Development and validation of an UHPLC-MS/MS method for simultaneous quantification of ibrutinib and its dihydrodiol-metabolite in human cerebrospinal fluid.

Ibrutinib is an orally administered first-in-class irreversible Bruton's tyrosine kinase (BTK) covalent inhibitor for the treatment of patients with B-cell malignancies. Several isolated clinical observations reported its efficacy in central nervous system dissemination. Herein, we described the development and validation of an ultra-performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS) procedure for the quantification of ibrutinib and its active metabolite PCI-45227 in cerebrospinal fluid (CSF). This is the first complete validated method for quantification of ibrutinib and PCI-45227 in CSF. The compounds were eluted on a Waters BEH C18 column (50.0 × 2.1 mm; 1.7 µm) using a gradient elution with a mobile phase composed of ammonium formate buffer 5 mM pH 3.2 and acetonitrile +0.1% formic acid with a flow rate of 400 µL·min-1. Two deuterated internal standards were used to obtain the most accurate quantification. The CSF samples were prepared by a simple and rapid dilution. The method was validated by testing the selectivity, response function, intra-day and inter-day precisions, trueness, limits of detection (LOD) and lower limits of quantification (LLOQ). The validation results proved that the methods were suitable to quantify ibrutinib and PCI-45227 in real biological CSF samples from 0.50 (ibrutinib) or 1.00 (PCI-45227) to 30.00 ng·mL-1. Furthermore, the developed method was adapted to allow the quantification of both compounds in plasma and the results were compared to those reported in literature. The plasmatic samples were treated by protein precipitation and the method was validated to quantify ibrutinib and PCI-45227 in real biological plasmatic samples from 5.00 to 491 ng·mL-1. Lastly, for both matrices, accuracy profiles were plotted from the trueness and precision results using a 20% α-risk (ß = 80%) and the tolerance intervals were comprised within the acceptance limits fixed at ±25% for the LLOQ and ±15% for the other concentrations. Finally, these methods were successfully applied to quantify ibrutinib and PCI-45227 in real human CSF and plasma samples.

Avoiding glucocorticoid administration in a neurooncological case.

Restricting glucocorticoid (GC) use in the treatment of patients with a solid tumor may help improving outcome. Here, we report administration of celecoxib rather than dexamethasone to prevent brain edema in a patient with a cerebellar glioblastoma multiforme WHO grade IV (GBM) upon the patient's request, as well as determining cerebrospinal fluid (CSF) and serum concentrations. CSF concentration (0.04 microM) was 54 times below serum concentration (2.18 microM), or 2500 times below levels inhibiting GBM cells in vitro (100 microM), revealing a blood CSF barrier for celecoxib. The patient did not require dexamethasone for the entire treatment. GC administration hence was avoided successfully in this case. The role of COX-2 inhibitors in treatment of GBM is detailed, leading to the conclusion of a pressing need for a clinical evaluation of non-steroidal COX-2 inhibitors with the ability to penetrate into brain tumors.

Pharmacokinetics, cerebrospinal fluid penetration, and metabolism of piroxantrone in the rhesus monkey.

Piroxantrone is an anthrapyrazole derivative with broad anti-tumor activity in vitro and less cardiac toxicity than the anthracyclines. The metabolic pathways and central nervous system penetration of piroxantrone have not been determined. In this study we examined the pharmacokinetic behavior of piroxantrone in plasma and cerebrospinal fluid in a non-human primate model. In addition, a urinary metabolite of piroxantrone was isolated and its cytotoxicity evaluated in vitro. The disappearance of piroxantrone from plasma after an intravenous dose of 150 mg/m2 given over 60 minutes was biexponential with mean t1/2 alpha of 1.0 minutes and a mean t1/2 beta of 180 minutes. The mean area under the curve was 220 microM.min and the clearance was 1420 ml/min/m2. Piroxantrone was not detectable in the cerebrospinal fluid. Piroxantrone and three other compounds not present in pre-treatment samples were detected in urine. The major urinary metabolite was isolated. Its cytotoxicity against MOLT-4 cells in vitro was at least one log less than that of piroxantrone. In addition, one of the other compounds detected in urine was determined to be a glucuronide conjugation product of the major metabolite. The results of this study may be useful in the interpretation of the activity and toxicity of piroxantrone in clinical trials.