Plasma and Cerebrospinal Fluid Population Pharmacokinetics of Temozolomide in Malignant Glioma Patients

Patients and Treatments.

Patients with histologically proven malignant glioma were enrolled in two parallel clinical phase II trials. Newly diagnosed glioblastoma multiforme patients were treated with radiotherapy and concomitant and adjuvant temozolomide (pilot study; Ref. 18 ); chemonaive patients with recurrent or progressive malignant gliomas (glioblastoma multiforme or anaplastic astrocytoma/anaplastic oligoastrocytoma) received TMZ as first-line chemotherapy (recurrent study; Ref. 19 ). All patients participating in one of these two phase II trials were also eligible for participation in this ancillary and nonmandatory pharmacokinetic study, and a separate informed consent was obtained for this part. Other eligibility criteria included absence of increased intracranial pressure documented by magnetic resonance imaging, age ≥18 years, eastern cooperative oncology group performance status ≤2 or Karnofsky performance status ≥70%, adequate hematological, renal, and hepatic functions, defined as absolute neutrophil count ≥1.5 × 10⁹/liter; platelet count ≥100 × 10⁹/liter; hemoglobin >90 g/liters; serum creatinine and total serum bilirubin ≤1.5 times the upper limit of normal; aspartate aminotransferase, alanine aminotransferase, and alkaline phosphatase <2.5 times the upper limit of normal. Exclusion criteria included any medical conditions that could interfere with the oral administration of TMZ or any previous or concurrent malignancies at other sites, with the exception of the cervix and nonmelanoma skin cancer. The clinical and pharmacokinetic protocols were reviewed and approved by the local ethics committee.

TMZ was administered on one of the two following schedules:

1. Continuous schedule (pilot study). 75 mg/m² TMZ daily for 42–49 days in a fasting state, 1 h before radiotherapy (2 Gy/fraction; 5 days/week, total dose, 60 Gy) or in the morning on weekends. After a 4-week interval, patients received up to 6 cycles of adjuvant TMZ at 200 mg/m²/day × 5 days, every 4 weeks (18) .

2. Intermittent schedule. Administration of TMZ at 150–200 mg/m²/day × 5 days every 4 weeks, for up to 6 adjuvant treatment cycles (pilot study) or up to 17 cycles in recurrent disease (recurrent study), until occurrence of unacceptable toxicity, or until evidence of tumor progression (19) .

Prophylactic antiemetics (4 mg/day ondansetron, 1 mg/day granisetron; 10–40 mg/day metoclopramide, 50 mg/day alizapride) were used only as required during concomitant radiotherapy plus TMZ therapy and routinely prescribed once a day before adjuvant or recurrent TMZ treatment. Anticonvulsants [cytochrome P-450 inducers (phenytoïne, carbamazepine); cytochrome P-450 inhibitors (valproïc acid); others (lamotrigine, gabapentine, clonazepam)], corticosteroids (dexamethasone, prednisone), antacids (omeprazole, ranitidine) or the cytoprotective agent, sucralfate, were administered as needed.

Pharmacokinetic Sampling and Processing.

Plasma and CSF concentrations of TMZ were analyzed in sparse samples collected on different occasions over a 17 months period. Venous blood samples (5 ml) were drawn into cooled lithium-heparinized tubes at three different times between 0.2 and 8.4 h after oral TMZ administration on the first (day 1) and last day (day 42–49) of the concomitant radiotherapy plus TMZ therapy (continuous schedule) and on day 1 and day 5 during first cycle of adjuvant or recurrent TMZ treatment (intermittent schedule). The exact time of TMZ administration as well as the time of blood and CSF sampling were carefully recorded. After collection, samples were immediately centrifuged (2000 rpm during 10 min at 4°C), the plasma was then acidified with 0.1 ml 1 m HCl and stored at −20°C until analysis. CSF was collected on two occasions through a lumbar puncture between 1.3 and 6.6 h after oral TMZ intake. A lumbar puncture was performed on day 1 of the concomitant radiochemotherapy (continuous schedule) and on the first day of the adjuvant or recurrent chemotherapy (intermittent schedule). In one patient, the presence of an Ommaya reservoir, implanted previously because of the development of an occlusive hydrocephalus, allowed the collection of sequential CSF samples. Processing of the CSF samples was analogous to the blood samples but did nor require centrifugation.

Blood and CSF Samples Analysis.

