. The disposition profiles of ABZSO enantiomers were similar in all treatments, but the calculated area under the curve for the (-)-ABZSO was higher in all cases compared with (+)-ABZSO. The results suggest that there is no chiral inversion of ABZSO enantiomers. After the administration of rac-ABZSO, 17.2% of the total dose was recovered in urine as albendazole ABZ (0.1%), albendazole sulfone ABZSO(2) (0.3%), albendazole 2-aminosulfone (ABZ-SO(2)NH(2)) (3.1%) and ABZSO (13.7%). The ratio (+) to (-) was similar in urine (1.6) and blood (1.7).     

Albendazole treatment in laying hens: Egg residues and its effects on fertility and hatchability

This work characterized the egg residual concentrations of albendazole (ABZ ) and its sulphoxide (ABZSO ) and sulphone (ABZSO ₂) metabolites and evaluated their effect on egg fertility and hatchability after ABZ treatments to laying hens. Seventy hens were allocated in groups: Group‐1 was the control without treatment; Group‐2 received a single ABZ oral dose (10 mg/kg); Group‐3, ‐4 and ‐5 were treated with ABZ in medicated feed over 7 days at 10, 40, or 80 mg kg^?1 day^?1, respectively. Eggs were analyzed to determine the ABZ /metabolite level by HPLC or subjected to incubation to evaluate the fertility and hatchability. Only ABZSO and ABZSO ₂ metabolites were quantified in egg after ABZ single oral administration with maximum concentrations of 0.47 ± 0.08 and 0.30 ± 0.07 μg/ml, respectively. ABZ and its metabolites were found in eggs after 7‐day ABZ treatments. The egg residue exposure estimated as AUC s (areas under the concentration vs . time curve) were 100.5 (ABZ ), 56.3 (ABZSO ) and 141.3 μg hr g^?1 (ABZSO ₂). ABZ administration did not affect the egg fertility at any dosages. Egg hatchability was not affected by ABZ treatment at 10 mg/kg in medicated feed, but it decreased when the dose was 4–8 times higher. These results should be considered when ABZ is used for deworming laying hens.     

Enhancement of the plasma concentration of albendazole sulphoxide in sheep following coadministration of parenteral netobimin and liver oxidase inhibitors

The effects of methimazole (MTZ), metyrapone (MTP) and quinine (QNE) on the pharmacokinetics and bioavailability of parenterally administered netobimin (NTB) and its major metabolites, albendazole sulphoxide (ABZSO) and albendazole sulphone (ABZSO2), were studied in sheep. NTB trisamine solution was first administered alone at 20 mg kg-1 by subcutaneous injection and then coadministered with either MTZ (1.5 mg kg-1 intramuscularly), MTP (20 mg kg-1 subcutaneously) or QNE (30 mg kg-1 intraruminally) in adult sheep. Blood samples were taken serially over a 120 hour period and plasma was analysed for NTB and its metabolites by high performance liquid chromatography. NTB parent drug showed a similar pharmacokinetic behaviour after all parenteral treatments. Both ABZSO AUCs (P less than 0.01) and Cmax (P less than 0.05) were significantly higher in the presence of MTZ and MTP than with the treatment with NTB alone. In the presence of each of the oxidation inhibitor compounds, the ratio of AUC ABZSO/ABZSO2 was significantly higher than with the NTB alone treatment. It has been demonstrated that the coadministration of substances which alter liver microsomal oxidation resulted in a modified pharmacokinetic pattern for the metabolites of NTB. Both NTB + MTZ and NTB + MTP treatments resulted in an improved pharmacokinetic profile for the anthelmintically active ABZSO metabolite.