A comparative kinetic study of ivermectin and moxidectin in lactating camels (Camelus dromedarius).

The plasma and milk kinetics of ivermectin (IVM) and moxidectin (MXD) was evaluated in lactating camels treated subcutaneously (0.2 mg kg(-1)) with commercially available formulations for cattle. Blood and milk samples were taken concurrently at predetermined times from 12 h up to 60 days post-administration. No differences were observed between plasma and milk kinetics of IVM, while substantial differences were noted between plasma and milk profiles of MXD in that both the maximal concentration (Cmax) and the area under concentrations curves (AUC) were three to four-fold higher for milk than for plasma. The time (Tmax) to reach Cmax was significantly faster for MXD (1.0 day) than that for IVM (12.33 days). The Cmax and the AUC were significantly higher for MXD (Cmax = 8.33 ng ml(-1); AUC = 70.63 ng day ml(-1)) than for IVM (Cmax = 1.79 ng ml(-1); AUC = 30.12 ng day ml(-1)) respectively. Drug appearance in milk was also more rapid for MXD (Tmax = 3.66 days) compared to IVM (Tmax = 17.33 days). The extent of drug exchange from blood to milk, expressed by the AUCmilk/AUCplasma ratio, was more than three-fold greater for MXD (4.10) compared to that of IVM (1.26), which is consistent with the more lipophilic characteristic of MXD. However, the mean residence time (MRT) was similar in both plasma and milk for each drug.     

Ivermectin pharmacokinetics in lactating sheep.

Ivermectin (IVM) concentrations in plasma and milk were studied in six Istrian Pramenka dairy sheep after a single subcutaneous dose of 0.2 mg/kg b.w. of IVM in the early lactation period to describe IVM disposition in milk and to evaluate the transfer of IVM residues via milk to suckling lambs. Large inter-animal in concentration variability of IVM in both matrices was observed. The highest overall concentration was found in the same animal: 21.7 microg/l of H(2)B(1a) in plasma on the second day and 44.9 microg/kg of H(2)B(1a) in milk on the first day after the drug was administered. The mean time in which IVM concentrations fell below the limit of detection for the whole ewe group was 22 and 23 days for plasma and milk, respectively. Time course of IVM concentration in milk was following the time course of IVM concentration in plasma, with an overall mean+/-S.D. of milk/plasma ratio of 1.67+/-0.50 for the first 7 days of the experiment. A mean of 0.7% of the dose was excreted through milk. Individual pharmacokinetic parameters were determined by fitting a one-compartment model to the milk and plasma concentration-time profiles. Mean t(max), c(max), t(1/2k(e)) and AUC values for plasma data were: 1.70+/-0.65 days, 11.88+/-6.96 microg/l, 2.85+/-1.97 days and 63.99+/-28.34 microg day/l, respectively, and for milk: 1.28+/-1.07 days, 22.67+/-18.27 microg/l, 3.56+/-2.01 days and 114.60+/-60.41 microg day/l, respectively. The highest level of concentration in suckling lamb plasma, 0.36 microg/l of H(2)B(1a), was slightly above the limit of determination. The mean lamb to ewe ratio of areas under the plasma concentration-time curve for the first 5 days was 0.02. On the basis of obtained results, it can therefore be claimed that indirect IVM exposure of the suckling lambs via milk was negligible.     

Pharmacokinetics of ivermectin in sheep following pretreatment with Escherichia coli endotoxin

The comparative pharmacokinetics of ivermectin (IVM), between healthy and in Escherichia coli lipopolysaccharides (LPS) injected sheep, was investigated after an intravenous (IV) administration of a single dose of 0.2 mg/kg. Ten Suffolk Down sheep, 55 ± 3.3 kg, were distributed in two experimental groups: Group 1 (LPS): treated with three doses of 1 μg LPS/kg bw at ?24, ?16, and ?0.75 hr before IVM; group 2 (Control): treated with saline solution (SS). An IV dose of 0.2 mg IVM/kg was administered 45 min after the last injection of LPS or SS. Plasma concentrations of IVM were determined by liquid chromatography. Pharmacokinetic parameters were calculated based on non‐compartmental modeling. In healthy sheep, the values of the pharmacokinetic parameters were as follows: elimination half‐life (2.85 days), mean residence time (MRT) (2.27 days), area under the plasma concentration curve over time (AUC, 117.4 ng day^?1 ml^?1), volume of distribution (875.6 ml/kg), and clearance (187.1 ml/day). No statistically significant differences were observed when compared with the results obtained from the group of sheep treated with LPS. It is concluded that the acute inflammatory response (AIR) induced by the intravenous administration of E. coli LPS in adult sheep produced no changes in plasma concentrations or in the pharmacokinetic behavior of IVM, when it is administered intravenously at therapeutic doses.     

