The effect of diet type on the plasma disposition of triclabendazole in goats

The effect of two different diet types (concentrate feed+hay and grazing) on the pharmacokinetic profiles of triclabendazole following oral administration in goats was investigated. A total of 12 goats were randomly allocated into two groups which were either indoor and fed concentrate + hay ration (housed group) or were grazing on pasture (grazing group). Triclabendazole was administered orally to animals in two groups at 10 mg/kg bodyweight. Blood samples were collected from 1 h to 192 h post-treatment and analyzed by high performance liquid chromatography (HPLC). Feeding with different diets significantly effected the plasma disposition of triclabendazole sulphoxide. Maximum plasma concentration (C(max): 13.22+/-2.81 microg/ml), time to reach maximum plasma concentration (t(max): 18.4+/-2.19 h), area under the curve (AUC: 613+/-137 microg h/ml), half-life (t(1/2): 24.77+/-1.94 h) and mean resident time (MRT: 40.22+/-4.36 h) of triclabendazole sulphoxide in housed group were significantly different from those of grazing group (C(max): 10.17+/-1.51 microg/ml, t(max): 14.0+/-2.19 h, AUC: 406+/-98 microg h/ml), t(1/2): 16.16+/-1.17 h and MRT: 34.48+/-4.40 h). It is concluded that anthelmintically more active sulphoxide metabolite has higher plasma concentration when triclabendazole is administered to goats fed with concentrate feed + hay compared to grazing goats.     

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.     

The effect of feed quality on the kinetic disposition of orally administered triclabendazole in sheep

The effect of two qualities of feed on the kinetic disposition of triclabendazole (TCBZ) metabolites was investigated in sheep (n = 4) following oral administration of TCBZ at 10 mg/kg body weight. The same sheep were given sequentially two qualitatively different diets: a low-quality (LQ) diet based on wheat straw ad libitum, and a high-quality (HQ) diet based on barley+alfalfa. The triclabendazole sulphoxide (TCBZSO) and triclabendazole sulphone (TCBZSO₂) concentrations were determined in blood samples taken serially from the jugular vein between 5 min and 9 days after TCBZ administration. The parent drug TCBZ was not detected in any of the samples. The quality of feed affected the kinetics of both TCBZ metabolites. The rate of appearance (T_lag and T_max) in the jugular blood was slower and the formed amount (AUC) of TCBZSO was slightly higher when the sheep were on the LQ diet (T_lag = 7.74 h; T_max = 27.91 h; AUC = 1042 g.h/ml) than when they were offered the HQ diet (T_lag = 1.90 h; T_max = 16.01 h; AUC = 832.4 g.h/ml). The MRT of TCBZSO was about 40% longer with the LQ diet than with the HQ diet. Similarly, the rate of appearance of TCBZSO₂ in plasma of sheep was slower when they were on the LQ diet than when they were on the HQ diet, suggesting an impairment of the hepatic enzymatic activity involved in the oxidation of TCBZSO to TCBZSO₂.     

The effect of fasting on the plasma disposition of triclabendazole following oral administration in goats

This study was designed to investigate the effect of feeding on the plasma disposition of triclabendazole (TCBZ) in goats following oral administration. A total of eight goats, aged 14–16 months and weighing 20–30 kg were used in this study. The animals were allocated into two groups (fasted and fed groups) of four animals each. The goats in fed group were fed ad libitum but the animals in fasted group were not fed 24 h before and 6 h after drug administration. Commercial oral drench formulation of TCBZ (Endex-K, 5%) was administered orally to animals in two groups at dose of 10 mg/kg bodyweight. Heparinized blood samples were collected between 1 and 192 h after treatment and the plasma samples were analysed by high performance liquid chromatography (HPLC) for TCBZ, TCBZ sulphoxide (TCBZ–SO), and TCBZ sulphone (TCBZ–SO₂). Relatively very low concentration of TCBZ parent drug was detected between 2 and 48 h, but TCBZ–SO and TCBZ–SO₂ metabolites were present between 2 and 192 h in the plasma samples of fed and fasted animals. Fasting significantly enhanced the plasma concentration of TCBZ and its metabolites. The availability of TCBZ, TCBZ–SO and TCBZ–SO₂ in the plasma samples of fasted goats were markedly greater compared to those of fed goats. It was concluded that fasting decreases the digesta flow rate and prolongs the retention of the drug into the gastrointestinal tract, resulting in enhanced quantitative gastrointestinal absorption or systemic availability of TCBZ and its metabolites in fasted goats.     

