Mechanism-based modeling of the effect of a novel inhibitor of vascular adhesion protein-1 on albuminuria and renal function markers in patients with diabetic kidney disease.

The vascular adhesion protein-1 (VAP-1) inhibitor ASP8232 reduces albuminuria in patients with type 2 diabetes and chronic kidney disease. A mechanism-based model was developed to quantify the effects of ASP8232 on renal markers from a placebo-controlled Phase 2 study in diabetic kidney disease with 12 weeks of ASP8232 treatment. The model incorporated the available pharmacokinetic, pharmacodynamic (plasma VAP-1 concentration and activity), serum and urine creatinine, serum cystatin C, albumin excretion rate, urinary albumin-to-creatinine ratio, and urine volume information in an integrated manner. Drug-independent time-varying changes and different drug effects could be quantified for these markers using the model. Through simulations, this model provided the opportunity to dissect the relationship and longitudinal association between the estimated glomerular filtration rate and albuminuria and to quantify the pharmacological effects of ASP8232. The developed drug-independent model may be useful as a starting point for other compounds affecting the same biomarkers in a similar time scale.

Population pharmacokinetics and pharmacodynamics of a novel vascular adhesion protein-1 inhibitor using a multiple-target mediated drug disposition model.

ASP8232 is a novel inhibitor of vascular adhesion protein-1 that was under evaluation for reducing residual albuminuria in patients with diabetic kidney disease. To characterize the pharmacokinetics (PK) of ASP8232 and its effect on vascular adhesion protein 1 (VAP-1) plasma activity and VAP-1 concentrations (pharmacodynamics, PD) in an integrated and quantitative manner, a target mediated drug disposition model was developed based on pooled data from four completed clinical trials with ASP8232 in healthy volunteers, and in patients with diabetic kidney disease and diabetic macular edema, respectively. In this model, the binding of ASP8232 to its soluble and membrane-bound target in the central and peripheral compartments were included. The model was able to adequately describe the non-linear PK and PD of ASP8232. The observed difference in PK between healthy volunteers and renally impaired patients could be explained by an effect of baseline estimated glomerular filtration rate on ASP8232 clearance and relative bioavailability. The relationship between ASP8232 concentration and VAP-1 inhibition was successfully established and can be applied to simulate drug exposure and degree of VAP-1 inhibition for any given dose of ASP8232 across the spectrum of renal function.

Darexaban (YM150), an oral direct factor Xa inhibitor, has no effect on the pharmacokinetics of digoxin.

To investigate the impact of the direct Factor Xa inhibitor darexaban administered in a modified-release formulation (darexaban-MR) on the pharmacokinetic (PK) profile of digoxin. In this Phase I, randomized, double-blind, two-period crossover study (8 days for each treatment, 10 days washout), 24 healthy subjects received darexaban-MR 120 mg once/day (qd) + digoxin 0.25 mg qd in one treatment period, and placebo + digoxin 0.25 mg qd in the other treatment period. Blood for PK assessment of digoxin and darexaban was obtained in serial profile on day 8, as well as pre-dose on day 6-7; urinary PK samples were obtained up to 24 h after the last dose on day 8. A lack of interaction was determined if 90 % confidence intervals (CIs) for the geometric mean ratios (GMR) of digoxin C max,ss and AUC0-24h,ss with and without darexaban-MR co-administration were within 0.80-1.25 limits. Pharmacodynamic activity was assessed by international normalized ratio and activated partial thromboplastin time. Twenty-three subjects completed the study. The GMR (90 % CI) for C max,ss and AUC0-24h,ss of digoxin plus darexaban versus digoxin plus placebo was 1.03 (90 % CI: 0.94-1.12) and 1.11 (90 % CI: 1.05-1.17), respectively. The 90 % CI for the GMRs fell within the limits of 0.80-1.25, indicating a lack of drug-drug interaction. Co-administration of digoxin with darexaban-MR was well tolerated, with no unexpected treatment-emergent adverse events or safety concerns. Co-administration of darexaban-MR did not impact the steady-state PK profile of digoxin.

The pharmacokinetics of darexaban (YM150), an oral direct factor Xa inhibitor, are not affected by ketoconazole, a strong inhibitor of CYP3A and P-glycoprotein.

We investigated the effects of ketoconazole on the pharmacokinetics (PK) of the direct clotting factor Xa inhibitor darexaban (YM150) and its main active metabolite darexaban glucuronide (YM-222714) which almost entirely determines the antithrombotic effect. In this open-label, randomized, two-period crossover study, 26 healthy male volunteers received in one treatment period a single dose of darexaban 60 mg, and in the other treatment period, ketoconazole 400 mg once daily on Days 1-9 with a single dose of darexaban 60 mg on Day 4. Washout between periods was at least 1 week. The geometric mean ratio (90% confidence interval) of darexaban glucuronide (darexaban plus ketoconazole versus darexaban) for AUCinf was 1.11 (1.00, 1.23), and for Cmax 1.18 (1.03, 1.35). Darexaban concentrations remained very low (AUClast ∼196-fold lower) in relation to darexaban glucuronide concentrations. In conclusion, the PK of darexaban glucuronide was not affected to a clinically relevant degree by co-administration of the strong CYP3A/P-glycoprotein inhibitor, ketoconazole. The PK of the parent compound darexaban were changed, however, concentrations remained quantitatively insignificant in relation to the main active moiety, darexaban glucuronide.

