Optimizing the Physicochemical Properties of Raf/MEK Inhibitors by Nitrogen Scanning.

Substituting a carbon atom with a nitrogen atom (nitrogen substitution) on an aromatic ring in our leads 11a and 13g by applying nitrogen scanning afforded a set of compounds that improved not only the solubility but also the metabolic stability. The impact after nitrogen substitution on interactions between a derivative and its on- and off-target proteins (Raf/MEK, CYPs, and hERG channel) was also detected, most of them contributing to weaker interactions. After identifying the positions that kept inhibitory activity on HCT116 cell growth and Raf/MEK, compound 1 (CH5126766/RO5126766) was selected as a clinical compound. A phase I clinical trial is ongoing for solid cancers.

Design and synthesis of an androgen receptor pure antagonist (CH5137291) for the treatment of castration-resistant prostate cancer.

A series of 5,5-dimethylthiohydantoin derivatives were synthesized and evaluated for androgen receptor pure antagonistic activities for the treatment of castration-resistant prostate cancer. Since CH4933468, which we reported previously, had a problem with agonist metabolites, novel thiohydantoin derivatives were identified by applying two strategies. One was the replacement of the alkylsulfonamide moiety by a phenylsulfonamide to avoid the production of agonist metabolites. The other was the replacement of the phenyl ring with a pyridine ring to improve in vivo potency and reduce hERG affinity. Pharmacological assays indicated that CH5137291 (17b) was a potent AR pure antagonist which did not produce the agonist metabolite. Moreover, CH5137291 completely inhibited in vivo tumor growth of LNCaP-BC2, a castration-resistant prostate cancer model.

Quantitative analysis of the effect of supersaturation on in vivo drug absorption.

The purpose of this study is to clarify the effects of intestinal drug supersaturation on solubility-limited nonlinear absorption. Oral absorption of a novel farnesyltransferase inhibitor (FTI-2600) from its crystalline free base and its HCl salt was determined in dogs. To clarify the contribution of supersaturation on improving drug absorption, in vivo intraluminal concentration of FTI-2600 after oral administration was estimated from the pharmacokinetics data using a physiologically based model. Dissolution and precipitation characteristics of FTI-2600 in a biorelevant media were investigated in vitro using a miniscale dissolution test and powder X-ray diffraction analysis. In the in vitro study, the HCl salt immediately dissolved but precipitated rapidly. The metastable amorphous free base precipitant, which did not convert into the stable crystalline free base in the simulated intestinal fluids for several hours, generated a 5-fold increase in dissolved concentration compared to the equilibrium solubility of the crystalline free base. By computer simulation, the intraluminal drug concentration after administration of the free base was estimated to reach the saturated solubility, indicating solubility-limited absorption. On the other hand, administration of the HCl salt resulted in an increased intraluminal concentration and the plasma concentration was 400% greater than that after administration of the free base. This in vivo/in vitro correlation of the increased drug concentrations in the small intestine provide clear evidence that not only the increase in the dissolution rate, but also the supersaturation phenomenon, improved the solubility-limited absorption of FTI-2600. These results indicate that formulation technologies that can induce supersaturation may be of great assistance to the successful development of poorly water-soluble drugs.

Rate-limiting steps of oral absorption for poorly water-soluble drugs in dogs; prediction from a miniscale dissolution test and a physiologically-based computer simulation.

PURPOSE: Nonlinear oral absorption due to poor solubility often impedes drug development. The purpose of this study was to elucidate the rate-limiting process in oral absorption of Biopharmaceutical Classification System (BCS) class II (low solubility-high permeability) drugs in order to predict nonlinear absorption of dose caused by solubility-limited absorption. METHODS: Oral absorption of danazol, griseofulvin, and aprepitant was predicted from a miniscale dissolution test and a physiologically-based model. The effect of particle size reduction and dose increase on absorption was investigated in vitro and in vivo to clarify the rate-limiting steps of dissolution-rate-limited and solubility-limited absorption. RESULTS: The rate-limiting steps of oral absorption were simulated and increase in the dissolution rate and administration dose showed a shift from dissolution rate-limited to solubility-limited absorption. In the study in dogs, particle size reduction improved the oral absorption of large particle drugs but had little effect on small particle drugs. Dose nonlinearity was observed with small particles at a high dose. Our model quantitatively predicted results observed in vivo, including but not exclusively, dissolution-rate-limited and solubility-limited absorption. CONCLUSION: The present study provides a powerful tool to predict dose nonlinearity and will aid in the success of BCS class II drug development.

Effect of coupling of albumin onto surface of PEG liposome on its in vivo disposition.