The kinetics of triclabendazole disposition in sheep

To investigate whether the disposition of triclabendazole (TCBZ) and its metabolites in blood or bile influenced its flukicidal potency, TCBZ was administered intraruminally at 10 mg kg-1 to sheep surgically fitted with a permanent re-entrant bile duct cannula. The profiles of TCBZ metabolites in peripheral plasma and bile were determined using high performance liquid chromatography. In plasma, only TCBZ sulphoxide (TCBZ-SO) and TCBZ sulphone were present and reached their maximum concentrations (greater than 13 micrograms ml-1) at 18 and 36 h, respectively, after administration. TCBZ metabolites were specifically bound to plasma albumin, which is believed to exert a major influence on the duration of plasma TCBZ metabolite concentrations and consequent exposure of liver fluke. In bile, the major TCBZ metabolites were hydroxylated in the 4' position and secreted predominantly as sulphate esters with lesser proportions as glucuronide conjugates. The major biliary metabolite was conjugated hydroxy TCBZ-SO which reached a maximum concentration in excess of 40 micrograms ml-1 and contributed almost half the total conjugated metabolites. The major free biliary metabolite was TCBZ-SO. Of the administered TCBZ dose, 9.7% was secreted as free metabolites in bile whereas 35.8% was secreted as conjugated metabolites. Approximately 6.5% of the dose was excreted in urine.     

Inhibition of cytochrome P450 activity enhances the systemic availability of triclabendazole metabolites in sheep

Understanding the disposition kinetics and the pattern of metabolism is critical to optimise the flukicidal activity of triclabendazole (TCBZ) in ruminants. TCBZ is metabolised by both flavin-monooxygenase (FMO) and cytochrome P450 (P450) in the liver. Interference with these metabolic pathways may be useful to increase the systemic availabilities of TCBZ metabolites, which may improve the efficacy against Fasciola hepatica . The plasma disposition of TCBZ metabolites was evaluated following TCBZ co-administration with FMO [methimazole (MTZ)] and P450 [piperonyl butoxyde (PB) and ketoconazole (KTZ)] inhibitors in sheep. Twenty (20) healthy Corriedale x Merino weaned female lambs were randomly allocated into four experimental groups. Animals of each group were treated as follow: Group A, TCBZ alone (5 mg/kg, IV route); Group B, TCBZ (5 mg/kg, IV) + MTZ (3 mg/kg, IV); Group C, TCBZ (5 mg/kg, IV) + PB (30 mg/kg, IV) and Group D, TCBZ (5 mg/kg, IV) + KTZ (10 mg/kg, orally). Blood samples were taken over 240 h post-treatment and analysed by HPLC. TCBZ sulphoxide and sulphone were the main metabolites recovered in plasma. MTZ did not affect TCBZ disposition kinetics. TCBZ sulphoxide Cmax values were significantly increased ( P  < 0.05) after the TCBZ + PB (62%) and TCBZ + KTZ (37%) treatments compared to those measured in the TCBZ alone treatment. TCBZ sulphoxide plasma AUCs were higher ( P  < 0.05) in the presence of both PB (99%) and KTZ (41%). Inhibition of TCBZ P450-mediated oxidation in the liver accounted for the increased systemic availability of its active metabolite TCBZ sulphoxide. This work contributes to the search of different strategies to improve the use of this flukicidal drug in ruminants.     

Metabolite concentrations in plasma following treatment of cattle with five anthelmintics

Plasma concentrations of anthelmintics and their metabolites were determined after cattle were treated at recommended dose rates and routes of administration. Fenbendazole, oxfendazole, febantel, albendazole and thiabendazole were given orally and oxfendazole was also administered with an intraruminal injector. After fenbendazole, oxfendazole and febantel were administered, fenbendazole, oxfendazole and fenbendazole sulphone were all detected in plasma in each case. However, there were marked differences between the three anthelmintics in the peak concentrations and areas under the plasma concentration/time curve (AUC) of these three metabolites. Intraruminal administration of oxfendazole produced higher AUC for fenbendazole and fenbendazole sulphone than did oral administration. Albendazole sulphoxide and sulphone were detected in cattle plasma after albendazole administration but no parent drug was present. These metabolites disappeared more rapidly in cattle than has been reported for sheep. Only 5(6)hydroxythiabendazole was detected in cattle plasma after thiabendazole treatment.     