Plasma pharmacokinetics and faecal excretion of ivermectin, doramectin and moxidectin following oral administration in horses

The present study was carried out to investigate whether the pharmacokinetics of avermectins or a milbemycin could explain their known or predicted efficacy in the horse. The avermectins, ivermectin (IVM) and doramectin (DRM), and the milbemycin, moxidectin (MXD), were each administered orally to horses at 200 microg/kg bwt. Blood and faecal samples were collected at predetermined times over 80 days (197 days for MXD) and 30 days, respectively, and plasma pharmacokinetics and faecal excretion determined. Maximum plasma concentrations (Cmax) (IVM: 21.4 ng/ml; DRM: 21.3 ng/ml; MXD: 30.1 ng/ml) were obtained at (tmax) 7.9 h (IVM), 8 h (DRM) and 7.9 h (MXD). The area under the concentration time curve (AUC) of MXD (92.8 ng x day/ml) was significantly larger than that of IVM (46.1 ng x day/ml) but not of DRM (53.3 ng x day/ml) and mean residence time of MXD (17.5 days) was significantly longer than that of either avermectin, while that of DRM (3 days) was significantly longer than that of IVM (2:3 days). The highest (dry weight) faecal concentrations (IVM: 19.5 microg/g; DRM: 20.5 microg/g; MXD: 16.6 microg/g) were detected at 24 h for all molecules and each compound was detected (> or = 0.05 microg/g) in faeces between 8 h and 8 days following administration. The avermectins and milbemycin with longer residence times may have extended prophylactic activity in horses and may be more effective against emerging and maturing cyathostomes during therapy. This will be dependent upon the relative potency of the drugs and should be confirmed in efficacy studies.     

Evaluation of the interaction between ivermectin and albendazole following their combined use in lambs

Mixtures of drugs from different chemical families have been proposed as a valid strategy to delay the development of anthelmintic resistance. The current work summarizes the outcome of the evaluation of the plasma disposition kinetics of albendazole (ABZ) and ivermectin (IVM) administered either alone or co-administered to lambs infected with gastrointestinal (GI) nematodes resistant to both anthelmintic molecules. Thirty six (36) Corriedale lambs naturally infected with multiple resistant GI nematodes were allocated into six treatment groups: (a) ABZ intravenous (ABZ(IV)); (b) IVM(IV); (c) ABZ(IV) + IVM(IV); (d) ABZ intraruminal (IR); (e) IVM subcutaneous (SC) and (f) ABZ(IR) + IVM(SC). Plasma samples were collected over 15 days post-treatment and analysed by HPLC. The estimated pharmacokinetic (PK) parameters were statistically compared using parametric and non-parametric statistical tests. The presence of IVM did not affect the plasma disposition kinetics of ABZ and its metabolites after the i.v. administration. However, the ABZ sulphoxide (ABZSO) area under the concentration vs. time curve (AUC) was significantly lower (P < 0.01) after the intraruminal (i.r.) administration of ABZ alone compared to that obtained for the combined treatment with IVM [subcutaneous (s.c.) injection]. The IVM plasma AUC obtained after its i.v. co-administration with ABZ was 88% higher (P < 0.05) compared to the treatment with IVM alone. Any marked difference on IVM PK parameters was observed between the treatments ABZ + IVM and IVM alone injected subcutaneously. The data obtained here indicate that the co-administration of ABZ and IVM does not induce an adverse kinetic interaction. This type of pharmacology-based evaluation of drug interactions is becoming highly relevant as drug combinations are now widely used as an alternative to control resistant helminth parasites in livestock.     

