Relationship between everolimus exposure and safety and efficacy: meta-analysis of clinical trials in oncology.

BACKGROUND: In patients with solid tumours, daily everolimus dosing demonstrated dose proportionality and linear pharmacokinetics. A meta-analysis was conducted to characterise the relationship between everolimus Cmin and efficacy and safety and the effect of CYP3A4 and P-glycoprotein (PgP) substrate/inhibitor/inducer coadministration on everolimus trough concentration (Cmin). METHODS: Individual patient data from five phase 2/3 studies, in which steady state, predose pharmacokinetic samples were taken from patients with solid tumours administered everolimus 10mg/day, were pooled. FINDINGS: Efficacy and safety were evaluable for 945 and 938 patients, respectively. A 2-fold increase in everolimus Cmin increased the likelihood of tumour size reduction (odds ratio 1.40, 95% confidence interval (CI) 1.23-1.60), was associated with a trend for reduced risk of progression-free survival events (risk ratio [RR] 0.90, 95% CI 0.69-1.18) and increased the risk of grade ⩾3 pulmonary (RR 1.93, 95% CI 1.12-3.34), stomatitis (RR 1.49, 95% CI 1.05-2.10) and metabolic (RR 1.30, 95% CI 1.02-1.65) events. Coadministering everolimus with strong CYP3A4 and PgP inhibitors increased everolimus Cmin by 10% and 20%, respectively; coadministration with CYP3A4 inducers reduced Cmin by 7%. INTERPRETATION: A 2-fold increase in everolimus Cmin was associated with improved tumour size reduction and increased risk of high-grade pulmonary, metabolic and stomatitis events. FUNDING: Novartis Pharmaceuticals Corporation.

The pharmacokinetic profile of recombinant human erythropoietin is unchanged in patients undergoing cardiac surgery.

BACKGROUND: In anticipation of future studies, we examined the pharmacokinetics profile of erythropoietin (EPO) in patients undergoing cardiac surgery. METHODS: Cardiac surgical patients were enrolled into one of six groups: four cardiopulmonary bypass (CPB) groups [placebo (n = 6), 250 IU/kg EPO (n = 3), 500 IU/kg EPO (n = 3), and 500 IU/kg EPO, two doses (n = 6)] and two off-pump coronary artery bypass (OPCAB) groups [placebo (n = 3) and 500 IU/kg EPO (n = 3)]. The EPO was administered prior to anesthesia and 10 min after CPB (if required). Blood samples for serum EPO were collected at baseline, 10 min after dosing, 5 min after sternotomy, during CPB or the equivalent for OPCAB (5, 15, 45, 60 min), and post-CPB (5, 15, 45, and 60 min, 6, 12 and 24 h, and daily until day 5). RESULTS: Endogenous EPO increased within 24 h of surgery in the placebo group and remained elevated. There was approximately a 40% decrease in serum EPO concentration at the initiation of CPB due to an increase in circulatory blood volume. There were no differences in apparent volume of distribution in the plasma (Vc) (42.2 +/- 9.9, 39.8 +/- 6.3, 42.3 +/- 14.0 mL/kg), clearance (CL) (4.63 +/- 1.14, 3.44 +/- 0.68, 4.27 +/- 0.52 mL h/kg), and t((1/2)) (16.4 +/- 8.0 16.9 +/- 10.6, 22.4 +/- 9.3 h) between the CPB treatment groups. The pharmacokinetic profile of EPO in the OPCAB group was similar to that for the CPB groups: Vc = 39.3 +/- 7.0 mL/kg, CL = 4.98 +/- 0.17 mL h/kg and t((1/2)) = 17.1 +/- 18.1 h. CONCLUSIONS: CPB had no apparent effect on the pharmacokinetics of EPO.

Pharmacokinetic and pharmacodynamic modeling of recombinant human erythropoietin after multiple subcutaneous doses in healthy subjects.

