Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery

Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery

Retinol has been widely used as an anti-wrinkle active ingredient in cosmetic fields. However, the oxidation of retinol by air was one of the critical problems for application in the skincare field. In this study, Retinol-loaded lipid nanocarriers were prepared via the vacuum emulsification method t...

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Main Authors: Seung-Hyun Jun, Hanul Kim, HyeJin Lee, Ji Eun Song, Sun Gyoo Park, Nea-Gyu Kang
Format: Article
Language:English
Published: MDPI AG 2021-03-01
Series:Polymers
Subjects:
retinol encapsulation
nanostructured lipid nanocarrier
vacuum emulsification
thermal stability
penetration efficiency
low inflammatory factors
Online Access:https://www.mdpi.com/2073-4360/13/5/826
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spelling doaj-71eb6ded24164243bca8e1a61d8e05ab2021-03-09T00:03:29ZengMDPI AGPolymers2073-43602021-03-011382682610.3390/polym13050826Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin DeliverySeung-Hyun Jun0Hanul Kim1HyeJin Lee2Ji Eun Song3Sun Gyoo Park4Nea-Gyu Kang5LG Household and Health Care R&D Center, Seoul 07795, KoreaLG Household and Health Care R&D Center, Seoul 07795, KoreaLG Household and Health Care R&D Center, Seoul 07795, KoreaLG Household and Health Care R&D Center, Seoul 07795, KoreaLG Household and Health Care R&D Center, Seoul 07795, KoreaLG Household and Health Care R&D Center, Seoul 07795, KoreaRetinol has been widely used as an anti-wrinkle active ingredient in cosmetic fields. However, the oxidation of retinol by air was one of the critical problems for application in the skincare field. In this study, Retinol-loaded lipid nanocarriers were prepared via the vacuum emulsification method to increase the stability of retinol vulnerable to air and optimized encapsulation conditions and to increase the penetration efficiency into skin. Optimizing the components of lipid nanocarriers, gradients of carbon chain C8-22 using various lipid species which made the amorphous structure and enough spaces to load retinol inside the capsules were estimated from the lower enthalpy change and peak shift in DSC analysis. The vacuum-assisted lipid nanocarriers (VLN) could help suppress oxidation, which could have advantages to increase the thermal stability of retinol. The retinol-loaded VLN (VLN-ROL) had narrow size distribution under 0.3 PDI value, under 200 nm scaled particle size, and fully negative surface charge of about -50 mV for the electrostatic repulsion to avoid aggregation phenomenon among the lipid nanoparticles. It maintained 90% or more retinol concentration after 4 weeks of storage at 25, 40 and 50 °C and kept stable. The VLN-ROL-containing cream showed improved penetration efficiency applied to porcine skins compared to the commercial retinol 10S from BASF. The total amount of retinol into the skin of VLN-ROL (0.1% of retinol) was enhanced by about 2.2-fold (2.86 ± 0.23 μg) higher than that in 0.1% of bare retinol (about 1.29 ± 0.09 μg). In addition, applied on a 3D Human skin model, the epidermal thickness and the relative percentage of dermal collagen area effectively increased compared to the control and retinol, respectively. Additionally, the level of secreted IL-1α was lower and epidermal damage was weaker than commercial product A. This retinol-loaded lipid nanocarrier could be a potentially superior material for cosmetics and biomedical research.https://www.mdpi.com/2073-4360/13/5/826retinol encapsulationnanostructured lipid nanocarriervacuum emulsificationthermal stabilitypenetration efficiencylow inflammatory factors
collection DOAJ
language English
format Article
sources DOAJ
author Seung-Hyun Jun
Hanul Kim
HyeJin Lee
Ji Eun Song
Sun Gyoo Park
Nea-Gyu Kang
spellingShingle Seung-Hyun Jun
Hanul Kim
HyeJin Lee
Ji Eun Song
Sun Gyoo Park
Nea-Gyu Kang
Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery
Polymers
retinol encapsulation
nanostructured lipid nanocarrier
vacuum emulsification
thermal stability
penetration efficiency
low inflammatory factors
author_facet Seung-Hyun Jun
Hanul Kim
HyeJin Lee
Ji Eun Song
Sun Gyoo Park
Nea-Gyu Kang
author_sort Seung-Hyun Jun
title Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery
title_short Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery
title_full Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery
title_fullStr Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery
title_full_unstemmed Synthesis of Retinol-Loaded Lipid Nanocarrier via Vacuum Emulsification to Improve Topical Skin Delivery
title_sort synthesis of retinol-loaded lipid nanocarrier via vacuum emulsification to improve topical skin delivery
publisher MDPI AG
series Polymers
issn 2073-4360
publishDate 2021-03-01
description Retinol has been widely used as an anti-wrinkle active ingredient in cosmetic fields. However, the oxidation of retinol by air was one of the critical problems for application in the skincare field. In this study, Retinol-loaded lipid nanocarriers were prepared via the vacuum emulsification method to increase the stability of retinol vulnerable to air and optimized encapsulation conditions and to increase the penetration efficiency into skin. Optimizing the components of lipid nanocarriers, gradients of carbon chain C8-22 using various lipid species which made the amorphous structure and enough spaces to load retinol inside the capsules were estimated from the lower enthalpy change and peak shift in DSC analysis. The vacuum-assisted lipid nanocarriers (VLN) could help suppress oxidation, which could have advantages to increase the thermal stability of retinol. The retinol-loaded VLN (VLN-ROL) had narrow size distribution under 0.3 PDI value, under 200 nm scaled particle size, and fully negative surface charge of about -50 mV for the electrostatic repulsion to avoid aggregation phenomenon among the lipid nanoparticles. It maintained 90% or more retinol concentration after 4 weeks of storage at 25, 40 and 50 °C and kept stable. The VLN-ROL-containing cream showed improved penetration efficiency applied to porcine skins compared to the commercial retinol 10S from BASF. The total amount of retinol into the skin of VLN-ROL (0.1% of retinol) was enhanced by about 2.2-fold (2.86 ± 0.23 μg) higher than that in 0.1% of bare retinol (about 1.29 ± 0.09 μg). In addition, applied on a 3D Human skin model, the epidermal thickness and the relative percentage of dermal collagen area effectively increased compared to the control and retinol, respectively. Additionally, the level of secreted IL-1α was lower and epidermal damage was weaker than commercial product A. This retinol-loaded lipid nanocarrier could be a potentially superior material for cosmetics and biomedical research.
topic retinol encapsulation
nanostructured lipid nanocarrier
vacuum emulsification
thermal stability
penetration efficiency
low inflammatory factors
url https://www.mdpi.com/2073-4360/13/5/826
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