Involvement of P-glycoprotein on ivermectin kinetic behaviour in sheep: itraconazole-mediated changes on gastrointestinal disposition

Different pharmacological approaches have been used in an attempt to increase the systemic availability of anthelmintic drugs. The comparative effect of the itraconazole (ITZ)-mediated modulation of P-glycoprotein (P-gp) activity on the in vivo kinetic behaviour of ivermectin (IVM) administered by the intravenous (i.v.) and intraruminal (i.r.) routes to sheep was assessed in the current work. Corriedale sheep received IVM (50 microg/kg) by the i.v. route either alone (group A) or co-administered with the P-gp modulator ITZ (100 mg orally three times every 12 h) (group B). Animals in groups C and D were intraruminally treated with IVM (50 microg/kg) alone or co-administered with ITZ (100 mg orally three times every 12 h) respectively. Jugular blood and gastrointestinal tissue samples (animals treated by the i.r. route) were collected. The samples were analysed by HPLC using fluorescence detection. The plasma disposition of IVM given intravenously was unaffected by the presence of ITZ. However, after the i.r. treatment the co-administration with ITZ resulted in markedly higher IVM plasma concentration profiles compared to the control group. Likewise, the presence of ITZ enhanced the IVM concentration profiles measured in the gastrointestinal mucosal tissues. An ITZ-induced reduction on the P-gp efflux activity at the intestinal lining may have accounted for the greater absorption and enhanced systemic availability observed for IVM in the intraruminally treated animals.     

联合应用阿苯达唑和伊维菌素在线虫感染鄂尔多斯细毛羊体内的药动学研究

为阐明联合应用阿苯达唑(ABZ)和伊维菌素(IVM)在胃肠道线虫感染鄂尔多斯细毛羊体内的药动学互作关系,以感染胃肠道线虫的鄂尔多斯细毛羊为研究对象,比较研究了单独或联合应用阿苯达唑和伊维菌素后的药物动力学特征。通过粪便虫卵检查法,选取感染胃肠道线虫的鄂尔多斯细毛羊15只,随机分成3组,每组5只。第1组口服给予阿苯达唑(15mg/kg),第2组皮下注射伊维菌素(0.2mg/kg),第3组皮下注射伊维菌素(0.2mg/kg)的同时口服阿苯达唑(15mg/kg)。于给药后不同时间,由颈静脉采集血样,分离血浆,并用高效液相色谱法测定各时间点血浆阿苯达唑、阿苯达唑亚砜、阿苯达唑砜和伊维菌素浓度,并用PK Solution 2.0药物动力学软件计算出各药动学参数。结果表明,联合用药组绵羊血浆伊维菌素峰浓度(Cmax)、药时曲线下面积(AUC)和平均滞留时间(MRT)分别为44.80ng/mL±6.12ng/mL、5 007.46ng.h/mL±1 301.42ng.h/mL和85.47h±5.03h,均显著(P<0.05)小于单独用药组的对应参数值67.62ng/mL±9.06ng/mL、7 125.08ng.h/mL±908.52ng.h/mL和113.39h±9.00h。口服阿苯达唑组绵羊血浆中仅检测到了阿苯达唑砜和阿苯达唑亚砜,而未检测到阿苯达唑母药。联合用药后,除阿苯达唑砜的达峰时间(T max)显著推迟外,阿苯达唑砜和阿苯达唑亚砜的其他各参数之间均无显著性差异。因此,联合应用IVM和ABZ可影响它们在胃肠道线虫感染鄂尔多斯细毛羊体内的药动学特征,且对伊维菌素药动学特征的影响尤为明显,在临床联合用药过程中应予以重视。     

Comparative plasma dispositions of ivermectin and doramectin following subcutaneous and oral administration in dogs