A comparison of plasma metabolite levels in goats and sheep during continuous low-level administration of fenbendazole

Plasma levels of fenbendazole (FBZ) and its sulphoxide (OFZ) and sulphone (FBZ.SO₂) metabolites were measured in goats and sheep during low-level administration of FBZ given by intraruminal infusion or formulated into a urea-molasses feed supplement block (UMB). In experiment 1, 6 goats and 6 sheep were offered UMB containing 0.5 g FBZ/kg (MUMB) and individual block consumption was measured daily for 18 days. In experiment 2, some of the same animals (n=4 for each species) received FBZ by intraruminal infusion at 1, 1.5 and 3 mg/kg liveweight per day for 7 days at each dosage. FBZ, OFZ and FBZ.SO levels were determined in plasma collected every 3 days in experiment 1 and on days 4, 5 and²6 of each infusion period in experiment 2. In both experiments, higher equilibrium levels were observed for the three metabolites in sheep than in goats. Significant linear relationships were observed between the daily FBZ dosages and the plasma levels of the three metabolites in both species. The regression coefficients were significantly higher in sheep than in goats for FBZ and OFZ but not for FBZ.SO₂, and they were also significantly higher during MUMB administration than during infusion for all three metabolites in both species. FBZ is a suitable anthelmintic for incorporation into a MUMB formulation for use in livestock production systems where responses to molasses urea supplementation have been demonstrated and gastrointestinal parasitism impairs productivity. The results indicate that target dose rates for goats should be 0.75 mg/kg per day compared with 0.5 mg/kg per day for sheep.Abbreviations ANOVA analysis of variance - FBZ fenbendazole - FBZ.SO₂ fenbendazole sulphone - HPLC high-performance liquid chromatography - MUMB urea-molasses feed supplement block containing 0.5 g fenbendazole/kg - OFZ fenbendazole sulphoxide - UMB urea-molasses feed supplment block     

Pharmacokinetics of fenbendazole in dogs

Fenbendazole was administered to dogs at a dose rate of 20 mg/kg body weight on a single occasion in gelatin capsules, on 5 consecutive days in feed, and on a single occasion as an alginate suspension. It was also administered at a dose rate of 100 mg/kg body weight on a single occasion in feed. Following single administration of 20 mg/kg fenbendazole mean maximum concentrations (Cmax) of the parent drug and its known active sulphoxide metabolite were 0.42 +/- 0.05 and 0.31 +/- 0.05 microgram/ml, respectively. Mean times until maximum concentrations were achieved (tmax) were 12.67 +/- 4.18 and 15.33 +/- 2.81 h, respectively, and areas under the plasma concentration-time curves (AUC) were 5.83 +/- 0.65 and 4.60 +/- 0.57 microgram.h/ml, respectively. Administration in feed increased the apparent bioavailability and administration for 5 consecutive days provided sustained plasma concentrations, generally greater than 0.2 microgram/ml. Administration as an alginate did not increase bioavailability or extend the persistence in plasma. It did increase the tmax to 16.80 +/- 2.93 and 20.00 +/- 2.53 h for fenbendazole and its sulphoxide metabolite, respectively. Increasing the dose from 20 mg/kg to 100 mg/kg did not substantially increase the Cmax or AUC.     