A pharmacokinetic and pharmacodynamic (PK/PD) model for recombinant human erythropoietin (Epoetin alfa) in healthy subjects was developed to describe the time profiles of changes in serum Epoetin alfa and the pharmacological responses of percent reticulocytes, total red blood cell counts, and hemoglobin after single and multiple subcutaneous administration of Epoetin alfa. Data used in the development of the model were obtained from a clinical study carried out in healthy volunteers in which Epoetin alfa was administered either as 150 IU/kg three-times-a-week (t.i.w.) or fixed 40,000 IU weekly (q.w.) doses for 4 weeks. A dual-absorption rate model (fast zero-order and slow first-order inputs) with linear disposition kinetics was used to characterize the pharmacokinetics of erythropoietin after subcutaneous administration. A new catenary cell production and lifespan loss model was used to fit the pharmacodynamic data yielding estimates of SC50, Smax, and other pharmacodynamic parameters. Flip-flop kinetics was apparent in the pharmacokinetics as the absorption rate was slower (k(a) = 0.7 day(-1)) than the elimination rate (CL/V(d) = 1.2-9.2 day(-1)). In the pharmacodynamics, an SC50 of 58 mIU/mL was estimated indicating that low serum erythropoietin concentrations were sufficient to produce pharmacological effects. The established PK/PD model predicts similar pharmacological responses of hemoglobin and total red blood cell counts for the 150 IU/kg t.i.w. and 40,000 IU q.w. regimens in healthy subjects.

The pharmacokinetics of erythropoietin in the cerebrospinal fluid after intravenous administration of recombinant human erythropoietin.

OBJECTIVES: Erythropoietin (EPO) was originally described as a regulator of erythropoiesis. Recently, synthesis of EPO and expression of the EPO receptor (EPO-R) have been reported for the central nervous system (CNS). The potential use of EPO to prevent or reduce CNS injury and the paucity of information regarding its entry into the human CNS led us to examine the pharmacokinetics (PK) of recombinant human EPO (r-HuEPO) in the serum and cerebrospinal fluid (CSF). METHODS: Four patients with Ommaya reservoirs were enrolled to facilitate serial CSF sampling. R-HuEPO was given intravenously (IV) in single doses of 40,000 IU or 1,500 IU/kg and in multiple doses of 40,000 IU daily for 3 days. RESULTS: The EPO concentrations in the CSF increased after a period of slow equilibration. Linear first-order distribution kinetics were observed for serum and CSF. The concentration of EPO in the CSF was proportional to the serum concentration of EPO and the permeability of the blood-brain barrier (BBB), as determined by the albumin quotient (QA=[albumin] CSF/[albumin] serum). A rise in the CSF concentration was seen as early as 3 h after IV administration. Peak levels (C(max)) were reached between 9 h and 24 h. After a single dose of 1,500 IU/kg, the Cmax in the CSF ranged from 11 mIU/ml to 40 mIU/ml, and the ratios of CSF/serum Cmax ranged from 3.6x10-4 to 10.2x10-4. The terminal half-life (t1/2) values of EPO in serum and CSF were similar. The t(1/2) of r-HuEPO in the CSF ranged from 25.6 h to 35.5 h after a single dose of 1,500 IU/l. Using these parameters a PK model was generated that predicts the concentration-time profile of EPO in the CSF. CONCLUSIONS: We report that r-HuEPO can cross the human BBB and describe for the first time the PK of EPO in the CSF after IV administration. Our data suggest that the concentration-time profile of EPO in the CSF can be predicted for individual patients if the serum concentration of EPO and the Q(A) are known. This information may be useful in the design of clinical trials to explore the potential therapeutic effects of EPO during CNS injury.

Pharmacokinetic and pharmacodynamic modeling of recombinant human erythropoietin after single and multiple doses in healthy volunteers.

This study describes a pharmacokinetic (PK) model to account for serum recombinant human erythropoietin (rHuEpo) concentrations in healthy volunteers following intravenous (IV) and subcutaneous (SC) dosing; it also characterizes the pharmacodynamics (PD) of SC rHuEpo effects on reticulocytes, red blood cells (RBC), and hemoglobin (Hb) in blood. Data were obtained from 4 clinical studies carried out in healthy volunteers. Epoetin alfa (rHuEpo) was administered as 5 single IV doses ranging from 10 to 500 IU/kg, as 8 single SC doses ranging from 300 to 2400 IU/kg, and as 2 multiple SC dosage regimens (150 IU/kg/3 times a week [tiw] and 600 IU/kg/wk). A dual-absorption rate model (fast zero-order and slow first-order inputs) with nonlinear disposition characterized the PK of SC rHuEpo. A high K(m) value was obtained indicating that clearance was mildly nonlinear. Absorption was slow (t(max) approximately 24 hours), and the bioavailability of SC rHuEpo increased with dose (ranging from 46%-100%). A catenary cell production and loss model with a feedback down regulation component was used to fit the reticulocyte data yielding estimates of the stimulatory capacity (S(max)), sensitivity (SC(50)), and life span parameters. These parameters were used for simulations of RBC and Hb profiles. An SC(50) of 27 to 61 IU/L was estimated indicating that low physiological plasma rHuEpo concentrations were sufficient to produce pharmacological effects. No marked sex-dependent differences in clinical responses to rHuEpo therapy were found despite baseline differences. Realistic pharmacokinetic and physiological models accounted for clinical responses from a wide array of dosing conditions with rHuEpo. The rationale for greater efficacy of SC administration of rHuEpo compared to IV was ascertained.