This study evaluates the comparative plasma dispositions of ivermectin (IVM) and doramectin (DRM) following oral and subcutaneous administration (200 microg/kg) over a 40-day period in dogs. Twenty bitches were allocated by weight in to four groups (Groups I-IV) of five animals each. Animals in the first two groups (Groups I and II) received orally the injectable solutions of IVM and DRM, respectively, at the dose of 200 microg/kg bodyweight. The other two groups (Groups III and IV) received subcutaneously injectable solutions at the same dose rate. Blood samples were collected between 1h and 40 days after treatment and the plasma samples were analysed by high performance liquid chromatography (HPLC) using fluorescence detection. The results indicated that IVM produced a significantly higher maximum plasma concentration (C(max): 116.80+/-10.79 ng/ml) with slower absorption (t(max): 0.23+/-0.09 day) and larger area under the concentration versus time curve (AUC: 236.79+/-41.45 ng day/ml) as compared with DRM (C(max): 86.47+/-19.80 ng/ml, t(max): 0.12+/-0.05 day, AUC: 183.48+/-13.17 ng day/ml) following oral administration of both drugs; whereas no significant differences were observed on the pharmacokinetic parameters between IVM and DRM after subcutaneous administrations. In addition, subcutaneously given IVM and DRM presented a significantly lower maximum plasma concentration (C(max): 66.80+/-9.67 ng/ml and 54.78+/-11.99 ng/ml, respectively) with slower absorption (t(max): 1.40+/-1.00 day and 1.70+/-0.76 day, respectively) and larger area under the concentration versus time curve (AUC: 349.18+/-47.79 ng day/ml and 292.10+/-78.76 ng day/ml, respectively) as compared with the oral administration of IVM and DRM, respectively. No difference was observed for the terminal half-lives ((t(1/2lambda(z)) and mean residence times (MRT) of both molecules. Considering the pharmacokinetic parameters, IVM and DRM could be used by the oral or subcutaneous route for the control of parasitic infection in dogs.     

Plasma achiral and chiral pharmacokinetic behaviour of intravenous oxfendazole co-administered with piperonyl butoxide in sheep

Co-administration of piperonyl butoxide (PB) potentiates fenbendazole (FBZ) in small ruminants. The resultant increase in bioavailability of FBZ and its metabolite oxfendazole (OFZ) has important implications for the efficacy of these drugs against benzimidazole (BZD)-resistant strains of Teladorsagia circumcincta. This study evaluated the racemic (achiral) and enantiomeric (chiral) plasma disposition kinetics of OFZ and its metabolites after the co-administration of PB and OFZ in sheep. Six 6-8-month-old, parasite-free, female Dorset sheep (30-40 kg) were used in a two-phase crossover experiment. In phase I, three sheep received 30 mg/kg PB orally, followed by a single intravenous (i.v.) injection of OFZ at 5 mg/kg. The other three animals were treated similarly except that 5 mL of water replaced PB. In phase 2, treatments for the two groups were reversed and were given 14 days after the initiation of phase I. Three analytes OFZ, FBZ and fenbendazole sulphone (FBZSO(2)) were recovered in plasma up to 48 h post-treatment in both experimental groups. Achiral and chiral pharmacokinetic (PK) profiles for OFZ, after the co-administration of PB, were characterized by a significantly greater area under the concentration--time curve (AUC) and a longer mean residence time (MRT). Chiral OFZ distribution ratios were comparable in both treatment groups. Piperonyl butoxide treatment markedly influenced the plasma PK profiles for FBZ and FBZSO(2) following OFZ administration. Production of FBZ was enhanced as reflected by increased (> 60%) AUC, delayed T(max) and a significantly delayed (> 45%) elimination (t(1/2)(el)). Although AUC values for FBZSO(2) were not significantly different between groups, this metabolite was depleted more slowly from plasma (t(1/2)(el) > 60% and MRT > 42%) following PB treatment. This study demonstrated that PB co-administration is associated with an inhibition of OFZ biotransformation, as evidenced by the significantly higher plasma concentrations of OFZ and FBZ, and this could have important implications in terms of anti-parasite therapy against BZD-resistant parasite strains.     