To evaluate the effect of coupling of albumin onto the surface of poly(ethylene glycol)-modified liposome (PEG liposome) on the in vivo disposition of liposome, pharmacokinetics and tissue distribution were examined after intravenous administration of rat serum albumin-modified PEG (RSA/PEG) liposome into rats. RSA/PEG liposome showed longer blood-circulating property than PEG liposome and the hepatic clearance for RSA/PEG liposome was significantly smaller than that for PEG liposome. Single-pass liver perfusion experiments also showed that the hepatic disposition of RSA/PEG liposome was much less than that of PEG liposome and that pre-treatment of liver with trypsin did not significantly reduce the hepatic disposition of RSA/PEG liposome, suggesting that RSA/PEG liposome could avoid the hepatic uptake via the receptor-mediated endocytosis. To unravel the mechanism behind the less affinity of RSA/PEG liposome to the liver, serum proteins associated on their surface were quantitatively and qualitatively assessed. The results showed that the coupling of albumin onto PEG liposome significantly reduced the total amount of serum proteins associated onto the surface, and SDS-PAGE revealed that the decrease in the association with liposomes for several serum proteins, which might have opsonic activity. From these findings, introduction of serum albumin onto PEG liposome could be useful to develop a new nanoparticulate formulation with a better pharmacokinetic property.

Pre-coating with serum albumin reduces receptor-mediated hepatic disposition of polystyrene nanosphere: implications for rational design of nanoparticles.

We evaluated the in vivo disposition characteristics of polystyrene nanospheres (NS) with the particle size of 50 nm (NS-50) pre-coated with human serum albumin (HSA) after intravenous administration in rats. HSA-coated NS-50 showed much longer blood-circulating property and the hepatic uptake clearance for HSA-coated NS-50 was about 1/5 of that for NS-50. In parallel with the results obtained in the in vivo study, liver perfusion experiments also showed that the hepatic disposition of HSA-coated NS-50 was much less than that of NS-50 in the presence of serum in the perfusate. To unravel the mechanism behind the less affinity of HSA-coated NS-50 to the liver, serum proteins associated on the surface was quantitatively and qualitatively assessed. The results indicated that pre-coated HSA impaired subsequent association of serum proteins onto the surface, suggesting that the association of a given serum protein with opsonic activity might be suppressed by HSA pre-coating. From these findings, pre-coating of nanoparticles with serum albumin could be useful to prevent their rapid clearance by mononuclear phagocyte system in vivo.

Hepatic uptake of negatively charged particles in rats: possible involvement of serum proteins in recognition by scavenger receptor.

The mechanisms involved in the hepatic uptake of negatively charged carboxylated-polystyrene nanospheres with a size of 50 nm (CNS-50) were examined in rats. The liver perfusion experiments revealed that hepatic disposition of CNS-50 in the absence of serum could be partially ascribed to the direct recognition of the surface negative charge by scavenger receptors. On the other hand, the apparent negative charge of CNS-50 surface dramatically reduced in the presence of serum, because the adsorption of serum protein on their surface results in masking their intrinsic negative charge. However, hepatic disposition of CNS-50 in the presence of serum was significantly inhibited by poly inosinic acid (poly I), a typical inhibitor for scavenger receptors, and the extent of inhibition by poly I was even larger than that in the absence of serum, suggesting that the serum proteins associated on CNS-50 surface could be recognized by scavenger receptors. These results indicate that not only the intrinsic negative charge but also serum proteins associated on the surface play an important role in hepatic uptake of negatively charged particles via scavenger receptors.

Important role of serum proteins associated on the surface of particles in their hepatic disposition.

To elucidate the important factors for the difference in the hepatic disposition between polystyrene nanospheres with a size of 50 nm (NS-50) and lecithin-coated NS-50 (LNS-50), the liver perfusion studies and the in vitro uptake studies using the cultured Kupffer cells were performed. It was suggested that opsonin-mediated phagocytosis is not significantly involved in the hepatic disposition of LNS-50 in the presence of serum, whereas its involvement in the hepatic uptake of NS-50 was clearly demonstrated. Western blot analysis showed that IgG, complement C3, and fibronectin, well-known opsonins in the serum, adsorbed on the surface of NS-50 in larger amount than on the surface of LNS-50. On the other hand, serum albumin, which was suggested to function as a dysopsonin for the hepatic disposition of NS-50, was associated with both spheres almost to the same extent. These findings suggest that the hepatic disposition of LNS-50 at lower level should be ascribed to the less amount of serum opsonins associated on the surface and that the serum proteins associated with these spheres should be important as a determinant for their hepatic disposition.