Quantitation of TMZ in plasma and CSF was performed by reversed-phase high-performance liquid chromatography analysis using a slight modification of our method described previously (20) , to improve the sensibility of the method for the CSF samples analysis, for which lower TMZ levels were expected. The clean-up procedure involved a solid-phase extraction of biological sample (100 μl) on a 100 mg C₁₈-endcapped cartridge (Chromabond, Macherey-Nagel, Düren, Germany). Matrix components were eliminated with 750 μl of 0.5% acetic acid. TMZ was subsequently eluted with 1250 μl of methanol. The resulting eluate was evaporated under nitrogen at room temperature, reconstituted in 100 and 200 μl of 0.5% acetic acid for CSF and plasma samples respectively, and analyzed by high-performance liquid chromatography.

The chromatographic system consisted of a HP 1050 isocratic/quaternary pump (Hewlett-Packard, Böblingen, Germany) connected to an HP 1050 autosampler and an HP 1050 UV diode-array detector set at UV 330 nm. Separations were performed on a Nucleosil 100–5 C₁₈ AB column (125 × 4 mm inside diameter; Macherey-Nagel) equipped with an Nucleosil C₁₈ AB (8 × 4 mm) guard column. The high-performance liquid chromatography mobile phase was methanol/0.5% acetic acid (7:93 v/v). The flow rate was 1 ml/min. The retention time for TMZ and ethazolastone were 2.7 and 6.8 min, respectively. A HP ChemStation A-O6-03 software loaded onto a Compaq Deskpro EP/SB was used for the data processing of the chromatograms.

The plasma calibration standards (0.4, 2, 4, 10, and 20 μg/ml) and control samples (1, 10, and 18 μg/ml) were prepared with 5 ml of blank human plasma, added to TMZ stock solution (prepared in 0.1 m HCl), acidified with 250 μl of 2 m HCl and completed ad 5.5 ml with 0.1 m HCl. The CSF calibration standards (0.1, 0.2, 0.5, 1, and 2 μg/ml) and controls (0.33, 0.5, and 1 μg/ml) were prepared with an artificial CSF solution [0.8 g/liter glucose, 0.2 g/liter albumin, 7.3 g/liter NaCl, and 1.9 g/liter NAHCO₃ (adjusted to pH 7.5 with phosphate buffer)], added to various volumes of TMZ stock solution and acidified similarly to the plasma samples.

A linear response was observed for all calibration curves between 0.4 and 20 μg/ml and 0.1 to 2 μg/ml in plasma and CSF, respectively (r > 0.999). This method had a limit of quantitation of 0.2 μg/ml and 0.1 μg/ml in plasma and CSF, respectively, as well as an inter-assay variability and bias of <15%, in accordance with the recommendations of the Conference Report on Bioanalytical Method Validation (21) .

Model-Based Pharmacokinetic Analysis.

Population analysis was performed using the NONMEM computer program (version V with NM-TRAN version II) developed by Beal and Sheiner (22) . NONMEM uses mixed (fixed and random) effects regression to estimate the population mean and the variability of pharmacokinetic parameters and to identify factors that may influence them. A three-compartment model with first order absorption from the gastrointestinal tract (Fig. 1)⇓ was used to model TMZ in plasma and in CSF according to: where A₁, A₂, and A₃ are the amount in the absorption, plasma, and CSF compartments, respectively; K_a is the absorption rate constant; CL indicates the oral clearance; V_D is the volume of distribution of the central compartment; K₂₃ and K₃₂ are the two transfer rate constants from plasma to CSF (K₂₃) and from CSF to plasma (K₃₂). V_p, the volume of distribution in the CSF, was fixed to 140 ml according to the literature (23 , 24) because this parameter could not be identified simultaneously with K₂₃ and K₃₂. C_plasma and C_CSF are the TMZ concentrations in plasma and CSF.

A bioavailability of 1, assumed in absence of i.v. drug administration, was in good accordance with its known high bioavailability of 97% (13) . A proportional error distribution was used for the description of both the inter- and intra-individual variability of the pharmacokinetic parameters. The influence of each of the recorded population factors (covariates) on the pharmacokinetic parameters was tested sequentially. They included the demographic variables age, gender, body weight, height, BSA (according to the Dubois and Dubois formula; Ref. 25 ); a renal function surrogate (serum creatinine); the common comedications (anticonvulsants, antiemetics, antacids, cytoprotective agent, and corticosteroids); and concomitant radiotherapy to TMZ administration. Only those variables considered as potential covariates for developing the population pharmacokinetic model were tested. At the end of the analysis, all covariates that showed an influence on the parameters were evaluated again by comparison of the full model (with all factors included) with a model from which each of the factors was deleted sequentially.