Combined use of ivermectin and triclabendazole in sheep: in vitro and in vivo characterisation of their pharmacological interaction

This study evaluated the pharmacokinetic properties of ivermectin (IVM) and triclabendazole (TCBZ) given either separately or co-administered to sheep. Corriedale sheep received IVM alone, TCBZ alone or a combination of IVM and TCBZ intravenously. Ivermectin elimination was delayed and its plasma availability was 3-fold higher when co-administered with TCBZ. Similarly, plasma concentrations of TCBZ and its metabolites were influenced by the co-administration of IVM. Higher peak plasma concentrations of TCBZ metabolites were detected after the co-administration of TCBZ and IVM compared to those obtained following TCBZ treatment in isolation. Complementary in vitro assays were carried out to assess the influence of TCBZ on the P-glycoprotein-mediated intestinal transport of IVM, using the everted gut sac technique. Enhanced accumulation of IVM in the intestinal wall occurred after co-incubation with TCBZ.     

Pharmacokinetic evaluation of four ivermectin generic formulations in calves

The plasma concentration profiles of four randomly chosen ivermectin (IVM) generic formulations (IVM G1-G4) were compared after their subcutaneous (SC) administration to healthy calves. The disposition of other avermectin-type endectocide compounds, doramectin (DRM) and abamectin (ABM), was also assessed in the same pharmacokinetic trial. Forty-two parasite-free Aberdeen Angus male calves were randomly allocated into six treatment groups. Animals in each group (n = 7) received SC treatment (200 microg/kg) with one of the commercially available endectocide formulation used in the trial. Blood samples were taken into heparinised vacutainer tubes from the jugular vein prior to and up to 35 days post-treatment. The recovered plasma was analysed by HPLC with fluorescence detection. Large kinetic differences were observed among the DRM, ABM and IVM formulations under evaluation. The DRM plasma concentration profiles were higher than those measured for ABM and all the IVM generic formulations. The higher and sustained plasma concentrations of DRM accounted for greater area under concentration-time curve (AUC) and longer mean residence time (MRT) values compared to those obtained for both ABM and the IVM generic preparations. The pattern of IVM absorption from the site of subcutaneous administration showed differences among the generic formulations under evaluation. The IVM G2 preparation showed higher peak plasma concentration and AUC values (P < 0.05) compared to those obtained after the administration of the IVM G1 formulation. Longer (P < 0.05) MRT values were obtained after the administration of the IVM G3 compared to other IVM generic preparations. The kinetic behaviour of ABM did not show significant differences with that described for most of the IVM formulations. This study demonstrates that major differences on drug kinetic behaviour may be observed when using different endectocide injectable formulations in cattle.     

The comparative serum disposition kinetics of subcutaneous administration of doramectin, ivermectin and moxidectin in the Australian Merino sheep

This study evaluates the comparative serum disposition kinetics of injectable formulations of doramectin (DRM), ivermectin (IVM) and moxidectin (MXD) in Australian Merino sheep. Thirty-six, 2-year-old sheep were allocated by weight into six groups of six animals. Animals in each group received 200 microg/kg of DRM, MXD, IVM or a combination of two of these drugs by subcutaneous (s.c.) injection. Blood was collected at designated intervals (between 1 h and 40 days after treatment) and the serum analysed by high performance liquid chromatography (HPLC) using fluorescence detection. The results indicated that MXD administration produced a significantly higher maximum serum concentration and a more rapid absorption as compared with DRM and IVM. MXD and DRM had a significantly larger area under the concentration vs. time curve (AUC) than IVM, suggesting a more persistent effect for the former two products in sheep. The AUC for DRM was significantly higher when administered alone as compared with that observed when given in combination with MXD or IVM, suggesting preferential elimination of DRM compared with IVM and MXD from concurrent s.c. administration.     

