Is Monitoring of the Intracellular Active Metabolite Levels of Nucleobase and Nucleoside Analogs Ready for Precision Medicine Applications?

Nucleobase and nucleoside analogs (NAs) play important roles in cancer therapy. Although there are obvious individual differences in NA treatments, most NAs lack direct relationships between their plasma concentration and efficacy or adverse effects. Accumulating evidence suggests that the intracellular active metabolite levels of NAs predict patient outcomes. This article reviewed the relationships between NA intracellular active metabolite levels and their efficacy or adverse effects. The factors affecting the formation of intracellular active metabolites and combination regimens that elevate intracellular active metabolite levels were also reviewed. Given the mechanism of NA cytotoxicity, NA intracellular active metabolite levels may be predictive of clinical outcomes. Many clinical studies support this hypothesis. Therefore, the monitoring of intracellular active metabolite levels is beneficial for individualized NA treatment. However, to perform clinical monitoring in practice, well-designed studies are needed to explore the optimal threshold or range and the appropriate regimen adjustment strategies based on these parameters.

Development and application of a rapid and sensitive liquid chromatography-mass spectrometry method for simultaneous analysis of cytarabine, cytarabine monophosphate, cytarabine diphosphate and cytarabine triphosphate in the cytosol and nucleus.

In this study, a sensitive and rapid ultra-high-performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS) method was developed for the simultaneous analysis of cytarabine (ara-C), cytarabine monophosphate (ara-CMP), cytarabine diphosphate (ara-CDP) and cytarabine triphosphate (ara-CTP) in the cytosol and nucleus. The separation of analytes and endogenous interferents was achieved in 8 min on a hypercarb column (2.1 mm × 100 mm, 3 µm) by using a gradient elution with 95% acetonitrile and aqueous 5 mM hexylamine with 0.4% (v/v) diethylamine adjusted to pH 10. The analytes were detected with both negative and positive electrospray ionization in multiple reaction monitoring (MRM) mode. The calibration curve demonstrated good linearity ranging from 5 to 750 nM for ara-C, 50-7500 nM for ara-CMP, 20-3000 nM for ara-CDP and 1-150 nM for ara-CTP in the cytosol. In the nucleus, good linearity was achieved over a concentration range of 1-100 nM for ara-C, 5-500 nM for ara-CMP, 2.5-250 nM for ara-CDP and 0.5-50 nM for ara-CTP. Intra- and interbatch accuracies and precisions met the standards of validation. The matrix effect, recovery and stability were also within acceptable ranges. After incubation with 10 µM ara-C for 3 h, the levels of ara-C, ara-CMP, ara-CDP and ara-CTP in the cytosol and nucleus of HL-60 cells and HL-60/ara-C cells were determined. Most of the metabolites were found within the quantitation range. The results showed that the nuclear ara-CTP level was significantly different than the intracellular ara-CTP level between HL-60 and HL-60/ara-C cells.

Effect of Green Tea and (-)-Epigallocatechin Gallate on the Pharmacokinetics of Rosuvastatin.

BACKGROUND: Green tea can inhibit OATPs, so it may interact with the substrate of OATPs, such as rosuvastatin. OBJECTIVE: This study aimed to investigate the effects of green tea on the pharmacokinetics of rosuvastatin and its mechanism. METHODS: Male Sprague-Dawley rats received different doses of green tea extract (GTE) and (-)- epigallocatechin-3- gallate (EGCG). Caco-2 cells and OATP1B1-HEK293T cells were used in drug uptake and transport assay. The matrix concentrations of rosuvastatin and catechins were determined by ultra-performance liquid chromatographytandem mass spectrometry (UPLC-MS/MS). RESULTS: GTE and EGCG were both found to increase the area under the plasma concentration-time curve (AUC0-∞) of rosuvastatin ((p<0.050). In the Caco-2 cell model, the uptake and transport of rosuvastatin in the GTE groups were 1.94-fold (p<0.001) and 2.11-fold (p<0.050) higher, respectively, than those of the control group. However, in the EGCG group, the uptake and transport of rosuvastatin were decreased by 22.62% and 44.19%, respectively (p<0.050). In the OATP1B1- HEK293T cell model, the OATP1B1-mediated rosuvastatin uptake was decreased by GTE to 35.02% of that in the control (p<0.050) and was decreased by EGCG to 45.61% of that in the control (p<0.050). CONCLUSION: GTE increased the systemic rosuvastatin exposure in rats. The mechanism may include an increase in rosuvastatin absorption and a decrease in liver distribution by inhibiting OATP1B1. EGCG may be the main ingredient of green tea that affects the pharmacokinetic parameters of rosuvastatin. Our results showed the importance of conducting green tea-rosuvastatin study.