Carbon dioxide foam bubbles enhance skin penetration through the stratum corneum layer with mechanical mechanism.

Topical skin formulations often include penetration enhancers that interact with the outer stratum corneum (SC) layer to chemically enhance diffusion. Alternatively, penetration can be mechanically enhanced with simple rubbing in the presence of solid particles sometimes included to exfoliate the top layers of the SC. Our goal was to evaluate micron-sized carbon dioxide bubbles included in a foamed moisturizing formulation as a mechanical penetration enhancement strategy. We show that moisturizing foam bubbles cause an increase in SC formulation penetration using both mechanical and spectroscopic characterization. Our results suggest viscous liquid film drainage between coalescing gaseous bubbles creates local regions of increased hydrodynamic pressure in the foam liquid layer adjacent to the SC surface that enhances treatment penetration. An SC molecular diffusion model is used to rationalize the observed behavior. The findings indicate marked increased levels of treatment concentration in the SC at 2 h and that persists to 18 h after exposure, far exceeding non-foamed treatments. The study suggests an alternate strategy for increasing formulation penetration with a non-chemical mechanism.

Efficacy of a fine fiber film applied with a water-based lotion to improve dry skin.

BACKGROUND: Dry skin can trigger eczema that affects >10% of the US population. Dressing films have been developed to improve diseased skin, but there is limited knowledge about their effects, especially for dry skin-related symptoms. We developed an electrospinning method that creates a coating film, called a fine fiber (FF) film, characterized by the production of a transparent, thin, flexible, and adherent membrane on the skin surface. OBJECTIVE: The aim of this pilot study was to examine the effects of the FF film on dry skin. METHODS: Three treatments (lotion only, lotion with the FF film, and lotion with an alternative film) were designed to treat subjects with rough skin on their lower legs. Twenty-four females were enrolled and used either a water-based lotion U or a petrolatum-based lotion P and the FF film for 2 weeks followed by a regression phase for 1 week. Skin hydration and roughness scores were assessed as were the subjects' perceptions of the effects. RESULTS: When the FF film was applied with lotion U, skin hydration was significantly improved even after 1 week, accompanied by a significant improvement of skin roughness and an increase in skin hydration by the end of the regression phase. An evaluation of moisture permeability suggested that the FF film, especially with lotion U, performed as a semipermeable membrane with optimal moisture healing effects on dry skin. CONCLUSION: The FF film together with a water-based lotion is a promising treatment to quickly improve dry skin conditions.

Ectoine disperses keratin and alters hydration kinetics in stratum corneum.

Moisturizing compounds are commonly applied topically to human stratum corneum (SC). Many types of molecular species are employed, most commonly including humectants and occlusives. We find new evidence of keratin dispersion caused by the moisturizing compound ectoine (1,4,5,6-tetrahydro-2-methyl-4-pyrimidinecarboxylic acid), and provide the first characterization of its impacts on the hydration kinetics and biomechanics of SC. A second compound, 2-(2-hydroxyethoxy)ethylguanidine succinate (HEG) was investigated for comparison. A suite of biomechanical and biochemical assays including FTIR, drying stress, and cellular cohesion were used. Studies were conducted on normal, lipid-extracted, and lipid plus natural moisturizing factor extracted SC. Ectoine was found to improve the dispersity and hydration of keratin bundles in corneocytes. It also decreased rates of stress development in lipid extracted SC when exposed to a dry environment by ∼30% while improving stress reduction during rehydration by ∼20%. Peak stresses were increased in harsh drying environments of <5% RH, but SC swelling measurements suggest that water retention was improved in ambient conditions. Further, changes up to ∼4 J/m2 were seen in cohesion after ectoine treatments, suggesting corneodesmosome interactions. HEG was tested and found to disperse keratin without impacting corneodesmosomes. These results indicate that keratin dispersants produce beneficial effects on SC hydration kinetics, ultimately resulting in higher SC hydration under ambient conditions.

Lipid Loss Increases Stratum Corneum Stress and Drying Rates.

BACKGROUND: The lipid components and natural moisturizing factors (NMFs) of the stratum corneum (SC) are integral pieces of the self-regulating barrier strategy which comprises one of the most important functions of human skin and seems to be related to biomechanical responses of the SC. OBJECTIVES: This work presents the contributions of the lipid bilayers and NMFs to the barrier properties and mechanical responses of human SC. METHODS: We performed 2 biomechanical experiments, substrate curvature testing and double cantilever beam cohesion measurements, on isolated human SC exposed to either water, a 1:1 mixture of acetone/ether, or a 1:1 mixture of chloroform/methanol for various durations. RESULTS: We show that treating ex vivo SC with organic solvents results in lipid extraction which increases with duration of exposure. This extraction is tied to a remarkably linear increase in the levels and rates of biaxial stress development during drying/hydration cycles. This effect appears to be tied to the total amounts of lipids extracted. Furthermore, striking changes are seen in the intercellular cohesion properties of the tissue after solvent exposure. Interestingly, changes in drying stress profiles are not observed after treatment with water, which has been previously shown to remove NMFs from the tissue, and which therefore might be expected to induce changes in the drying behavior of the skin. However, changes in intercellular cohesion and the SC cohesion gradient are seen, suggesting impacts on the corneodesmosome protein binding junctions within the tissue. CONCLUSIONS: These results suggest that lipid loss causes marked increases in SC drying stresses, which may in turn contribute to changes in skin perception. NMF extraction may be important in vivo, but has remarkably little impact in isolated SC.

