天然绿色蚕丝抗氧化组分向皮肤迁移的特性研究

doi:10.13475/j.fzxb.20220901901

摘要/Abstract

摘要：

为明晰天然绿色蚕丝产品贴身使用时的抗氧化性能,利用经皮渗透实验研究了其抗氧化组分向皮肤迁移的性质,并利用自由基清除法评价了渗透后皮肤各层的抗氧化活性。研究结果表明:天然绿色蚕丝抗氧化组分向皮肤迁移具有时间依赖性,且和皮肤表面的湿度、酸碱性有关;抗氧化组分迁移量与样品的皮肤接触时间正相关;接触时间少于12 h,抗氧化组分更多地分布于角质层中,12 h后抗氧化组分更多地渗透并累积于真皮层中,其抗氧化组分不能穿透整个皮层;微湿的皮肤环境更有利于抗氧化组分向皮肤迁移,酸性皮肤环境有利于抗氧化组分向皮肤深层迁移;由于抗氧化物组分的存在,各皮层的抗氧化活性得到了显著增强,且具有剂量效应。

关键词: 天然绿色蚕丝, 抗氧化物质, 抗氧化纤维, 黄酮类, 皮肤, 迁移特性

Abstract:

Objective Naturally green-colored silk has excellent antioxidant property due to the intrinsic flavonoid-based pigments. It is a promising alternative antioxidant functional natural fiber for being as healthcare textiles. However, the transdermal characteristics, influencing factors and dose effect relationship of antioxidant components from naturally green-colored silk to skin have not been reported, so it is necessary to study them in order to clarify the antioxidant effect toward the human skin when using its products.

Method Transdermal permeation test were carried out on a transdermal permeation device and pork skins were used to simulate the permeation process of the antioxidant substances to the skin from the silk fiber. The pure water extract of natural green-colored silk and the extract of above skin tissues were analyzed by high performance liquid chromatography. The Folin phenol method was used to quantitatively detect the antioxidant extracts in each cortex. The classical DPPH radical scavenging method was used to evaluate the antioxidant activity of pig skin tissues after migration test.

Results The results of high-performance liquid chromatography analysis show that the antioxidant components in the fibers can migrate to the stratum corneum layer and dermis layer of the skin (Fig. 2). The antioxidants were found to be present mainly in the stratum corneum layer when the contact time was less than 12 h, but they were accumulated mainly in the dermis layer when the contact time exceeded 12 h (Fig. 4). The antioxidants could not permeate the whole skin layers. Under humidity conditions similar to skin sweating, the total polyphenol content in the skin reached at (11.7±2.9) μg/cm², accounting for 11.0% of the total fiber phenol content (Tab. 1). Antioxidant components migrated in general in acidic skin environments and migrated more to the deeper layers of the skin under the normal skin environment. In the acidic skin environment, the polyphenol content in the stratum corneum and dermis layer were 2.9 μg/cm² and 10.5 μg/cm² (Fig. 3), respectively. Both of the stratum corneum layer and dermis layer showed considerable improvement in antioxidant activity, and it obeyed the dose-response effect, and the more antioxidant components absorbed by the skin layers, the greater the free radical scavenging capacity of the skin layers. Volunteer trials were also carried out. After 24 h of fabric-to-skin contact, the content of polyphenols detected in the stratum corneum of the skin ranged from 5.1 to 6.6 μg/cm², with an average value of (5.7±0.5) μg/cm² (Fig. 5). Due to the high content of antioxidant components presented in the skin, the average scavenging rate toward the free radicals in the stratum corneum of the skin of volunteers was(76.7±8.2)%, which was significantly higher than the antioxidant activity of the stratum corneum (37.8±3.7)% of the pig skin experimental group at the same condition.

Conclusion The antioxidant components in the fibers can migrate to the stratum corneum layer and dermis layer of the skin. The amount of antioxidant permeated to the skin depended on the contact time, moisture, and the acidity and basicity of the skin. The amount of antioxidants in the skin was positively related to the contact time. The skin surface with light moisture facilitated the permeation of antioxidants to the skin, but it is not that the moister the skin, the greater the migration, similar to the human body skin with slightly sweating environment which is better for the antioxidant to permeate to the skin. Acidic skin environment enabled a deeper permeation of the antioxidants as compared with the basic skin environment. The antioxidant components in the fibers can migrate into the human skin and endow the skin with excellent antioxidant capacity. This enables naturally green-colored silk to be used as a promising antioxidant textile material.

Key words: naturally green-colored silk, antioxidant substance, antioxidant fiber, flavonoids, skin, transdermal characteristic

中图分类号:

TS102.33

谭婷, 李哲阳, 马明波, 周文龙. 天然绿色蚕丝抗氧化组分向皮肤迁移的特性研究[J]. 纺织学报, 2023, 44(10): 75-80.

TAN Ting, LI Zheyang, MA Mingbo, ZHOU Wenlong. Study of transdermal characteristics of antioxidant substances in naturally green-colored silk[J]. Journal of Textile Research, 2023, 44(10): 75-80.

图/表 6

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参考文献 11

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皮层	多酚含量/(μg·cm^-2)			多酚占纤维总酚含量的百分率/%
皮层	1∶0	1∶5	1∶10	1∶0	1∶5	1∶10
角质层	1.9±1.1	2.8±1.9	2.3±0.6	1.8±1.0	2.6±1.8	2.1±0.6
真皮层	1.9±1.4	8.9±3.4	7.8±2.3	1.8±1.3	8.3±3.1	7.3±2.1
总计	3.8±2.0	11.7±2.9	10.1±2.8	3.6±1.9	11.0±2.7	9.4±2.6