• Journal of the Society of Cosmetic Scientists of Korea
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• v.48 no.4
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• pp.385-392
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• 2022

In this study, keratin peptides were produced through high-temperature anaerobic fermentation of keratin, a protein contained in deer antler, with Fervidobacterium islandicum AW-1, and factors related to human hair, confirming the possibility of keratin peptides as cosmetic ingredients. As a result of the cytotoxicity and proliferation of deer antler fermented keratin peptide according to the concentration in the dermal papilla cell line, cytotoxicity was not observed and the cell proliferation effect was shown. For human dermal papilla cells, statistically significant increasing in growth factors according to the deer antler fermented keratin peptide was determined possiblity of effects on hair growth. Cosmetic products containing deer antler fermented keratin peptides were manufactured and skin safety and anti hair loss efficacy clinical tests were conducted. As a result, after 12 weeks of use, the total number of hairs statistically significant increased compared to before using the product and the difference in total number of hairs compared to the control group was found. In conclusion, we suggest that the possibility of fermented deer antler keratin peptide as a cosmeceutical ingredient as well as a health functional food material was confirmed.

• Journal of the Society of Cosmetic Scientists of Korea
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• v.36 no.2
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• pp.105-113
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• 2010

This study introduces a flexible approach to enhance skin permeation by using ethosomes with deformable lipid membranes as well as controllable sizes. To demonstrate this, a set of ethosomes encapsulating an anti-hair loss ingredient, Triaminodil$^{TM}$, as a model drug, were fabricated with varying their size, which was achieved by solely applying the different level of mechanical energy, while maintaining their chemical composition. After characterization of the ethosomes with dynamic light scattering, transmission electron microscopy, and deformability measurements, it was found that their membrane deformability depended on the particle size. Moreover, studies on in vitro skin permeation and murine anagen induction allowed us to figure out that the membrane deformability of ethosomes essentially affects delivery efficiency of Triaminodil$^{TM}$ through the skin. It was noticeable in our study that there existed an optimum particle size that can not only maximize the delivery of the drug through the skin, but also increase its actual dermatological activity. These findings offer a useful basis for understanding how ethosomes should be designed to improve delivery efficiency of encapsulated drugs therein in the aspects of changing their length scales and membrane properties.