The persistence of the broad-spectrum antiparasitic activity of endectocide compounds relies on their disposition kinetics and pattern of plasma/tissues exchange in the host. This study evaluates the comparative plasma disposition kinetics of ivermectin (IVM), moxidectin (MXD) and doramectin (DRM) in cattle treated with commercially available injectable formulations. Twelve (12) parasite-free male Hereford calves (180-210 kg) grazing on pasture were allocated into three groups of four animals each. Animals in each group received either IVM (Ivomec 1%, MSD AGVET, Rahway, NJ, USA), MXD (Cydectin 1%. American Cyanamid, Wayne, NJ, USA) or DRM (Dectomax 1%, Pfizer Inc., New York, NY, USA) by subcutaneous injection at a dose of 200 micrograms/kg. Jugular blood samples were collected from 1 h up to 80 days post-treatment, and plasma extracted, derivatized and analysed by high performance liquid chromatography (HPLC) using fluorescence detection. The parent molecules were detected in plasma between 1 h and either 70 (DRM) or 80 (IVM and MXD) days post-treatment. The absorption of MXD from the site of injection was significantly faster (absorption half-life (t1/2ab) = 1.32 h) than those of IVM (t1/2ab = 39.2 h) and DRM (t1/2ab = 56.4 h). MXD peak plasma concentration (Cmax) was reached significantly earlier (8.00 h) compared to those of IVM and DRM (4-6 days post-treatment). There were no differences on Cmax values: the area under the concentration-time curve (AUC) was higher for IVM (459 ng.d/mL) and DRM (627 ng.d/mL) compared to that of MXD (217 ng.d/mL). The mean plasma residence time was longer for MXD (14.6 d) compared to IVM (7.35 d) and DRM (9.09 d). Unidentified metabolites were detected in plasma: they accounted for 5.75% (DRM), 8.50% (IVM) and 13.8% (MXD) of the total amount of their respective parent drugs recovered in plasma. The comparative plasma disposition kinetics of IVM, MXD and DRM in cattle, characterized over 80 days post-treatment under standardized experimental conditions, is reported for the first time.
Triclabendazole (TCBZ) is a halogenated benzimidazole compound that possesses high activity against immature and adult stages of the liver fluke, Fasciola hepatica. The intensive use of TCBZ in endemic areas of fascioliasis has resulted in the development of liver flukes resistant to this compound. TCBZ sulphoxide (TCBZSO) and TCBZ sulphone (TCBZSO2) are the main molecules recovered in the bloodstream of TCBZ-treated animals. In order to gain some insight into the possible mechanisms of resistance to TCBZ, the goals of the work described here were: to compare the ex vivo transtegumental diffusion of TCBZ parent drug and its sulpho-metabolites (TCBZSO and TCBZSO2) into TCBZ-susceptible and -resistant liver flukes; and to assess the comparative pattern of TCBZ biotransformation by TCBZ-susceptible and -resistant F. hepatica. For the tegumental diffusion studies, TCBZ-susceptible (Cullompton) and -resistant (Sligo) adult flukes collected from untreated infected sheep were incubated (15-180 min) in KRT buffer containing either TCBZ, TCBZSO or TCBZSO2 (5 nmol.ml-1). For the metabolism studies, microsomal fractions obtained from TCBZ-susceptible and -resistant flukes were incubated for 60 min with TCBZ (40 microM), and the amount of the formed metabolic product (TCBZSO) was measured. Drug/metabolite concentrations were quantified by HPLC. All the assayed TCBZ-related molecules penetrated through the tegument of both TCBZ-susceptible and -resistant flukes. However, significantly lower (approximately 50%) concentrations of TCBZ and TCBZSO were recovered within the TCBZ-resistant flukes compared to the TCBZ-susceptible ones over the 180 min incubation period. The rate of TCBZ sulphoxidative metabolism into TCBZSO was significantly higher (39%) in TCBZ-resistant flukes. The flavin-monooxigenase (FMO) enzyme system appears to be the main metabolic pathway involved in the formation of TCBZSO in both TCBZ-susceptible and -resistant flukes. The altered drug influx/efflux and enhanced metabolic capacity identified in TCBZ-resistant liver flukes may account for the development of resistance to TCBZ.