The efficacy and pharmacokinetics of long-term low-level intraruminal administration of tricalbendazole in buffalo with induced fasciolosis

A study was conducted on the pharmacokinetics and therapeutic efficacy of triclabendazole at three low dose rates of 0.5, 1.0 and 1.5 mg/kg body weight in buffaloes experimentally infected with Fasciola gigantica. The pharmacokinetics were compared with the effects of a single intraruminal dose at 24.0 mg/kg body weight in uninfected buffaloes. At all three dose rates, an equilibrium between the absorption of triclabendazole and the disposition of its metabolites was observed by days 3 and 4 and remained almost unchanged thereafter. Continuous daily dosing at 1.5 mg/kg body weight proved to be efficacious against liver fluke infection in buffaloes.Abbreviations TCBZ triclabendazole - p.i. post-infection - HPLC high-performance liquid chromatography - TCBZ-SO triclabendazole sulphoxide - TCBZ-SO2 triclabendazole sulphone - C _max peak concentration in plasma - T _max time to reach C _max - AUC area under the concentration-time curve - t _1/2 elimination half-life - epg eggs per gram     

Disposition of fenbendazole in the rabbit

The disposition of fenbendazole was studied in rabbits following either oral or intravenous administration. The major metabolites appearing in plasma were fenbendazole sulphoxide (oxfendazole) and fenbendazole sulphone. Calculation of the total urinary and faecal elimination of the drug and of its known metabolites showed that only 40 per cent of the dose was recovered after oral dosing; 29.7 per cent after an intravenous dose. The sulphoxide and sulphone were minor elimination products. The major excretory metabolite was p-hydroxyfenbendazole.     

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.     

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.     

Comparative kinetic disposition of oxfendazole in sheep and goats before and during infection with Haemonchus contortus and Trich ostrongylus colubriformis

The kinetic disposition of [¹⁴C]-oxfendaEole (OFZ) and its metabolites, fenben-dazole (FBZ) and fenbendazole sulphone (FBZ.SO₂), in plasma and abomasal fluid were determined in Merino sheep and Angora goats before and during infection with Trichostrongylus colubriformis and Haemonchus contortus. The systemic availability (area under the plasma curve, AUC) of OFZ was significantly lower in goats (13.5 μg.h/ml) than in sheep (22.2 μg.h/ml) and was reduced with infection in goats (5.6 μg.h/ml) and sheep (15.1 μg.h/ml). The elimination of plasma [^l4C] was faster in goats than in sheep. The responses observed for [¹⁴C] were a reflection of the behaviour of OFZ. The concentration of OFZ and metabolites in abomasal fluid were similar in both species in the absence or presence of infection. However, as the mean flow rate of abomasal fluid was slower in goats (240 ml/h) than in sheep (488 ml/h), only 7% of the dose passed the pylorus in abomasal fluid of goats compared with 14% in sheep. The presence of gastrointestinal nematodes generally increased abomasal fluid flow rate but neither species nor infection had any effect on the rate or extent of [¹⁴C] excretion in urine or faeces. It is suggested that goats possess a faster hepatic metabolism than sheep resulting in more rapid elimination of OFZ.     

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)     

Interaction of Fasciola hepatica with albendazole and its metabolites

Adult Fasciola hepatica recovered from sheep 12 and 24 h after a single oral dose of albendazole (20 mg/kg) contained significant amounts of two oxidized metabolites of albendazole (ABZ), a sulphoxide (SX) and a sulphone (SO), but not ABZ. Flukes incubated in vitro with 10 microM SX or SO contained these metabolites at a level two to three times the level observed in flukes recovered from sheep 24 h after a curative oral dose of ABZ. The concentration of ABZ in flukes was 10-fold greater than either SX or SO after a 24 h in vitro incubation in 10 microM of the respective drug. Flukes exposed to ABZ in vitro contained two-fold higher SX levels than SX-treated flukes due to a combination of spontaneous oxidation in media and fluke-mediated oxidation of ABZ. Measurement of end-products of glucose metabolism following 24 h incubation in 10 microM of either ABZ, SX or SO did not show a significant difference between treated and untreated flukes.     

