PURPOSE: Percutaneous absorption assays of molecules for pharmaceutical and cosmetology purposes are important to determine the bioavailability of new compounds, once topically applied. The current method of choice is to measure the rate of diffusion through excised human skin using a diffusion cell. This method however entails significant drawbacks such as scarce availability and poor reproducibility of the sample, low sampling rate, and tedious assay setup. METHODS: The objective of the present work is to propose an alternative method that overcomes these issues by integrating an experimental model of the skin (artificial stratum corneum) and online optical sensors into a microfluidic device. RESULTS: The measurement of the diffusion profile followed by the calculation of the permeability coefficients and time lag were performed on seven different molecules and obtained data positively fit with those available from literature on human skin penetration. The coating of the lipid mixture to generate the artificial stratum corneum also proved robust and reproducible. The results show that the proposed device is able to give fast, real-time, accurate, and reproducible data in a user-friendly manner, and can be produced at a large scale. CONCLUSION: These assets should help both the cosmetics and pharmaceutics fields where the skin is the target or a pathway of a formulated compound, by allowing more candidate molecules or formulations to be assessed during the various stages of their development.
PURPOSE: Percutaneous absorption assays of molecules for pharmaceutical and cosmetology purposes are important to determine the bioavailability of new compounds, once topically applied. The current method of choice is to measure the rate of diffusion through excised human skin using a diffusion cell. This method however entails significant drawbacks such as scarce availability and poor reproducibility of the sample, low sampling rate, and tedious assay setup. METHODS: The objective of the present work is to propose an alternative method that overcomes these issues by integrating an experimental model of the skin (artificial stratum corneum) and online optical sensors into a microfluidic device. RESULTS: The measurement of the diffusion profile followed by the calculation of the permeability coefficients and time lag were performed on seven different molecules and obtained data positively fit with those available from literature on human skin penetration. The coating of the lipid mixture to generate the artificial stratum corneum also proved robust and reproducible. The results show that the proposed device is able to give fast, real-time, accurate, and reproducible data in a user-friendly manner, and can be produced at a large scale. CONCLUSION: These assets should help both the cosmetics and pharmaceutics fields where the skin is the target or a pathway of a formulated compound, by allowing more candidate molecules or formulations to be assessed during the various stages of their development.
Authors: Jean F Michelet; Christian Olive; Elodie Rieux; Dominique Fagot; Lucie Simonetti; Jean B Galey; Maria Dalko-Csiba; Bruno A Bernard; Rui Pereira Journal: Exp Dermatol Date: 2012-05 Impact factor: 3.960
Authors: S Schreiber; A Mahmoud; A Vuia; M K Rübbelke; E Schmidt; M Schaller; H Kandárová; A Haberland; U F Schäfer; U Bock; H C Korting; M Liebsch; M Schäfer-Korting Journal: Toxicol In Vitro Date: 2005-09 Impact factor: 3.500
Authors: Aurélie Laurent; Frédéric Mistretta; David Bottigioli; Karima Dahel; Catherine Goujon; Jean François Nicolas; Anca Hennino; Philippe E Laurent Journal: Vaccine Date: 2007-06-11 Impact factor: 3.641