Lovejoy Nleya1,2, Roslyn Thelingwani1, Xue-Qing Li3, Erika Cavallin3, Emre Isin3, Charles Nhachi2, Collen Masimirembwa4. 1. African Institute of Biomedical Science and Technology (AIBST), Harare, Zimbabwe. 2. Department of Clinical Pharmacology, University of Zimbabwe College of Health Sciences, Harare, Zimbabwe. 3. Cardiovascular, Renal and Metabolism, IMED Biotech Unit, AstraZeneca, Gothenburg, Sweden. 4. African Institute of Biomedical Science and Technology (AIBST), Harare, Zimbabwe. collenmasimirembwa@yahoo.com.
Abstract
AIM: The study sought to determine the effect of ketoconazole (KTZ) on the pharmacokinetics of praziquantel (PZQ) and on the formation of its major hydroxylated metabolites, cis- and trans-4-OH-PZQ, and X-OH-PZQ in healthy subjects. METHODS: Two treatments were evaluated by single-dose PK studies; the reference treatment was a 20 mg/kg dose of praziquantel given alone. The test treatment was a 20 mg/kg dose of praziquantel given in combination with 200 mg of ketoconazole. The study had a balanced and randomised cross-over design. Serial blood samples were collected between 0 and 12 h after each drug administration. PZQ, and cis- and trans-4-OH-PZQ and X-OH-PZQ concentrations in plasma were determined by LC-MS. A non-compartmental approach was used for pharmacokinetic analysis. Data were analysed using ANOVA and assessment of the 90% confidence interval of the geometric means of the log-transformed PK parameters obtained for each treatment. RESULTS: The pharmacokinetics of PZQ following the two treatments, PZQ alone and PZQ + KTZ, were not equivalent based on the assessment of the 90% CI of the geometric mean ratios of the AUC and Cmax (α = 0.05). The geometric mean ratios of the AUC and Cmax were found to be 176.8% and 227% respectively. The 90% CI of the AUC and Cmax were found to be 129.8%-239.8% and 151.4%-341.4% respectively. The AUC of PZQ was increased by 75% with KTZ co-administration (3516 vs 6172 ng h/ml) (p < 0.01). Meanwhile, the mean AUC of trans-4-OH-PZQ increased by 67% (61,749 ng h/ml vs 103,105 ng h/ml) (p < 0.01). X-OH-PZQ levels were reduced by about 57% (semi-quantified as 7311 ng h/ml vs 3109 ng h/ml by using trans-4-OH as standards) (p < 0.01) with KTZ co-administration. CONCLUSIONS: The relative bioavailability of praziquantel was increased by concomitant KTZ administration. KTZ preferentially inhibited the formation of X-OH-PZQ rather than 4-OH-PZQ, confirming in vitro data which implicates CYP3A4 in the formation of X-OH-PZQ rather than 4-OH-PZQ. The 4-hydroxylation of PZQ was shown to be the major metabolic pathway of PZQ, as evidenced by larger quantities of 4-OH-PZQ produced, thus explaining the modest albeit significant effect of ketoconazole on PZQ pharmacokinetics.
RCT Entities:
AIM: The study sought to determine the effect of ketoconazole (KTZ) on the pharmacokinetics of praziquantel (PZQ) and on the formation of its major hydroxylated metabolites, cis- and trans-4-OH-PZQ, and X-OH-PZQ in healthy subjects. METHODS: Two treatments were evaluated by single-dose PK studies; the reference treatment was a 20 mg/kg dose of praziquantel given alone. The test treatment was a 20 mg/kg dose of praziquantel given in combination with 200 mg of ketoconazole. The study had a balanced and randomised cross-over design. Serial blood samples were collected between 0 and 12 h after each drug administration. PZQ, and cis- and trans-4-OH-PZQ and X-OH-PZQ concentrations in plasma were determined by LC-MS. A non-compartmental approach was used for pharmacokinetic analysis. Data were analysed using ANOVA and assessment of the 90% confidence interval of the geometric means of the log-transformed PK parameters obtained for each treatment. RESULTS: The pharmacokinetics of PZQ following the two treatments, PZQ alone and PZQ + KTZ, were not equivalent based on the assessment of the 90% CI of the geometric mean ratios of the AUC and Cmax (α = 0.05). The geometric mean ratios of the AUC and Cmax were found to be 176.8% and 227% respectively. The 90% CI of the AUC and Cmax were found to be 129.8%-239.8% and 151.4%-341.4% respectively. The AUC of PZQ was increased by 75% with KTZ co-administration (3516 vs 6172 ng h/ml) (p < 0.01). Meanwhile, the mean AUC of trans-4-OH-PZQ increased by 67% (61,749 ng h/ml vs 103,105 ng h/ml) (p < 0.01). X-OH-PZQ levels were reduced by about 57% (semi-quantified as 7311 ng h/ml vs 3109 ng h/ml by using trans-4-OH as standards) (p < 0.01) with KTZ co-administration. CONCLUSIONS: The relative bioavailability of praziquantel was increased by concomitant KTZ administration. KTZ preferentially inhibited the formation of X-OH-PZQ rather than 4-OH-PZQ, confirming in vitro data which implicates CYP3A4 in the formation of X-OH-PZQ rather than 4-OH-PZQ. The 4-hydroxylation of PZQ was shown to be the major metabolic pathway of PZQ, as evidenced by larger quantities of 4-OH-PZQ produced, thus explaining the modest albeit significant effect of ketoconazole on PZQ pharmacokinetics.
Entities:
Keywords:
Bioavailability; CYP3A4; Drug interactions; Drug metabolism; Pharmacokinetics; Praziquantel
Authors: Alexandra Probst; Daniela Hofmann; Olga S Fedorova; Sofia V Mazeina; Tatiana S Sokolova; Ekaterina Golovach; Jennifer Keiser Journal: Antimicrob Agents Chemother Date: 2022-09-12 Impact factor: 5.938