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http://dx.doi.org/10.4014/mbl.1807.07001

Screening of Skin-permeable Peptide in Thermal Stabilizing Formulation Using Phage Display  

Lee, Seol-Hoon (Department of Applied Chemistry, Dongduk Women's University)
Publication Information
Microbiology and Biotechnology Letters / v.46, no.4, 2018 , pp. 326-333 More about this Journal
Abstract
In this study, we identified methods to improve heat stability and skin permeability of functional protein biopolymers, such as growth factors, enzymes, and peptides. The biopolymers participate in cellular activation and catalytic functions in vivo. Therefore, when applied to cosmetics, their efficacies are expected to be helpful for skin care. However, they have disadvantages that include instability to heat and low skin permeability due to their high molecular weight. To overcome these problems, we searched for a composition that increases heat stability. Stability was improved using a polymeric humectant having a long polyethylene glycol length, compared with a mono-molecular structure humectant. Next, to enhance skin permeation, a permeation enhancing peptide was selected from a phage library. The permeation enhancing peptide can be commonly used to promote the permeation of growth factors, enzymes, and peptides. Screening was performed on the polymeric humectant formulation. One dominant peptide from the modified-screening method was identified. Furthermore, it was confirmed that the permeability of the peptide was better than that of the peptide developed through a screening system based on phosphate-buffered saline. The data indicate that the polymeric humectant formulation will be helpful for increasing the heat stability of protein ingredients and that skin permeability could be increased by a formulation-specific, penetration-enhancing peptide.
Keywords
Phage display; skin penetration; heat stability; polymeric humectant;
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