Free fatty acids chain length distribution affects the permeability of skin lipid model membranes.

The lipid matrix in the stratum corneum (SC) plays an important role in the barrier function of the skin. The main lipid classes in this lipid matrix are ceramides (CERs), cholesterol (CHOL) and free fatty acids (FFAs). The aim of this study was to determine whether a variation in CER subclass composition and chain length distribution of FFAs affect the permeability of this matrix. To examine this, we make use of lipid model membranes, referred to as stratum corneum substitute (SCS). We prepared SCS containing i) single CER subclass with either a single FFA or a mixture of FFAs and CHOL, or ii) a mixture of various CER subclasses with either a single FFA or a mixture of FFAs and CHOL. In vitro permeation studies were performed using ethyl-p-aminobenzoic acid (E-PABA) as a model drug. The flux of E-PABA across the SCS containing the mixture of FFAs was higher than that across the SCS containing a single FA with a chain length of 24 C atoms (FA C24), while the E-PABA flux was not effected by the CER composition. To select the underlying factors for the changes in permeability, the SCSs were examined by Fourier transform infrared spectroscopy (FTIR) and Small angle X-ray scattering (SAXS). All lipid models demonstrated a similar phase behavior. However, when focusing on the conformational ordering of the individual FFA chains, the shorter chain FFA (with a chain length of 16, 18 or 20 C atoms forming only 11m/m% of the total FFA level) had a higher conformational disordering, while the conformational ordering of the chains of the CER and FA C24 and FA C22 hardly did not change irrespective of the composition of the SCS. In conclusion, the conformational mobility of the short chain FFAs present only at low levels in the model SC lipid membranes has a great impact on the permeability of E-PABA.

Targeted sequence alteration of a chromosomal locus in mouse liver.

Targeted sequence alteration would be an attractive method in gene therapy and biotechnology. To achieve in vivo targeted sequence alteration, a tailed duplex DNA consisting of annealed 35mer and 794mer single-stranded DNAs was delivered by means of hydrodynamic tail vein injection into liver of transgenic mouse harboring a reporter gene (the rpsL gene) in its genome. The tailed DNA was designed for a conversion of ATC to AGC at codon 80 of the rpsL transgene. The anticipated T-->G sequence alteration was induced in the transgene in the liver with an efficiency of approximately 0.1%. These results demonstrate the significant potential of this method for applications in gene therapy and biotechnology.

Effects of target sequence and sense versus anti-sense strands on gene correction with single-stranded DNA fragments.

The correction of an inactivated hygromycin resistance and enhanced green fluorescent protein (Hyg-EGFP) fusion gene by a several hundred-base single-stranded (ss) DNA fragment has been reported. In this study, the effectiveness of this type of gene correction was examined for various positions in the rpsL gene. Sense and anti-sense ssDNA fragments were prepared, and the gene correction efficiencies were determined by co-introduction of the target plasmid containing the gene with the ssDNA fragments. The gene correction efficiency varied (0.8-9.3%), depending on target positions and sense/anti-sense strands. Sense ssDNA fragments corrected the target gene with equal or higher efficiencies as compared to their anti-sense counterparts. The target positions corrected with high efficiency by the sense fragments also tended to be corrected efficiently by the anti-sense fragments. These results suggest that the sense ssDNA fragments are useful for the correction of mutated genes. The variation in the correction efficiency may depend on the sequence of the target position in double-stranded DNA.

Improved gene correction efficiency with a tailed duplex DNA fragment.

A 606-base single-stranded (ss) DNA fragment, prepared by restriction enzyme digestion of ss phagemid DNA, corrects a hygromycin resistance and enhanced green fluorescent protein (Hyg-EGFP) fusion gene more efficiently than a PCR fragment, which is the conventional type of DNA fragment used in gene correction. Here, a tailed duplex, obtained by annealing an oligonucleotide to the ss DNA fragment, was used in the correction. The tailed duplex may be a good substrate for the RAD51 protein, an important enzyme in homologous recombination, which could be the gene correction pathway. The annealing of the oligonucleotides enhanced the correction efficiency of the Hyg-EGFP gene, especially when annealed in the 3'-region of the ss DNA fragment. Both the length and backbone structure of the oligonucleotides affected the gene correction efficiency. This type of gene correction device was also effective for another target gene, the rpsL gene. The results obtained in this study indicate that tailed duplex DNA fragments are effective nucleic acids for gene correction.

Conversion of nucleotide sequence with single-stranded DNA fragment prepared from phagemid DNA.

The correction of a mutated gene is a highly attractive approach for gene therapy. This in vivo mutagenesis method will also be an effective tool in biotechnology. However, the current small fragment homologous replacement (SFHR) method with a heat-denatured double-stranded PCR fragment yielded the low correction efficiency. Single-stranded DNA fragments were prepared from single-stranded phagemid DNAs and tested in a gene correction assay with a Hyg-EGFP fusion gene inactivated by a substitution mutation, as a model target. A 606-nt sense, single-stranded DNA fragment dramatically (12-fold) improved the gene correction efficiency, although the antisense strand showed only minimal correction efficiency. On the other hand, correction of frameshift mutations with the sense single-stranded DNA fragment were 2-3-fold as efficient as that with the PCR fragment. These results suggest that the use of a sense, single-stranded DNA fragment is useful in the SFHR method for the correction of mutated genes.