Plasma and milk kinetic of eprinomectin and moxidectin in lactating water buffaloes (Bubalus bubalis)

The pharmacokinetics and mammary excretion of moxidectin and eprinomectin were determined in water buffaloes (Bubalus bubalis) following topical administration of 0.5mgkg(-1). Following administration of moxidectin, plasma and milk concentrations of moxidectin increased to reach maximal concentrations (C(max)) of 5.46+/-3.50 and 23.76+/-16.63ngml(-1) at T(max) of 1.20+/-0.33 and 1.87+/-0.77 days in plasma and milk, respectively. The mean residence time (MRT) were similar for plasma and milk (5.27+/-0.45 and 5.87+/-0.80 days, respectively). The AUC value was 5-fold higher in milk (109.68+/-65.01ngdayml(-1)) than in plasma (23.66+/-12.26ngdayml(-1)). The ratio of AUC milk/plasma for moxidectin was 5.04+/-2.13. The moxidectin systemic availability (expressed as plasma AUC values) obtained in buffaloes was in the same range than those reported in cattle. The faster absorption and elimination processes of moxidectin were probably due to a lower storage in fat associated with the fact that animals were in lactation. Nevertheless, due to its high excretion in milk and its high detected maximum concentration in milk which is equivalent or higher to the Maximal Residue Level value (MRL) (40ngml(-1)), its use should be prohibited in lactating buffaloes. Concerning eprinomectin, the C(max) were of 2.74+/-0.89 and 3.40+/-1.68ngml(-1) at T(max) of 1.44+/-0.20 and 1.33+/-0.0.41 days in plasma and milk, respectively. The MRT and the AUC were similar for plasma (3.17+/-0.41 days and 11.43+/-4.01ngdayml(-1)) and milk (2.70+/-0.44 days and 8.49+/-3.33ngdayml(-1)). The ratio of AUC milk/plasma for eprinomectin was 0.76+/-0.16. The AUC value is 20 times lower than that reported in dairy cattle. The very low extent of mammary excretion and the milk levels reported lower than the MRL (20ngml(-1)) supports the permitted use of eprinomectin in lactating water buffaloes.     

黄芩苷对大鼠口服非索非那定的药动学影响

为了研究黄芩苷在大鼠体内对非索非那定药动学及P-gp表达的影响,将SD大鼠36只随机分为A、B、C三组,连续灌胃7天,A组给予黄芩苷200mg/kg,B组蒸馏水空白对照,C组维拉帕米药物对照(10mg/kg),第8天灌胃后2小时,各组随机取6只大鼠处死,解剖并迅速取出肝脏、空肠,荧光定量PCR测定各组织P-gp的mRNA表达水平。各组另外6只大鼠灌胃后同时给予非索非那定（30mg/kg）,按时间点连续采集血样,采用高效液相色谱法测定非索非那定血药浓度。结果表明,黄芩苷对非索非那定的吸收有明显促进作用,主要表现在黄芩苷组非索非那定峰浓度(Cmax)比空白对照组增加17.04%（P<0.05）,曲线下面积AUC(0-12)增加19.23%（P<0.05）,黄芩苷减少了大鼠空肠和肝脏P-gp蛋白的表达（P<0.05）。结论：黄芩苷能下调大鼠P-gp表达,增加P-gp底物非索非那定在大鼠体内的生物利用度,是一种P-gp抑制剂。     

Comparison of the pharmacokinetics of moxidectin (Equest®) and ivermectin (Eqvalan®) in horses

A study was undertaken in order to evaluate and compare plasma disposition kinetic parameters of moxidectin and ivermectin after oral administration of their commercially available preparations in horses. Ten clinically healthy adult horses, weighing 390-446 kg body weight (b.w.), were allocated to two experimental groups of five horses. Group I was treated with an oral gel formulation of moxidectin (MXD) at the manufacturers recommended therapeutic dose of 0.4 mg/kg bw. Group II was treated with an oral paste formulation of ivermectin (IVM) at the manufacturers recommended dose of 0.2 mg/kg b.w. Blood samples were collected by jugular puncture at different times between 0.5 h and 75 days post-treatment. After plasma extraction and derivatization, samples were analysed by HPLC with fluorescence detection. Computerized kinetic analysis was carried out. The parent molecules were detected in plasma between 30 min and either 30 (IVM) or 75 (MXD) days post-treatment. Both drugs showed similar patterns of absorption and no significant difference was found for the time corresponding to peak plasma concentrations or for absorption half-life. Peak plasma concentrations (Cmax) of 70.3+/-10.7 ng/mL (mean +/- SD) were obtained for MXD and 44.0+/-23.1 ng/mL for IVM. Moreover, the values for area under concentration-time curve (AUC) were 363.6+/-66.0 ng x d/mL for the MXD treated group, and 132.7+/-47.3 ng x d/mL for the IVM treated group. The mean plasma residence times (MRT) were 18.4+/-4.4 and 4.8+/-0.6 days for MXD and IVM treated groups, respectively. The results showed a more prolonged residence of MXD in horses as demonstrated by a four-fold longer MRT than for IVM. The longer residence and the higher concentrations found for MXD in comparison to IVM could possibly explain a more prolonged anthelmintic effect. It is concluded that in horses the commercial preparation of MXD presents a pharmacokinetic profile which differs significantly from that found for a commercial preparation of IVM. To some extent these results likely reflect differences in formulation and doses.     

