Application of fractal kinetics for carrier-mediated transport of drugs across intestinal epithelial membrane.

Abstract

Fractal kinetics was used for the analysis of the carrier-mediated transport for drugs across the intestinal epithelial cells. The transport was examined under various agitation rates using a monolayer of Caco-2 cells and rabbit ileum sheets. The passive transport of antipyrine across Caco-2 cells was increased with the increasing rate of agitation and was supposed to be caused by a change in the thickness of the unstirred water layer. On the contrary, in the case of L-lactic acid transport, which follows a carrier-mediated transport mechanism, the more the agitation rate controlling the fractal dimension was increased, the more the permeability rate across the Caco-2 cells was decreased. Fractal kinetic analysis of L-lactic acid transport indicated that the permeability was caused by a single saturable process. Similar agitation effects with L-lactic acid transport were observed in the transport of phenylalanine and cephradine in Caco-2 cells. However, the permeability rates of benzoic acid and 3-O-methyl-D-glucose across Caco-2 cells and L-lactic acid transport across the rabbit ileum tissue indicated the maximum levels at a designated agitation rate. This phenomenon was likely to be caused by the agitation effects controlling not only the fractal environment but also the unstirred water layer. Carrier-mediated transports are well defined by fractal kinetics rather than classical kinetic analysis. Fractal kinetics are one of the important areas for understanding and confirming the properties of a carrier-mediated transport process.