Lectin-like oxidized LDL receptor-1 (LOX-1) is an endothelial receptor for oxidized LDL (oxLDL) and plays multiple roles in the development of cardiovascular diseases. We screened more than 400 foodstuff extracts for identifying materials that inhibit oxLDL binding to LOX-1. Results showed that 52 extracts inhibited LOX-1 by more than 70% in cell-free assays. Subsequent cell-based assays revealed that a variety of foodstuffs known to be rich in procyanidins such as grape seed extracts and apple polyphenols, potently inhibited oxLDL uptake in Chinese hamster ovary (CHO) cells expressing LOX-1. Indeed, purified procyanidins significantly inhibited oxLDL binding to LOX-1 while other ingredients of apple polyphenols did not. Moreover, chronic administration of oligomeric procyanidins suppressed lipid accumulation in vascular wall in hypertensive rats fed with high fat diet. These results suggest that procyanidins are LOX-1 inhibitors and LOX-1 inhibition might be a possible underlying mechanism of the well-known vascular protective effects of red wine, the French Paradox.
The purpose of this study was to perform a kinetic analysis of the tissue distribution of doxorubicin (DXR) and liposomes separately after intravenous administration of DXR entrapped in liposomes in rats. Liposomes were double labeled with 14C-DXR (L-DXR) and 3H-inulin (L-INU). Blood and tissues were sampled at specified times until 120 min. Blood clearance of L-DXR was similar to that of L-INU. Distribution of both L-DXR and L-INU into the liver was parallel and extensive, while in the heart, the pattern of distribution differed between L-DXR and L-INU after peak concentration. Time courses of tissue concentration were explained well by dividing tissue into a shallow compartment with efflux and a deep compartment without efflux. In the liver, pharmacokinetic parameters of L-DXR and L-INU were similar, and the two kinetically different compartments may correspond to different uptake processes in hepatic endocytosis. In the heart, the shallow compartment was considered to correspond to the cardiac vascular space, and the intercompartmental rate constant (k3) for L-DXR was much larger than that for L-INU. The estimated half-life for this process was 20 min. The half-life for the degradation of liposomes in blood circulation was also estimated at 20 min from data on the urinary excretion of released 3H-inulin. These results suggest that the release of DXR from liposomes may be the rate-limiting process in the tissue distribution of DXR to the heart.
The objective of this study is to perform kinetic modelling of the tissue distribution of doxorubicin encapsulated into liposomes (L-DXR), especially to the heart and liver. The release process of doxorubicin (DXR) from liposomes in blood was quantified by a release clearance. This parameter defines a release rate of DXR based on the concentration of L-DXR in blood and was estimated from kinetic modelling of DXR distribution to the heart after L-DXR administration. The distribution of free DXR to the heart was modelled separately. The experimental data for this modelling were reported previously (Harashima et al., Biopharm. Drug. Disposit., 13, 155-170 (1992)). This analysis provided a free DXR concentration profile as well as a release clearance of DXR after L-DXR administration. There was a remarkable difference in the free DXR concentration in blood between free and liposomal administration. The area under the DXR curve in the heart was reduced by approximately one third from that for the first two hours after DXR administration by liposomal encapsulation, which could be the reason for reduced cardiac toxicity. In our previous report, the distribution of L-DXR to the liver was shown to be explained by a sequentially linked two-compartment model with efflux process. The validity of this efflux model was examined in this study by a repeated dose study. The apparent uptake clearance decreased with time and showed a second peak after the repeated dose, which justified the efflux model. These kinetic analyses give quantitative understanding of the effect of liposomal encapsulation on the tissue distribution of DXR.
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