Bioavailability of albendazole sulphoxide after netobimin administration in sheep: effects of fenbendazole coadministration.

After oral co-administration of two dosages of netobimin (7.5 and 20 mg kg-1 with fenbendazole (1.1 mg kg-1) to Merino sheep, the AUC0-infinity of albendazole sulphoxide at the lower dosage of netobimin, was significantly increased (75.5 per cent) from control value (34.43 +/- 7.91 versus 60.33 +/- 11.93 microg h ml-1). The pharmacokinetic parameters MRT and T1/2 were also increased: 18.96 +/- 2.54 vs 26.44 +/- 4.69 h and 10.31 +/- 1.72 vs 22.28 +/- 6.75 h respectively. No data corresponding to the higher dosage of netobimin (20 mg kg-1) were statistically different from control values. It is concluded that fenbendazole increases the bioavailability of albendazole sulphoxide in sheep at the 7.5 mg kg-1 dosage, and this may produce a potentiated anthelmintic action.     

Ivermectin (3.15%) long-acting formulations in cattle: absorption pattern and pharmacokinetic considerations

Ivermectin (IVM) is a broad-spectrum antiparasitic drug extensively used in veterinary medicine. The composition of the pharmaceutical preparation affects IVM absorption and its systemic availability. After the introduction of the first approved IVM formulation (propylene glycol/glycerol formal 60:40) used at 200 microg/kg, different pharmaceutical modifications have been assayed to extend IVM persistent endectocide activity. Recently, IVM 3.15% long-acting (IVM-LA) preparations to be administered at 630 microg/kg to cattle were introduced into the veterinary pharmaceutical market. The work reported here was designed to evaluate the comparative IVM absorption pattern and plasma concentration profiles obtained after subcutaneous administration of the classic pioneer IVM formulation (1%) and two different commercially available IVM-LA preparations (3.15%) to cattle. Twenty-eight Holstein heifers were divided in four experimental groups (n=7) and treated subcutaneously as follows--Group A: IVM 1% given at 200 microg/kg, Group B: IVM 1% administered at 630 microg/kg, Group C: IVM-LA (A) injected at 630 microg/kg and Group D: IVM-LA (B) given at 630 microg/kg. Blood samples were taken between 0.5 and 90 days post-treatment and IVM plasma concentrations were determined by HPLC with fluorescence detection. There were no differences in the persistence of IVM plasma concentrations after the administration of IVM 1% formulation at the two used dose levels (200 and 630 microg/kg). Higher peak plasma concentration (C(max)) and shorter mean residence time (MRT) were obtained for IVM 1% given at 630 microg/kg (Group B) compared to the treatments with both IVM-LA preparations. The IVM-LA (A) formulation showed a more extended absorption process than IVM-LA (B) preparation, which accounted for a longer persistence of detectable IVM plasma concentrations. The parasitological implications of the observed differences in peak plasma concentrations (C(max) values) and in the IVM concentration levels measured from day 20, and afterwards until day 90 post-treatment, between the different preparations assayed need to be elucidated. The characterization of the absorption patterns and kinetic behaviour obtained after injection of these novel long-acting formulations used at three times the therapeutic dose recommended for the classic IVM preparation in cattle is a further contribution to the field.     