The disposition of albendazole in sheep

Albendazole (ABZ) was administered intraruminally at 4.75 mg/kg to sheep fitted with a permanent bile-duct cannula to determine if its metabolites might contribute to its flukicidal action. ABZ metabolism was consistent with first-pass clearance by the liver, resulting in ABZ sulphoxide (ABZ-SO) and ABZ sulphone (ABZ-SO2) being present in plasma at maximum concentrations (mean Cmax +/- SD) of 2.0 +/- 0.2 micrograms/ml and 0.4 +/- 0.1 micrograms/ml after 8 +/- 3 h and 24 +/- 5 h, respectively. ABZ-SO, but more particularly ABZ-SO2, appeared to bind to plasma proteins but their clearance rates from plasma were similar. Biliary ABZ metabolites were mainly unconjugated ABZ-SO and 2OH-ABZ-SO (8.0% dose) or conjugated glucuronide and sulphate esters (6.3% dose) mainly of 2OH-ABZ-SO and 2OH-ABZ-SO2. The concentration of the major biliary metabolite, unconjugated ABZ-SO, followed a similar time profile to that of ABZ-SO in plasma except that Cmax was much higher (6.2 +/- 2.2 micrograms/ml). Intraruminal administration of ABZ reduced bile flow rate by 30% which may be attributable to an inhibitory effect of ABZ on microtubule formation in hepatic secretory cells. It is suggested that ABZ is sequestered in the liver. This is unlikely to contribute to its flukicidal action, which is probably attributable to ingestion of ABZ-SO from bile and blood by the fluke.     

The Pharmacokinetics and Efficacy of Long-Term Low-Level and Split-Dose Administration of Albendazole Through In-Feed Formulations against Ovine and Caprine Parasitic Gastroenteritis

Two trials were conducted against natural and experimentally induced parasitic gastroenteritis in sheep and goats using an in-feed formulation of albendazole to evaluate its therapeutic and prophylactic efficacy. In the first trial, albendazole was incorporated in feed pellets to deliver an average daily dose of 0.7 mg/kg body weight in order to evaluate its prophylactic efficacy. In the second trial, feed pellets were offered to deliver an average total dose of 8.0 mg/kg body weight in two equal split doses in order to evaluate its curative efficacy.Sustained plasma concentrations of the active compound, albendazole sulphoxide, and its metabolite albendazole sulphone, sufficient to prevent establishment of infection, were achieved when the animals were allowed to feed on medicated pellets for 10 consecutive days. The bioavailability of the metabolites of albendazole following the administration of a therapeutic dose in two split doses of the in-feed formulation was sufficient to remove established adult nematodes. The concentrate feed pellets could be used for self-medicating small ruminants for therapeutic use as well as for prophylaxis based on their strategic use appropriate to the epidemiology of the parasitic disease.     

国产三氯苯咪唑驱除山羊肝片形吸虫效果试验

以国产三氯苯咪唑对自然感染肝片形吸虫的山羊进行了驱虫试验，并以硝氯酚为药物对照。结果表明，三氯本咪唑5mg/kg体重的剂量对肝片形吸虫成虫和童虫的驱虫率分别为99.3%和92.9%，驱净率为75％；三氯苯咪唑10mg/kg体重的剂量对肝片形吸虫成虫和童虫的驱虫率均为100％，驱净率为100％；硝氯酚5mg/kg体重剂量对肝片形吸虫成虫驱虫率为100％，但对童虫的仅为74.3%，而驱净率仅为60％。在整个试验期间试验羊均无不良反应。     

The binding and distribution of albendazole and its principal metabolites in Giardia duodenalis

Trophozoites of the protozoan parasite Giardia duodenalis were exposed to various albendazole concentrations for 4 h, washed, fixed and incubated with antibodies raised against albendazole and its two major metabolites albendazole sulphoxide and albendazole sulphone. Tubulin antibodies were also used. A peroxidase- or FITC-conjugated secondary antibody was used to detect the primary antibody with transmission electron microscopy or confocal laser scanning microscopy, respectively. Albendazole, a benzimidazole compound, was detected in the mid-dorsal region of trophozoites, albendazole sulphoxide in the posterior-dorsal region and albendazole sulphone in clusters above the median bodies. Tubulin was recognised in the ventral disk. This is the first indication that G. duodenalis may be capable of metabolising albendazole and the potential path of the metabolised drug traced within the trophozoite. Fluorescence measurements revealed that albendazole sulphoxide binding decreased and albendazole sulphone binding increased with exposure of the trophozoites to increasing albendazole concentration. This indicates that if albendazole was being metabolised by trophozoites, it occurred to a greater extent following exposure to higher albendazole concentrations.