Novel second generation analogs of eribulin. Part III: Blood-brain barrier permeability and in vivo activity in a brain tumor model.

Novel second generation analogs of eribulin mesylate, a tubulin agent recently approved for the treatment of breast cancer, are reported. Our recent efforts have focused on expanding the target indications for this class of compounds to other tumor types. Herein, we describe the design, synthesis and evaluation of eribulin analogs active against brain tumor cell lines in vitro and corresponding brain tumor models in mice. Attenuation of basicity of the amino group(s) in the C32 side-chain region led to compounds with lower susceptibility to P-gp mediated drug efflux, allowing these compounds to permeate through the blood-brain barrier. In preclinical in vivo studies, these compounds showed significantly higher levels in the brain and cerebrospinal fluid as compared to eribulin. In addition, analogs within this series showed antitumor activity in an orthotopic murine model of human glioblastoma.

Novel second generation analogs of eribulin. Part II: Orally available and active against resistant tumors in vivo.

Eribulin mesylate is a newly approved treatment for locally advanced and metastatic breast cancer. We targeted oral bioavailability and efficacy against multidrug resistant (MDR) tumors for further work. The design, synthesis and evaluation of novel amine-containing analogs of eribulin mesylate are described in this part. Attenuation of basicity of the amino group(s) in the C32 side-chain region led to compounds with low susceptibility to PgP-mediated drug efflux. These compounds were active against MDR tumor cell lines in vitro and in xenograft models in vivo, in addition to being orally bioavailable.

In vitro and in vivo anticancer activities of synthetic (-)-laulimalide, a marine natural product microtubule stabilizing agent.

Laulimalide is a cytotoxic natural product isolated from marine sponges. It is structurally distinct from taxanes. However, like paclitaxel, laulimalide binds to tubulin and enhances microtubule assembly and stabilization. It exhibits potent inhibition of cellular proliferation with IC50 values in the low nM range against numerous cancer cell lines. In contrast to paclitaxel, however, laulimalide is also very potent against multidrug-resistant (MDR) cancer cell lines which overexpress P-glycoprotein (PgP). It has unique structural and biological properties, and attempts at synthesis have attracted considerable effort in recent years, resulting in more than ten published total syntheses. Despite this extensive attention, there have been no reported in vivo evaluations of laulimalide to date, probably due to the structural complexity of laulimalide and the scarcity of natural material. In our studies to explore the therapeutic potential of laulimalide, a total synthesis capable of producing gram quantities of laulimalide was designed, which enabled both in vitro and in vivo evaluation. Our in vitro results with synthetic material confirmed the previous reports that laulimalide is a mitotic blocker that can inhibit the growth of a variety of both non-MDR and MDR human cancer cell lines. However, despite demonstrating promise in cell-based and pharmacokinetic studies, laulimalide exhibited only minimal tumor growth inhibition in vivo and was accompanied by severe toxicity and mortality. The unfavorable efficacy to toxicity ratio in vivo suggests that laulimalide may have limited value for development as a new anticancer therapeutic agent.

Pharmacokinetic characterization of a natural product-inspired novel MEK1 inhibitor E6201 in preclinical species.

PURPOSE: E6201 is a natural product-inspired novel inhibitor of mitogen-activated protein kinase/extracellular signal-regulated kinase kinase-1 (MEK1) and other kinases and is currently under development as an anticancer (parenteral administration) and antipsoriasis agent (topical application). In vitro and in vivo preclinical studies were performed to characterize the pharmacokinetics of E6201. Allometric scaling was applied to predict human pharmacokinetics of E6201. METHODS: In vitro metabolism studies for CYP induction and CYP inhibition were conducted using human hepatocytes and microsomes, respectively. Metabolic stability using microsomes and protein-binding studies using pooled plasma were performed for mice, rats, dogs, and human. Pharmacokinetics of E6201 and its isomeric metabolite, ER-813010, in mice, rats, and dogs was determined following single IV administration of E6201 at three dose levels. Bioanalysis was performed using LC/MS/MS. Pharmacokinetic parameters were determined using non-compartmental analysis, and allometric scaling with a two-compartment model was used to predict E6201 pharmacokinetics in humans. RESULTS: E6201 showed high plasma protein binding (>95%), and metabolic stability half-life ranged from 36 to 89 min across species. In vitro CYP inhibition (CYP1A2, 2C9, 2C19, 2D6, 2E1, and 3A) and CYP induction (CYP1A, 3A, 2C9, and 2C19) suggested no inhibitory or induction effect on the tested human CYPs up to 10 µM of E6201. Pharmacokinetics of E6201 in mice, rats, and dogs was characterized by mean clearance ranging from 3.45 to 10.92 L/h/kg, distribution volume ranging from 0.63 to 13.09 L/kg, and elimination half-life ranging from 0.4 to 1.6 h. ER-813010 was detected in all species with metabolite to parent exposure ratio (AUC(R)) ranging from 3.1 to 33.4% and exhibited fast elimination (<3 h). The allometry predicted high clearance and large volume of distribution of E6201 in humans and was in general in good agreement with the observed first human subject pharmacokinetics. CONCLUSIONS: E6201 exhibited high clearance, high to moderate distribution, and fast elimination in preclinical species. In vitro results suggested that E6201 has low risk of drug-drug interactions due to CYP inhibition and induction in humans. In the first-in-man study, E6201 exhibited high clearance, which was well predicted by allometric scaling.