Plasma pharmacokinetics and faecal excretion of ivermectin (Eqvalan paste) and doramectin (Dectomax, 1%) following oral administration in donkeys

Ivermectin (IVM- Eqvalan paste, 1.87%) and doramectin (DRM-Dectomax 1%) were each administered orally to donkeys at 200 microgkg(-1) bodyweight. Blood and faecal samples were collected at predetermined times over 30 days and plasma pharmacokinetics and faecal excretion determined. Maximum plasma concentrations (C(max)) of IVM (23.6 ngml(-1)) and DRM (33.9 ngml(-1)) were obtained at (t(max)) 19.2 and 24h, respectively. The area under the concentration curve (AUC) of DRM (228.9 ngdayml(-1)) was significantly larger than that of IVM (119.3 ngdayml(-1)) and mean residence time (MRT) was 6.5 days for IVM and 9.1days for DRM. The highest (dry weight) faecal concentrations (9.33 microgg(-1) - IVM, 12.12 microgg(-1) - DRM) were detected at 55.9 and 48.0 h, respectively and each compound was detected (0.05 microgg(-1)) in faeces between 11h and 9 days following oral administration in donkeys.     

Combined subcutaneous administration of ivermectin and nitroxynil in sheep: Age/body weight related changes to the kinetic disposition of both compounds

The effect of age/body weight in the plasma disposition kinetics of ivermectin (IVM) and nitroxynil (NTX) after their co-administration as a combined formulation to sheep was studied. Sixteen (16) male sheep were allocated into two experimental groups (n = 8 each): (a) high body weight (high bw) (18-20 months old), and (b) low body weight (low bw) (6-8 months old). Animals in both groups were subcutaneously (sc) treated with IVM (200 μg/kg) and NTX (10 mg/kg) using a commercially available combined formulation (Nitromectin^®, Lab. Ovejero, Spain). Blood samples were taken by jugular venopuncture before (time 0), at 2, 4, 8, 12 h and at 1, 2, 3, 5, 7, 10, 15, 20, 25, 35, 40, 50 and 60 days after administration. Recovered plasma was analysed to quantify IVM and NTX by HPLC. Higher IVM plasma concentrations were measured until 20 days post-administration in “low bw” compared to “high bw” animals, where IVM was recovered up to 35 days post-treatment. The IVM absorption process greatly differed between experimental groups. A significantly higher (p < 0.01) C_max (36.7 ± 7.52 ng/ml) value was obtained at a delayed (p < 0.05) T_max (48.0 ± 0.0 h) in light compared to heavy (C_max: 8.0 ± 0.80 ng/ml; at 34.0 h) body weight sheep. IVM elimination half-life and mean residence time were significantly shorter in light compared to heavy (older) sheep. NTX mean plasma concentrations were lower in “low bw” compared to those measured in “high bw” sheep, with elimination phases declining up to 60 d post-administration in both experimental groups. The NTX AUC value in “low bw” (1188.5 ± 122.6 μg day/ml) was significantly lower (p < 0.05) than that obtained in the “high bw” (oldest) animals (1735.0 ± 155.8 μg day/ml). Shorter NTX elimination half-life and mean residence time (p < 0.01) were obtained in the youngest (“low bw”) compared to the oldest (high bw) sheep. The work reported here assessed for the first time the disposition of IVM and NTX after their combinated injection to sheep, demonstrating that animal body weight/development greatly affects the kinetic behaviour of both anthelmintic drugs.     

Some Pharmacokinetic Parameters of Eprinomectin in Goats following Pour-on Administration

Some pharmacokinetic parameters of eprinomectin were determined in goats following topical application at a dose rate of 0.5 mg/kg. The plasma concentration versus time data for the drug were analysed using a one-compartment model. The maximum plasma concentration of 5.60±1.01 ng/ml occurred 2.55 days after administration. The area under the concentration–time curve (AUC) was 72.31±11.15 ng day/ml and the mean residence time (MRT) was 9.42±0.43 days. Thus, the systemic availability of eprinomectin to goats was significantly lower than that for cows. The low concentration of eprinomectin in the plasma of goats suggests that the pour-on dose of 0.5 mg/kg would be less effective in this species than in cows. Further relevant information about the optimal dosage and residues in the milk of dairy goats is needed before eprinomectin should be used in this species.