ABSTRACT:The enantioselective sulfoxidation of the prochiral anthelmintic compounds albendazole (ABZ) and fenbendazole (FBZ) was investigated in liver, lung and small intestinal microsomes obtained from healthy sheep and cattle. The microsomal fractions were incubated with a 40 M concentration of either ABZ or FBZ. Inhibition of the flavin-containing monooxygenase (FMO) system was carried out by preincubation with 100 M methimazole (MTZ) either with or without heat pretreatment (2 min at 50°C). ABZ and FBZ were metabolized to the (؉) and (؊) enantiomers of their sulfoxide metabolites, named albendazole sulfoxide (ABZSO) and oxfendazole (OFZ), respectively. ABZ sulfoxidation rates were higher (p < 0.001) than those observed for FBZ. The FMO-mediated liver sulfoxidation of ABZ was enantioselective (100%) toward the (؉) ABZSO production in both species. Liver sulfoxidation of FBZ by FMO was also enantioselective toward (؉) OFZ (sheep ؍ 65%; cattle ؍ 79%). Cytochrome P450 was found to be mainly involved in the production of (؊) ABZSO in the liver. MTZ did not affect the sulfoxidation of ABZ by lung microsomes, which may indicate that FMO is not involved in the production of ABZSO in this tissue. A significant (p < 0.05) inhibition of (؊) ABZSO production by liver microsomes was observed after ABZ incubation in the presence of erythromycin (cattle ؍ 21%) and ketoconazole (sheep ؍ 36%). Both CYP3A substrates induced a reduction in the production of (؊) ABZSO (sheep ؍ 67-78%, cattle ؍ 50-78%) by lung microsomes. Overall, the results reported here contribute to the identification of the metabolic pathways involved in the biotransformation of benzimidazole anthelmintics extensively used for parasite control in ruminants.Livestock animals are exposed to a variety of xenobiotic agents (i.e., veterinary drugs, feed-additives, pesticides, pollutants, etc.) during their production cycles. These compounds are likely to be metabolized by different enzymatic systems from both hepatic and extrahepatic tissues. The metabolic activity of the flavin-containing monooxygenase (FMO) and cytochrome P450 (P450) systems plays a major role in determining the persistence of therapeutically used drugs in target species, which may additionally impose a risk to the consumer as a consequence of the permanence of drug residue levels in edible tissues. Metabolic interactions with either the FMO or P450 enzymatic systems may drastically affect the disposition kinetics of different drugs used in animal production, which will have a relevant impact on the pattern of drug/metabolite residues in edible tissues, a major concern for public health and consumer safety.Benzimidazole (BZD 1 ) and pro-BZD anthelmintics are extensively metabolized in domestic animals and humans. Their metabolic pattern and the resultant pharmacokinetic behavior are relevant in the attainment of high and sustained concentrations of pharmacologically active drug/metabolites at the target parasite . Albendazole (ABZ; methyl-[(5-propylthio)-1H-benzimidazol-2-yl] carba...
The time of parasite exposure to active drug concentrations determines the persistence of the antiparasitic activity of endectocide compounds. This study evaluates the disposition kinetics of moxidectin (MXD) in plasma and in different target tissues following its subcutaneous (s.c.) administration to cattle. Eighteen male, 10-month old Holstein calves weighing 120-140 kg were subcutaneously injected in the shoulder area with a commercially available formulation of MXD (Cydectin 1%, American Cyanamid, Wayne, NJ, USA) at 200 micrograms/kg. Two treated calves were killed at each of the following times post-treatment: 1, 4, 8, 18, 28, 38, 48, 58 and 68 days. Abomasal and small intestine mucosal tissue and fluids, bile, faeces, lung, skin and plasma samples were collected, extracted, derivatized and analysed to determine MXD concentrations by high performance liquid chromatography (HPLC) with fluorescence detection. MXD was extensively distributed to all tissues and fluids analysed, being detected (concentrations > 0.1 ng/g; ng/mL) between 1 and 58 days post-treatment. MXD peak concentrations were attained during the first sampling day. MXD maximum concentration (Cmax) values ranged from 52.9 (intestinal mucosa) up to 149 ng/g (faeces). The mean residence time (MRT) in the different tissues and fluids ranged from 6.8 (abomasal mucosa) up to 11.3 (bile) days. MXD concentrations in abomasal and intestinal mucosal tissue were higher than those detected in plasma; however, there was a high correlation between MXD concentrations observed in plasma and those detected in both gastrointestinal mucosal tissues. MXD concentrations were markedly greater in the mucosa than in its respective digestive fluid (P < 0.01). MXD concentrations in skin were higher than those found in plasma (P < 0.01). Drug concentrations recovered in the dermis were greater than those detected in the hypodermal tissue (P < 0.05). Large concentrations of MXD were excreted in bile and faeces. These findings may contribute to an understanding of the relationship between the kinetic behaviour and the persistence of the antiparasite activity of MXD against different ecto-endoparasites in cattle.
Graphical abstractHighlights► Macrocyclic lactones share some structural and physico-chemical properties. ► The kinetic-dynamic differences of these compounds should be addressed under in vivo standardized conditions. ► Lower concentrations of moxidectin were obtained in resistant Haemonchus contortus. ► Moxidectin showed a higher efficacy against resistant H. contortus. ► The P-glycoprotein expression in H. contortus was increased after ivermectin treatment.
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