Clofarabine for injection is a second-generation nucleoside analog approved in the United States (Clolar(®)) and Europe (Evoltra(®)) for the treatment of pediatric relapsed or refractory acute lymphoblastic leukemia. This report describes the population pharmacokinetics of clofarabine and its metabolite 6-ketoclofarabine in adult and pediatric patients with hematologic malignancies or solid tumors. Clofarabine pharmacokinetics were best described by a 2-compartment model with linear elimination and first-order absorption after oral administration. Clofarabine was rapidly absorbed following oral administration with a mean absorption time of less than 2 h and bioavailability of 57.5%. The important covariates affecting clofarabine pharmacokinetics were age, weight, and estimated creatinine clearance (eCrCL). No difference in pharmacokinetics was observed between sexes, races, or disease type. The elimination half-life was dependent on all the covariates but was generally less than 7 h in all cases. A difference in clofarabine pharmacokinetics was observed between adults and children. For a pediatric patient 3 years old weighing 16 kg with an eCrCL of 138 mL/min/1.73 m(2), the population estimates for total systemic clearance and volume of distribution at steady-state were 18.3 L/h (1.14 L/h/kg) and 92.9 L (5.81 L/kg), respectively. α- and β-half-life were 0.9 and 4.4 h, respectively. For an elderly patient 82 years old weighing 96 kg with an eCrCL of 46 mL/min/1.73 m(2), the population estimates for CL and Vdss were 21.5 L/h (0.22 L/h/kg) and 257.4 L (268 L/kg), respectively. α- and β-half-life were 0.5 and 10.6 h, respectively. Because of the difference in pharmacokinetics, adults have higher exposure than children given a similar dose standardized to body surface area. The exact mechanism of this difference is not understood. As eCrCL decreased, exposure increased due to reduced total systemic clearance. In the case of moderate (eCrCL 30 to 60 mL/min/1.73 m(2)) and severe (eCrCL <30 mL/min/1.73 m(2)) renal impairment, dose reduction may be needed to maintain similar exposure in an equivalent patient of the same age, weight, and normal renal function after both oral and intravenous administration. 6-Ketoclofarabine was a minor metabolite with peak plasma concentrations occurring about 1 h after the start of the infusion and having a metabolite ratio averaging less than 5% and not more than 8% for any particular individual. 6-Ketoclofarabine was rapidly cleared from plasma with an average apparent half-life of 4.9 h (range 3.9 to 6.2 h). No accumulation of 6-ketoclofarabine was observed with predose samples all below the limit of quantification on Days 8 and 15. Further monitoring of 6-ketoclofarabine is not required in future studies.
The population pharmacokinetics of plasma clofarabine and intracellular clofarabine triphosphate were characterized in pediatric patients with acute leukemias. Traditional model-building techniques with NONMEM were used. Covariates were entered into the base model using a forward selection significance level of .05 and a backwards deletion criterion of .005. Model performance, stability, and influence analysis were assessed using the nonparametric bootstrap and n-1 jackknife. Simulations were used to understand the relationship between important covariates and exposure. A 2-compartment model with weight (scaled to a 40-kg reference patient) modeled as a power function on all pharmacokinetic parameters (0.75 on clearance-related terms and 1.0 on volume-related terms) was fit to plasma clofarabine concentrations (n = 32). White blood cell (WBC) count, modeled as a power function (scaled to a WBC count of 10 x 10(3)/microL), was a significant predictor of central volume with power term 0.128 +/- 0.0314. A reference patient had a systemic clearance of 32.8 L/h (27% between-subject variability [BSV]), a central volume of 115 L (56% BSV), an intercompartmental clearance of 20.5 L/h (27% BSV), and a peripheral volume of 94.5 L (39% BSV). Intracellular clofarabine triphosphate concentrations were modeled using a random intercept model without any covariates. The average predicted concentration was 11.6 +/- 2.62 microM (80% BSV), and although clofarabine triphosphate half-life could not be definitively estimated, its value was taken to be longer than 24 hours. The results confirm that clofarabine should continue being dosed on a per-squaremeter or per-body-weight basis.
The MTD for weekly DN-101 was established as 45 mug. The DLTs observed were two episodes of rapidly reversible grade 2 hypercalcemia in two of the six patients treated at 60 microg weekly. Repeat doses of DN-101 at 45 microg weekly are well tolerated and this dose is suitable for studies of weekly DN-101 in cancer patients.
Using the structural information gathered from the X-ray structures of various cyclic urea/HIVPR complexes, we designed and synthesized many nonsymmetrical P2/P2'-substituted cyclic urea analogues. Our efforts concentrated on using an indazole as one of the P2 substituents since this group imparted enzyme (Ki) potency as well as translation into excellent antiviral (IC90) potency. The second P2 substituent was used to adjust the physical and chemical properties in order to maximize oral bioavailability. Using this approach several very potent (IC90 11 nM) and orally bioavailable (F% 93-100%) compounds were discovered (21, 22). However, the resistance profiles of these compounds were inadequate, especially against the double (I84V/V82F) and ritonavir-selected mutant viruses. Further modification of the second P2 substituent in order to increase H-bonding interactions with the backbone atoms of residues Asp 29, Asp 30, and Gly 48 led to analogues with much better resistance profiles. However, these larger analogues were incompatible with the apparent molecular weight requirements for good oral bioavailability of the cyclic urea class of HIVPR inhibitors (MW < 610).
