Novel confocal Raman microscopy method to investigate hydration mechanisms in human skin.

BACKGROUND: Skin hydration is essential for maintaining stratum corneum (SC) flexibility and facilitating maturation events. Moisturizers contain multiple ingredients to maintain and improve skin hydration although a complete understanding of hydration mechanisms is lacking. The ability to differentiate the source of the hydration (water from the environment or deeper skin regions) upon application of product will aid in designing more efficacious formulations. MATERIALS AND METHODS: Novel confocal Raman microscopy (CRM) experiments allow us to investigate mechanisms and levels of hydration in the SC. Using deuterium oxide (D2 O) as a probe permits the differentiation of endogenous water (H2 O) from exogenous D2 O. Following topical application of D2 O, we first compare in vivo skin depth profiles with those obtained using ex vivo skin. Additional ex vivo experiments are conducted to quantify the kinetics of D2 O diffusion in the epidermis by introducing D2 O under the dermis. RESULTS: Relative D2 O depth profiles from in vivo and ex vivo measurements compare well considering procedural and instrumental differences. Additional in vivo experiments where D2 O was applied following topical glycerin application increased the longevity of D2 O in the SC. Reproducible rates of D2 O diffusion as a function of depth have been established for experiments where D2 O is introduced under ex vivo skin. CONCLUSION: Unique information regarding hydration mechanisms are obtained from CRM experiments using D2 O as a probe. The source and relative rates of hydration can be delineated using ex vivo skin with D2 O underneath. One can envision comparing these depth-dependent rates in the presence and absence of topically applied hydrating agents to obtain mechanistic information.

FT-IR investigation of Terbinafine interaction with stratum corneum constituents.

Terbinafine (Tbf) is a well-established anti-fungal agent used for management of a variety of dermal conditions including ringworm and athlete's foot. Both the biochemical mechanism of Tbf fungicidal action (based on squalene epoxidase inhibition) and the target region for Tbf in vivo (the stratum corneum (SC)) are well determined. However, the biochemical and pharmacokinetic approaches used to evaluate Tbf biochemistry provide no biophysical information about molecular level physical changes in the SC upon Tbf binding. Such information is necessary for improved drug and formulation design. IR spectroscopic methods were used to evaluate the effects of Tbf on keratin structure in environments commonly used in pharmaceutics to mimic those in vivo. The Amide I and II spectral regions (1500-1700 cm-1) provided an effective means to monitor keratin secondary structure changes, while a Tbf spectral feature near 775 cm-1 provides a measure of relative Tbf levels in skin. Interaction of Tbf with the SC induced substantial ß-sheet formation in the keratin, an effect which was partially reversed both by ethanol washing and by exposure to high relative humidity. The irreversibility suggests the presence of a Tbf reservoir (consistent with kinetic studies), permitting the drug to be released in a controlled manner into the surrounding tissue.

Effects of permeation enhancers on flufenamic acid delivery in Ex vivo human skin by confocal Raman microscopy.

For effective topical delivery, a drug must cross the stratum corneum (SC) barrier into viable tissue. The use of permeation enhancers is a widespread approach for barrier modification. In the current study, flufenamic acid (FluA), a non-steroidal anti-inflammatory drug, is a model agent for investigating the influence of hydrophobic versus hydrophilic enhancers. In separate experiments, FluA in octanol or propylene glycol/ethanol (75/25) is applied to the SC for varying times followed by confocal Raman microscopic mapping of drug and enhancer penetration and spatial distribution. Deuterated versions of the enhancers permit us to spectroscopically distinguish the exogenous chemicals from the endogenous SC lipids without affecting penetration parameters. The FluA pathway is tracked by the CC stretching mode at ∼1618cm(-1). Discrete, small inclusions of both enhancers are observed throughout the SC. High concentrations of FluA are co-localized with octanol domains which appear to provide a pathway to the viable epidermis for the drug. In contrast, FluA concentrates in the upper SC when using the hydrophilic agent and endogenous lipids appear unperturbed in regions outside the enhancer pockets. The ability to examine perturbations to endogenous ultrastructure and molecular structure in skin while tracking penetration pathways provides insight into delivery mechanisms.

Discovery of pyrano[3,4-b]indoles as potent and selective HCV NS5B polymerase inhibitors.

A novel series of HCV NS5B RNA-dependent RNA polymerase inhibitors containing a pyrano[3,4-b]indole scaffold is described leading to the discovery of compound 16, a highly potent and selective inhibitor that is active in the replicon system.