Deconvolution analysis for absorption and metabolism of aspirin in microcapsules

Mechanistic and empirical modeling of skin permeation of drugs

The skin forms a barrier to the external environment, maintaining body fluids within our system and excluding harmful substances, while the skin is a site of administration of drugs for topical and systemic chemotherapy. It is an important issue to predict the rate at which drugs or other xenobiotics penetrate the skin. In this article, we review modeling approaches for predicting skin permeation of compounds, including both mechanistic and empirical approaches. Mechanistic approaches can give us much information on understanding of skin permeation of the compounds, such as structure-permeability relationship, contribution of each barrier step, mechanism of penetration enhancers, and in vivo-in vitro relationship. On the other hand, empirical modeling can overcome any inaccuracies of mechanistic models caused by the existence of uncertainties and, therefore, give us better predictions from the practical point of view. Artificial neural networks are being available for empirical modeling of complex skin transport phenomenon.

Gliadin nanoparticles as carriers for the oral administration of lipophilic drugs. Relationships between bioadhesion and pharmacokinetics

PURPOSE

The aim of this work was to evaluate the bioadhesive properties of non-hardened gliadin nanoparticles (NPs) and cross-linked gliadin nanoparticles (CL-NP) in the carbazole pharmacokinetic parameters obtained after the oral administration of these carriers.

METHODS

A deconvolution model was used to estimate the carbazole absorption when loaded in the different gliadin nanoparticles. In addition, the elimination rates of both adhered and non-adhered nanoparticulate fractions within the stomach were estimated.

RESULTS

Nanoparticles dramatically increased the carbazole oral bioavailability up to 49% and provided sustained release properties related to a decrease of the carbazole plasma elimination rate. The carbazole release rates from nanoparticles (NP and CL-NP), calculated by deconvolution, were found to be of the same order as the elimination rates of the adhered fractions of nanoparticles in the stomach mucosa. In addition, good correlation was found between the carbazole plasmatic levels, during the period of time in which the absorption process prevails, and the amount of adhered carriers to the stomach mucosa.

CONCLUSION

Gliadin nanoparticles significantly increased the carbazole bioavailability, providing sustained plasma concentrations of this lipophilic molecule. These pharmacokinetic modifications were directly related to the bioadhesive capacity of these carriers with the stomach mucosa.