The model was fitted to the data by using the first order method with the subroutine ADVAN5. NONMEM performs linearized maximum likelihood estimation by use of an objective function of minus twice the logarithm of the likelihood of the model. To determine the statistical significance between two models, we used the log-likelihood ratio test obtained by computing the difference in the minimum value of the objective function (the difference in the minimum value of the NONMEM objective function [−2ΔLL] for nested models is approximately χ² distributed); Model selection criteria were a decrease of the objective function (OF) of 3.8 points for one additional parameter and 5.9 points for two additional parameters (P < 0.05) as well as comparison of regression diagnostic plots. Figures were generated with Prism (version 4.0; GraphPad Software Inc., San Diego, CA).

Pharmacodynamics.

Posthoc Bayesian estimates of the pharmacokinetic parameters were obtained for all patients and used to calculate the area under the curve concentration-time curve (AUC) in plasma (AUC_plasma) and CSF (AUC_CSF) according to the following relationships: The AUC_plasma and AUC_CSF were first calculated with cumulative dose of each patient (total TMZ dose received during pilot or recurrent study), to evaluate the relationship between systemic or cerebral drug exposure and safety and efficacy outcomes (26) , i.e. hematological toxicity, survival, and progression-free survival (PFS; calculated from the first administration of TMZ up to the date of disease progression).

Hematological toxicity, commonly defined by the percentage of decrease in platelet and absolute neutrophil count (ANC) from baseline to nadir (27 , 28) , was observed during the first two cycles of the adjuvant or recurrent treatments (intermittent schedule). Percent decrease was calculated as follows, using neutrophil as example: and the relationship with AUC_plasma was assessed by logistic regression.

The associations between both AUC_plasma and AUC_CSF and the two efficacy outcomes, survival and PFS observed at the time of this analysis, were assessed by the Spearman rank correlation test and by logistic regression. For this statistical analysis, a model was fitted to the clinical data, initially expressed in months, which was transformed into binary response, as follows: (a) 0 = alive; 1 = dead, in terms of survival after 9, 12, and 24 months and (b) 0 = progression-free; and 1 = disease progression for PFS after 6, 9, and 12 months.

The results were considered statistically significant at P < 0.05, whereas P < 0.1 was regarded to be indicative of possible trends. All statistical tests were performed with the Statistix program (version 7.0, 2000, Analytical software; Statistix, Tallahassee, FL).

Demographics.

Data from 35 patients (23 from the pilot study; 12 from the recurrent study) with a total of 227 plasma and 47 CSF samples were collected for the population pharmacokinetics analysis. Patient demographics and baseline disease characteristics are listed in Table 1⇓ , and the different comedications are summarized in Table 2⇓ .

TMZ Concentrations in Plasma and CSF.

Because TMZ has a linear pharmacokinetics over the studied range of doses (8 , 16) , the concentrations obtained with the low-dose continuous schedule (75 mg/m²/day) during concomitant radiochemotherapy were normalized to those obtained with the 200 mg/m²/day dose (proportional factor: 2.67; Ref. 29 ). TMZ levels were ranged from 0.10 to 13.99 μg/ml in the plasma and from 0.16 to 1.93 μg/ml in the CSF. The observed concentration-time profile of TMZ in plasma and CSF are displayed in Fig. 2⇓ . Because plasma concentrations decreased more quickly than in the CSF, the CSF/plasma ratio increased across the dosing interval (median, 30.1%; range, 2.1–65.2%). The CSF curve was essentially flat at approximately 1 μg/ml, likely attributable to slow influx and efflux rates from the CSF compartment (30) .

Population Pharmacokinetic Analysis.

A three-compartment model with first-order absorption from the gastrointestinal tract was found to describe the data appropriately. The rate of absorption was estimated with poor precision because few concentration data points were collected during the first hours after TMZ intake. An inter-patient variability was assumed on CL, assignment of a variability on both K_a and K₂₃ significantly improved the fits [decrease in objective function (ΔOF) = −36.4], but no inter-patient variability on V_D and K₃₂ could be detected. The model building steps for the covariate analysis are shown in Table 3⇓ .

Among the tested demographic covariates in the multivariate analysis, body weight, height, BSA, and gender influenced TMZ clearance to a statistically significant extent (ΔOF > −5.5) and V_D is influenced to a small but significant extent by BSA only (ΔOF > −6.7).

Because body weight and height influenced TMZ pharmacokinetics, we retained BSA, which reflects both these values, as a covariate on CL and V_D in the model. All covariates (i.e., BSA on V_D and CL, and gender on CL) remained statistically significant in the multivariate analysis.

