In vitro models to estimate drug penetration through the compromised stratum corneum barrier

Objectives: The phospholipid vesicle-based permeation assay (PVPA) is a recently established in vitro stratum corneum model to estimate the permeability of intact and healthy skin. The aim here was to further evolve this model to mimic the stratum corneum in a compromised skin barrier by reducing the barrier functions in a controlled manner. Methods: To mimic compromised skin barriers, PVPA barriers were prepared with explicitly defined reduced barrier function and compared with literature data from both human and animal skin with compromised barrier properties. Caffeine, diclofenac sodium, chloramphenicol and the hydrophilic marker calcein were tested to compare the PVPA models with established models. Results and discussions: The established PVPA models mimicking the stratum corneum in healthy skin showed good correlation with biological barriers by ranking drugs similar to those ranked by the pig ear skin model and were comparable to literature data on permeation through healthy human skin. The PVPA models provided reproducible and consistent results with a distinction between the barriers mimicking compromised and healthy skin. The trends in increasing drug permeation with an increasing degree of compromised barriers for the model drugs were similar to the literature data from other in vivo and in vitro models. Conclusions: The PVPA models have the potential to provide permeation predictions when investigating drugs or cosmeceuticals intended for various compromised skin conditions and can thus possibly reduce the time and cost of testing as well as the use of animal testing in the early development of drug candidates, drugs and cosmeceuticals.     

In vitro percutaneous absorption enhancement of granisetron by chemical penetration enhancers

Granisetron (GRN), a potent antiemetic agent, is frequently used to prevent nausea and vomiting induced by cancer cytotoxic chemotherapy and radiation therapy.

Objective: As part of our efforts to further modify the physicochemical properties of this market drug, with the ultimate goal to formulate a better dosage form for GRN, this work was carried out to improve its permeability in vitro.

Methods: The permeation behavior of GRN in isopropyl myristate (IPM) was investigated across excised rabbit abdominal skin and the enhancing activities of three novel O-acylmenthol derivatives synthesized in our laboratory as well as five well-known chemical enhancers were evaluated.

Results: It was found that the steady-state flux of granisetron free base (GRN-B) was about 26-fold higher than that of granisetron hydrochloride (GRN-H). The novel enhancer, 2-isopropyl-5-methylcyclohexyl heptanoate (M-HEP), was observed to provide the most significant enhancement for the absorption of GRN-B. When incorporated in the donor solution with the optimal enhancer M-HEP, the steady-state flux of GRN-B increased from (196.44?±?12.03) μg·cm^?2·h^?1 to (1044.95?±?71.99) μg·cm^?2·h^?1 (P?<?0.01).

Conclusion: These findings indicated that the application of chemical enhancers was an effective approach to increase the percutaneous absorption of GRN in vitro.     

Role of partition coefficients in determining the percutaneous penetration of salicylic acid and formaldehyde under varying occlusion durations

Context: Occlusion is widely utilized to enhance the percutaneous penetration of applied drugs in clinical practice; however, occlusion does not increase the penetration of all chemicals.

Objective: This study determines: (1) whether occlusion enhances the percutaneous penetration of the lipophilic salicylic acid or the hydrophilic formaldehyde when compared to non-occlusion, (2) evaluate whether occlusion duration affects the penetration of compounds and (3) establish to what extent occlusive films in clinical practice interact with topically-applied chemicals and possibly hinder penetration.

Materials and methods: Separately, single doses of [14C]-formaldehyde and [14C]-salicylic acid were applied onto human skin overlying diffusion cells under non-occlusion as well as various occlusive time periods (1, 4 and 8?h). The percent dose penetrating into each compartment as well the percent dose adhering to the plastic wrap were determined.

Results: The radioactivity recovery as percent of applied dose of [14C]-salicylic acid was significantly higher under occlusion versus non-occlusion in the epidermis, dermis and receptor fluid after 24?h (p?Conclusion: Occlusion duration, previously undocumented for in vitro studies, impacted the percutaneous penetration of the lipophilic salicylic acid more so than the hydrophilic formaldehyde. A strong correlation between occlusion-enhanced penetration and partition coefficients was observed, but we do not wish to overgeneralize these results until more compounds of varying physical--chemical properties are studied.