Modeling of diffusion and concurrent metabolism in cutaneous tissue.

Clearance by cutaneous metabolism can shield the body from penetration of environmental and therapeutic xenobiotics. Here we report on a physical model to relate Fickian diffusion and concurrent Michaelis-Menten metabolism of drugs in the viable epidermis of human skin. For this purpose, we numerically generated substrate concentration profiles within the metabolizing tissue and the resulting donor-to-receiver substrate fluxes through the tissue for various mass transport and metabolism parameters.

Validation of excised bovine nasal mucosa as in vitro model to study drug transport and metabolic pathways in nasal epithelium.

The present work aims at the validation of excised bovine nasal mucosa as an in vitro model to address transport and metabolism pathways relative to the nasal mucosal uptake of therapeutic peptides. Preservation of the viability of the excised tissue in the course of in vitro studies of up to 3 h was demonstrated by (i) positive viability staining, (ii) constant transepithelial electrical resistance (42 +/- 12 Omega cm(2)), (iii) constant rates of metabolic turnover, and (iv) linear permeation profiles of therapeutic peptides and (3)H-mannitol. Using 1-leucine-4-methoxy-2-naphthylamide as a model substrate, we observed no difference between bovine and human nasal aminopeptidase activity.

Mechanistic and quantitative prediction of aminopeptidase activity in stripped human skin based on the HaCaT cell sheet model.

HaCaT cell culture sheets were recently demonstrated to be a useful tool to study epidermal metabolism. Here we report on a mechanistic and quantitative correlation between the kinetics of aminopeptidase-based cleavage of L-Ala-4-methoxy-2-naphthylamide (Ala-MNA) in HaCaT sheets versus stripped human skin. Fresh human skin (breast or abdominal) was obtained from cosmetic surgery, tape-stripped, and dermatomed.

Localization of aminopeptidase activity in freshly excised human skin: direct visualization by confocal laser scanning microscopy.

The aim of this study was to localize and visualize aminopeptidase activity within freshly excised, dermatomed human skin without perturbation of its histologic integrity. The use of confocal laser scanning microscopy (CLSM) is introduced as a novel approach by which to monitor the degradation of suitable substrates in the skin. The fluorescence of the metabolites originating from the cleavage of the aminopeptidase probe bis-Leu-rhodamine 110 (Leu2-R11O) was interpreted to reflect the local aminopeptidase activity in the tissue.