Intravascular clot formation is an important factor in a number of cardiovascular diseases. Therefore, the prevention of blood coagulation has become a major target for new therapeutic agents. One attractive approach is the inhibition of factor Xa (FXa), the enzyme directly responsible for thrombin activation. Herein we report a series of isoxazoline derivatives which are potent FXa inhibitors. Optimization of the side chain at the quaternary position of the isoxazoline ring led to SK549 which showed subnanomolar FXa potency (K(i) 0.52 nM). SK549 shows good selectivity for FXa compared to thrombin and trypsin, potent antithrombotic effect in the rabbit arterio-venous thrombosis model, and improved pharmacokinetics relative to other compounds evaluated from this series.
Background: Intermittent administration allows substantial dose escalation of calcitriol but limited bioavailability of the commercially available formulations at high doses is limiting. In this dose escalation study, we sought to evaluate the tolerability and pharmacokinetics of a single oral dose of DN-101, a high-dose calcitriol formulation. Methods: DN-101 doses were escalated in sequential groups of three to six patients with advanced solid tumors. Dose-limiting toxicity was defined as grade z2 hypercalcemia or grade z3 persistent treatment-related toxicities. Single-dose administration of 15,30, 60, 75, 90, 105, 135, and 165 Ag was tested. Results: Thirty-eight patients were enrolled in 2002 and 2003. The median age was 70 years (range, 44-91 years). Dose escalation was stopped at the 165 Ag level when the number of capsules required at one time reached 11. No dose-limiting toxicities occurred. Transient and selflimited grade 3 toxicities were hyponatremia (2) and proteinuria (1). A dose-proportional increase in peak concentration (C max ) and area under the concentration curve (AUC) was seen across the full range of DN-101doses tested. At the 165 Ag dose, C max was 6.21 F1.99 ng/mL, AUC(0-24) was 41.3 F 9.77 ng h/mL, AUC(0-1) was 55.4 F 8.44, and half-life (T 1/2 ) was 16.2 hours. Conclusions: At doses between 15 and 165 Ag, DN-101 exhibits linear pharmacokinetics. At 165 Ag, DN-101 achieves systemic exposure that is 5-to 8-fold higher than that achieved with commercial formulations of calcitriol, which makes DN-101 comparable to that required for antitumor activity in vivo in a murine squamous cell carcinoma model.Numerous studies have shown that calcitriol, the natural ligand of the vitamin D receptor, potently inhibits cell proliferation in vitro and in vivo in many cell types, including carcinomas of the breast, prostate, colon, skin, and brain, myeloid leukemia cells, and others (1, 2). Recently, calcitriol has also been shown to induce apoptosis and to inhibit angiogenesis, tumor invasion, and metastases (reviewed in ref. 3). Calcitriol or its analogues have been shown to produce additive or synergistic antineoplastic activity with a broad range of agents including dexamethasone (4, 5), retinoids (6, 7), tamoxifen (8 -10), and radiation (11, 12), and several cytotoxic chemotherapy drugs, including docetaxel (13), paclitaxel (14), platinum compounds (15, 16), mitoxantrone (17), doxorubicin (18), and etoposide (19), are enhanced by calcitriol or its analogues. These preclinical data have stimulated interest in developing calcitriol for cancer treatment. Antineoplastic effects of calcitriol occur at supraphysiologic concentrations. In in vitro models of human prostate (LNCaP and DU145), pancreas (CaPAN-1), lung (MV522), breast (MCF-7), myeloma (H929), leukemia (HL-60), rat prostate (Dunning), and murine squamous cell carcinoma (SCC), IC 50 values of 1 to 50 nmol/L have been reported (14, 20 -22). Johnson and Trump also confirm these findings.5 Kumagai et al. found that the 1,25 dihydroxychole...
We present several novel P1/P1' substituents that can replace the characteristic benzyl P1/P1' moiety of the cyclic urea based HIV protease inhibitor series. These substituents typically provide 5-10-fold improvements in binding affinity compared to the unsubstituted benzyl analogs. The best substituent was the 3,4-(ethylenedioxy)benzyl group. Proper balancing of the molecule's lipophilicity facilitated the transfer of this improved binding affinity into a superior cellular antiviral activity profile. Several analogs were evaluated further for protein binding and resistance liabilities. Compound 18 (IC90 = 8.7 nM) was chosen for oral bioavailability studies based on its log P and solubility profile. A 10 mg/kg dose in dogs provided modest bioavailability with Cmax = 0.22 microg/mL. X-ray crystallographic analysis of two analogs revealed several interesting features responsible for the 3,4-(ethylenedioxy)benzyl-substituted analog's potency: (1) Comparing the two complexes revealed two distinct binding modes for each P1/P1' substituent; (2) The ethylenedioxy moieties are within 3.6 A of Pro 81 providing additional van der Waals contacts missing from the parent structure; (3) The enzyme's Arg 8 side chain moves away from the P1 substituent to accommodate the increased steric volume while maintaining a favorable hydrogen bond distance between the para oxygen substituent and the guanidine NH.
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