Nitrosylated human serum albumin (SNO-HSA) induces apoptosis in tumor cells.

Recently, nitric oxide has been investigated as a potential anti-cancer therapy because of its cytotoxic activity. Previously, we found that S-nitrosylated human serum albumin (SNO-HSA) induced apoptosis in C26 cells, demonstrating for the first time that SNO-HSA has potential as an anti-cancer drug. In the present study, the anti-tumor activity of SNO-HSA in another tumor type of cancer cell was investigated using murine tumor LY-80 cells. Mitochondrial depolarization, activation of caspase-3 and DNA fragmentation were induced in LY-80 cells by SNO-HSA treatment in a dose-dependent manner. Inhibition of caspase activity resulted in complete inhibition of DNA fragmentation induced by SNO-HSA. The cytotoxic effects of SNO-HSA on LY-80 were concentration-dependent. Tumor growth in LY-80-tumor-bearing rats was significantly inhibited by administration of SNO-HSA compared with saline- and HSA-treatment. These results suggest that SNO-HSA has potential as a chemopreventive and/or chemotherapeutic agent because it induces apoptosis in tumor cells.

Design and evaluation of S-nitrosylated human serum albumin as a novel anticancer drug.

In recent studies, the cytotoxic activity of NO has been investigated for its potential use in anticancer therapies. Nitrosated human serum albumin (NO-HSA) may act as a reservoir of NO in vivo. However, there are no published reports regarding the effects of NO-HSA on cancer. Therefore, the present study investigated the antitumor activity of NO-HSA. NO-HSA was prepared by incubating HSA, which had been sulfhydrylated using iminothiolane, with isopentyl nitrite (6.64 mol NO/mol HSA). Antitumor activity was examined in vitro using murine colon 26 carcinoma (C26) cells and in vivo using C26 tumor-bearing mice. Exposure to NO-HSA increased the production of reactive oxygen species in C26 cells. Flow cytometric analysis using rhodamine 123 showed that NO-HSA caused mitochondrial depolarization. Activation of caspase-3 and DNA fragmentation were observed in C26 cells after incubation with 100 muM NO-HSA for 24 h, and NO-HSA inhibited the growth of C26 cells in a concentration-dependent manner. The growth of C26 tumors in mice was significantly inhibited by administration of NO-HSA compared with saline and HSA treatment. Immunohistochemical analysis of tumor tissues demonstrated an increase in terminal deoxynucleotidyl transferase dUTP nickend labeling-positive cells in NO-HSA-treated mice, suggesting that inhibition of tumor growth by NO-HSA was mediated through induction of apoptosis. Biochemical parameters (such as serum creatinine, blood urea nitrogen, aspartate aminotransferase, and alanine aminotransferase) showed no significant differences among the three treatment groups, indicating that NO-HSA did not cause hepatic or renal damage. These results suggest that NO-HSA has the potential for chemopreventive and/or chemotherapeutic activity with few side effects.

Albumin-conjugated PEG liposome enhances tumor distribution of liposomal doxorubicin in rats.

To evaluate the effect of coupling of recombinant human serum albumin (rHSA) onto the surface of poly(ethylene glycol)-modified liposome (PEG liposome) on the in vivo disposition characteristics of liposomal doxorubicin (DXR), the pharmacokinetics and tissue distribution of DXR were evaluated after intravenous administration of rHSA-modified PEG (rHSA/PEG) liposomal DXR into tumor-bearing rats. rHSA/PEG liposome prepared using a hetero-bifunctional cross-linker, N-succinimidyl 3-(2-pyridyldithio) propionate (SPDP), efficiently encapsulated DXR (over 95%). rHSA/PEG liposomal DXR showed longer blood-circulating property than PEG liposomal DXR and the hepatic and splenic clearances of rHSA/PEG liposomal DXR were significantly smaller than those of PEG liposomal DXR. It was also demonstrated that the disposition of DXR to the heart, one of the organs for DXR-related side-effects, was significantly smaller than free DXR. Furthermore, the tumor accumulation of rHSA/PEG liposomal DXR was significantly larger than that of PEG liposomal DXR. The "therapeutic index", a criterion for therapeutic outcome, for rHSA/PEG liposomal DXR was significantly higher than PEG liposomal DXR. These results clearly indicate that rHSA-conjugation onto the surface of PEG liposome would be a useful approach to increase the effectiveness and safety of PEG liposomal DXR.

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.

Analysis and prediction of absorption behavior of colon-targeted prodrug in rats by GI-transit-absorption model.

The gastrointestinal-transit-absorption (GITA) model is useful for the analysis and the prediction of the absorption behavior of drugs orally administered as solutions. In the present study, we tried to predict the plasma concentration-time profile of a colon-targeted prodrug, salicylazosulfanilic acid (SASA), and its parent drug, 5-aminosalicylic acid (5-ASA) which is regenerated after dosing. Prediction of plasma concentration-time profiles for SASA and 5-ASA was performed based on the GITA model using parameters describing GI-transit kinetics, the absorption in each GI segment, and the regeneration of 5-ASA in cecum. Plasma concentration-time profiles of both SASA and 5-ASA after oral administration of SASA were predicted very well by introducing a factor for the first-pass elimination of 5-ASA into the GITA model. The simulation study using the parameters obtained in the present study showed that about 94.7% of SASA reaches the cecum, where 5-ASA is regenerated very rapidly and 76.0% of 5-ASA is absorbed. Furthermore, the bioavailability of 5-ASA was estimated to be 0.330 because of the first-pass elimination through both cecum and liver. In conclusion, the absorption behaviors of a prodrug and its regenerated parent drug can be predicted very well and be clarified successfully using the GITA model.

Analysis and prediction of absorption behavior for theophylline orally administered as powders based on gastrointestinal-transit-absorption (Gita) model.

Absorption behavior of theophylline, categorized into Class I of Biopharmaceutics Classification System, orally administered as powders in rats was analyzed and predicted by Gastrointestinal-Transit-Absorption (GITA) model, which was modified to describe GI-transit kinetics and dissolution of powders orally administered. First of all, GI-transit kinetics of glass beads was examined to describe the transit kinetics of powders through GI tract in rats. The results showed that the gastric emptying of glass beads was slower than that of solution, but that there was not much difference in the transit rate constants through the small intestine and cecum between glass beads and solution. Furthermore, to introduce the dissolution process of theophylline powders into GITA model, an in-vitro dissolution test was examined for theophylline powders according to the Japanese Pharmacopoeia paddle method. The dissolution rate constants calculated based on the mean dissolution time were not so different in the range of pH from 1.2 to 6.5. Using the parameters for GI transit, dissolution and absorption obtained, the plasma concentration-time profile of theophylline after oral administration as powders to rats was predicted based on GITA model. The profile calculated was significantly correlated with the observed time course of plasma concentration for theophylline, and the parameters such as C(max) and AUC based on the predicted curve coincided with those on the observed data, showing that GITA model is useful for the prediction of the absorption behavior of drugs administered as powders. The simulation studies showed that about 80% of orally administered theophylline powders dissolved in the stomach and that the remaining powders rapidly moved to the lower jejunum and ileum, where they dissolved. Furthermore, it was suggested that theophylline is absorbed mostly in the upper small intestine, duodenum, upper jejunum and lower jejunum, after its oral administration as powders.