Considering that corticosteroids could partially restore the integrity of the blood-brain barrier, thereby limiting drug delivery to the tumor, and on the other hand also reduce intracranial pressure by decreasing peritumoral vasogenic edema resulting in a increased drug delivery (6 , 31, 32, 33, 34) , a relationship between corticotherapy and the two transfer rate constants, K₂₃ and K₃₂, were examined. No significant influence could be observed (ΔOF = −0.1).

No other demographic covariates (age, creatinine clearance) showed any statistical influence on TMZ disposition. Coadministration of drugs, such as anticonvulsants, antiemetics, antacids, cytoprotective agents, or again corticosteroids, did not influence any pharmacokinetic parameters to a statistically relevant extent. However, a trend toward a 15% increase of the rate constant of CSF entry, K₂₃, was observed in case of concomitant radiotherapy to TMZ (ΔOF = −2.6).

The final population estimate of oral CL was 10.0 liter/h and increased to 11.9 liter/h in male patients and oral V_D was 30.3 liters. These two parameters increased, respectively, to 14.2 liter/h and 50.2 liters on doubling BSA. K_a was 5.8 h⁻¹, K₂₃ was 7.2 × 10⁻⁴ h⁻¹, and K₃₂ was 0.76 h⁻¹. The derived elimination half-life was 2.1 h, whereas the absorption half-life was very rapid (7 min). The inter-individual variability (CV%) in CL (4.7%) and K₂₃ (16.6%) were relatively small compared with the high inter-individual variability in K_a (111%). A residual intra-individual variability of 21.4% was observed. The final population parameter estimates are presented in Table 4⇓ .

The comparison of individual and population-predicted (“typical subject”) values, obtained with the three-compartment model, versus observed concentrations in plasma and CSF are provided on Fig. 3⇓ . The individual and population predictions were symmetrically distributed around the line of identity, suggesting adequate model predictions, without any troublesome pattern in the residuals, as seen on Fig. 4⇓ .

AUC_plasma is generally considered as an indicator of systemic drug exposure whereas drug penetration into the central nervous system is reflected by AUC in the CSF. Thus, the AUC_plasma and AUC_CSF (mg/liter/h) were derived for each individual based on their final posthoc parameter estimates, yielding the respective mean values and AUC_CSF/AUC_plasma ratio shown in Table 5⇓ . For both types of schedules (continuous or intermittent), the AUC_CSF represented ∼20% of the AUC in plasma. The mean AUC_plasma after a daily dose of 75 or 200 mg/m²/day was 12.1 ± 1.1 and 30.1 ± 6.1 mg/liter/h, respectively. In the CSF, the corresponding values were 2.5 ± 0.3 and 6.1 ± 1.2 mg/liter/h.

Pharmacodynamic Relationships.

The relationship between population-based AUC_plasma and AUC_CSF of TMZ and efficacy outcomes, such as survival and PFS, was explored among the homogeneous pilot study population. The statistical evaluations performed with the Spearman rank correlations test revealed that both survival and PFS were significantly associated with either the cumulative dose (P = 0.0005 and P = 0.0009, respectively), the AUC_plasma (P = 0.0056 and P = 0.0065), or the AUC_CSF (P = 0.0005 and P = 0.0003). However, all predictors were highly inter-correlated (r > 0.86) so neither AUC_plasma nor AUC_CSF improved the prediction based on cumulative dose alone.

The statistical analysis was then repeated with the AUC_plasma and AUC_CSF calculated with the daily dose (i.e., TMZ 75 or 200 mg/m²/day) and the dose per cycle (continuous schedule, 75 mg/m²/day x 42–49day; intermittent schedule, 200 mg/m²/day × 5 days). It failed to demonstrate any significant correlation between both AUC_plasma or AUC_CSF and survival or PFS, with P > 0.1 in all cases.

Finally, no significant correlations could be observed by logistic regression between AUC_plasma or AUC_CSF and both survival and PFS censored at 6, 9, 12, or 24 months (P > 0.19).

Myelosuppression, in particular delayed thrombocytopenia, is the primary dose-limiting toxicity of TMZ. Hematological toxicity observed in this study population (2–3% grade III/IV neutropenia, 5–6% grade III/IV thrombocytopenia) was in agreement with data reported previously (9, 10, 11, 12, 13) . The mean decrement in absolute neutrophil count between baseline to nadir was 49% (range, 0–93%) and 47% (range, 4–97%) for platelets. It was then examined whether AUC_plasma was a predictor of hematological toxicity. No significant correlation between systemic TMZ exposure during the first two cycles of adjuvant or recurrent treatments (intermittent schedule) and the percentage of decrease in platelet (P = 0.812) nor absolute neutrophil count (P = 0.599) was observed.