The effect of selected methoxy flavonoids on the in vitro efflux transport of rhodamine 123 using rat jejunum
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Dodd, Stanley Anthony
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North-West University
Abstract
Many orally administered drugs must overcome several barriers before reaching their target site. The first major obstacle to cross is the intestinal epithelium. Although lipophilic compounds may readily diffuse across the apical plasma membrane, their subsequent passage across the basolateral membrane and into blood is by no means guaranteed. Efflux proteins located at the apical membrane, which include P-glycoprotein (P-gp, MDR1) and Multidrug Resistance-associated Protein (MRP2), may
drive compounds from inside the cell back into the intestinal lumen, preventing their
absorption into the blood. Intestinal P-gp is localised to the villus tip enterocytes, i.e. the
main site of absorption for orally administered compounds and in close proximity to the lumen. P-gp is therefore ideally positioned to limit the absorption of compounds by driving efflux back into the lumen. Drugs may also be modified by intracellular phase I and phase II metabolizing enzymes. This process may not only render the drug ineffective, but it may also produce metabolites that are themselves substrates for P-gp and/or MRP2. Drugs that reach the blood are then passed to the liver, where they are subjected to further metabolism and biliary excretion, often by a similar system of ATP binding
cassette (ABC) transporters and enzymes to that present in the intestine. Thus a synergistic relationship exists between intestinal drug metabolizing enzymes and
apical efflux transporters, a partnership that proves to be a critical determinant of oral
bioavailability. Aim: The aim of this study was to investigate the effect of selected
methoxy flavonoids (3-methoxyflavone, 5-methoxyflavone, 6-methoxyflavone and 7-
methoxyflavone) on the mean ratio of Rhodamine123 (Rho 123) transport across rat intestine (jejunum) and to investigate structure activity relationships (SAR) of the
selected flavonoids with reference to inhibition of P-gp. Methods: 5-Methoxyflavone, 5-methoxyflavone, 6-methoxyflavone and 7-methoxyflavone were evaluated at a concentration of 10μM and 20μM as modulators of Rho 123 transport across rat jejunum. The Sweetana-Grass diffusion cells were used to determine the transport of Rho 123. Each modulator was studied bidirectionally with two cells measuring transport in the apical to basolateral direction (AP/BL) and two cells measuring transport in the basolateral to apical direction (BUAP). The rate of transport was expressed as the apparent permeability coefficient (Papp)and the extent of active transport was expressed by calculating the ratio of BUAP to AP/BL. Each modulators Papp ratio was then compared with that of the control. Results: 3-Methoxyflavone decreased the Papp ratio from 3.34 (control) to 1.66 (10μM) and 1.33 (20μM) and showed statistical significant differences. 7-Methoxyflavone decreased the Papp ratio to 1.94 (10μM) and 1.55 (20μM) but only showed a statistical significant difference at 10μM. 5-Methoxyflavone decreased the Papp ratio to 2.41 (10μM) and 1.71 (20μM) and 6-methoxyflavone decreased the Papp to 3.03 (10μM) and 2.49 (20μM). Both 5- and 6-methoxyflavone showed no statistical significant differences from the control. The
structure activity relationships with reference to P-gp inhibition clearly indicated that the C3 and C7 positioning of the methoxy-group on the A ring played a major role in the inhibition of Rho 123 transport. Conclusion: All the selected modulators showed inhibition of Rho 123 transport across the jejunum. This should affect the bioavailability of the substrates of P-gp and other active transporters. In summary, this study describe the inhibitory interaction of selected flavonoids with P-gp. Structure activity relationships were identified describing the inhibitory potency of the flavonoids based on methoxy groups positioning. The inhibitory potency results were 3-methoxyflavone > 7-methoxyflavone > 5-methoxyflavone> 6-methoxyflavone
Description
Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2005.