Comparative pharmacokinetics of coumarin anticoagulants L: Physiologic modeling of S-warfarin in rats and pharmacologic target-mediated warfarin disposition in man.

The anticoagulant warfarin exemplifies a type of drug that exhibits high affinity to pharmacologic target sites of limited capacity, resulting in unusual concentration-dependent distribution and elimination properties. The time course of warfarin concentrations in the serum, liver, kidneys, muscle, and abdominal fat of male Sprague-Dawley rats was determined by high-performance liquid chromatography after IV injection of a 0.25 or 1.0 mg/kg dose. The rats were preclassified on the basis of their serum free fraction of warfarin; animals with free fraction values of approximately 0.004 and 0.01 and corresponding differences in elimination half-life were selected for study, yielding four experimental groups. Several rats of each group were sacrificed periodically over approximately 80-240 h for determination of drug concentrations. S-warfarin concentrations in serum declined apparently exponentially over at least one order of magnitude. During this time, concentrations in all other assayed tissues declined much more slowly. In another experiment, S-warfarin concentrations in serum and liver were followed for approximately 50 days after IV injection of a 1 mg/kg dose. This revealed a terminal, very slow elimination phase in serum nearly parallel to the decline in liver drug concentrations. Simultaneous physiologic modeling of all data (30 equations) using ADAPT II (Biomedical Simulations Resource, Los Angeles, CA), with intrinsic clearance, the dissociation constant of the warfarin-high affinity binding site complex, and two binding parameters for the (unassayed) remainder tissue compartment as parameters of unknown value, yielded very good fittings and parameter estimates with relatively small standard deviations. The unusual dose-dependent accumulation characteristics of this type of drug during continuous infusion are demonstrated by computer simulation of published results of warfarin infusions in rats. Utilization of a model premised on similar target-mediated drug disposition also allowed characterization of data from the literature for racemic warfarin pharmacokinetics in man.

Pharmacokinetic and pharmacodynamic modeling of recombinant human erythropoietin after intravenous and subcutaneous dose administration in cynomolgus monkeys.

The pharmacokinetics (PK) and pharmacodynamics (PD) of recombinant human erythropoietin (rHuEpo) were investigated in monkeys. A two-compartment model with dual input and nonlinear disposition could adequately characterize the PK of rHuEpo upon three intravenous and six s.c. administrations. The kinetic model suggests rapid zero-order absorption of part of the s.c. dose (35%) followed by a slow first-order entry through the lymphatics. The s.c. treatments caused a delayed dose-dependent rise in reticulocyte numbers peaking between 100 and 200 h and returning to baseline by 300 to 400 h. This was followed by steady rises in red blood cell (RBC) and hemoglobin counts. A physiological catenary model based on a life span concept with rHuEpo stimulating the production of two cell populations (progenitor cells and erythroblasts) was applied. The model could adequately describe the reticulocyte responses upon the various s.c. treatments, giving estimates of maturation times for cells in the various stages of differentiation including the early progenitor cells (70.4 h), erythroblasts (15.0 h), and reticulocytes (141.6 h) that are close to the literature reported values. An Smax of 3.13 was estimated indicating a moderate maximum stimulation of erythropoiesis, whereas the SC50 was 842 IU/l. The model was used to effectively predict the increases in RBC and hemoglobin counts as well. In conclusion, the physiological PK/PD model developed could adequately describe the time course of rHuEpo effects, yielding realistic estimates of cell life span parameters.