Clinical pharmacokinetics, pharmacodynamics, safety and tolerability of darexaban, an oral direct factor Xa inhibitor, in healthy Caucasian and Japanese subjects.

BACKGROUND: Darexaban (YM150) is a potent direct factor Xa (FXa) inhibitor developed for the prophylaxis of venous and arterial thromboembolic disease. This drug is rapidly and extensively metabolized to darexaban glucuronide (YM-222714), which is a pharmacologically active metabolite. The objective of the present study was to evaluate the clinical pharmacokinetics (PK), pharmacodynamics (PD), safety and tolerability of ascending multiple oral doses of darexaban in healthy non-elderly Caucasian and Japanese subjects. METHODS: A randomized, double-blind, placebo-controlled, single and multiple dose-escalating study of healthy Caucasian and Japanese male and female subjects was performed. The tested doses were 20, 60, 120 and 240 mg of darexaban. RESULTS: Plasma concentrations of darexaban glucuronide increased with dose, and Cmax and AUC increased dose-dependently after both single and repeated doses in both Caucasians and Japanese. Cmax was about 17%-19% lower in Caucasians than in Japanese, although AUC appeared to be similar. The time-profiles of prothrombin time reported as the international normalized ratio (PT-INR), activated partial thromboplastin time (aPTT) and FXa activity closely followed the time-concentration profile of darexaban glucuronide, and no clear differences were observed in ethnicity. Overall, 38 of the 82 enrolled subjects reported a total of 57 treatment-emergent adverse events (TEAEs). Fifty-five TEAEs were of mild intensity and two were of moderate intensity. CONCLUSION: It is concluded that single and multiple doses of darexaban are safe and well tolerated up to 240 mg with predictable PK and PD profiles in both Caucasians and Japanese, and that ethnicity does not affect its PK, PD or tolerability.

The pharmacokinetics of darexaban are not affected to a clinically relevant degree by rifampicin, a strong inducer of P-glycoprotein and CYP3A4.

AIMS: We investigated the effects of rifampicin on the pharmacokinetics (PK) of the direct clotting factor Xa inhibitor darexaban (YM150) and its main active metabolite, darexaban glucuronide (YM-222714), which almost entirely determines the antithrombotic effect. METHODS: In this open-label, single-sequence study, 26 healthy men received one dose of darexaban 60 mg on day 1 and oral rifampicin 600 mg once daily on days 4-14. On day 11, a second dose of darexaban 60 mg was given with rifampicin. Blood and urine were collected after study drug administration on days 1-14. The maximal plasma drug concentration (C(max)) and exposure [area under the plasma concentration-time curve from time zero to time of quantifiable measurable concentration; (AUC(last)) or AUC(last) extrapolated to infinity (AUC(∞))] were assessed by analysis of variance of PK. Limits for statistical significance of 90% confidence intervals for AUC and C(max) ratios were predefined as 80-125%. RESULTS: Darexaban glucuronide plasma exposure was not affected by rifampicin; the geometric mean ratio (90% confidence interval) of AUC(last) with/without rifampicin was 1.08 (1.00, 1.16). The C(max) of darexaban glucuronide increased by 54% after rifampicin [ratio 1.54 (1.37, 1.73)]. The plasma concentrations of darexaban were very low (<1% of darexaban glucuronide concentrations) with and without rifampicin. Darexaban alone or in combination with rifampicin was generally safe and well tolerated. CONCLUSIONS: Overall, rifampicin did not affect the PK profiles of darexaban glucuronide and darexaban to a clinically relevant degree, suggesting that the potential for drug-drug interactions between darexaban and CYP3A4 or P-glycoprotein-inducing agents is low.

Absorption, metabolism and excretion of darexaban (YM150), a new direct factor Xa inhibitor in humans.

1. The absorption, metabolism and excretion of darexaban (YM150), a novel oral direct factor Xa inhibitor, were investigated after a single oral administration of [(14)C]darexaban maleate at a dose of 60 mg in healthy male human subjects. 2. [(14)C]Darexaban was rapidly absorbed, with both blood and plasma concentrations peaking at approximately 0.75 h post-dose. Plasma concentrations of darexaban glucuronide (M1), the pharmacological activity of which is equipotent to darexaban in vitro, also peaked at approximately 0.75 h. 3. Similar amounts of dosed radioactivity were excreted via faeces (51.9%) and urine (46.4%) by 168 h post-dose, suggesting that at least approximately half of the administered dose is absorbed from the gastrointestinal tract. 4. M1 was the major drug-related component in plasma and urine, accounting for up to 95.8% of radioactivity in plasma. The N-oxides of M1, a mixture of two diastereomers designated as M2 and M3, were also present in plasma and urine, accounting for up to 13.2% of radioactivity in plasma. In faeces, darexaban was the major drug-related component, and N-demethyl darexaban (M5) was detected as a minor metabolite. 5. These findings suggested that, following oral administration of darexaban in humans, M1 is quickly formed during first-pass metabolism via UDP-glucuronosyltransferases, exerting its pharmacological activity in blood before being excreted into urine and faeces.