美白功效评价现状及发展趋势

doi:10.3969/j.issn.1001-1803.2021.09.012

摘要/Abstract

摘要：

近年来随着化妆品市场的迅速发展及东方女性对“美白”的热爱,使美白类化妆品成为消费者和化妆品企业关注的焦点。科技的发展和2020年《化妆品监督管理条例》的发布,使功效评价成为化妆品研发、上市中的关键环节之一。基于黑色素合成及转运机制,总结美白功效评价方法及发展趋势。着重介绍了3D皮肤模型、多光子成像技术等前沿技术的原理及特点和一些在原有美白功效评价模型或方法上的改良。

关键词: 美白, 功效评价, 黑色素合成, 黑色素转运, 条例

Abstract:

With the rapid development of the cosmetics market and the deep affection from Oriental women for “whitening”, whitening cosmetics have become the focus of consumers and cosmetics companies. With the development of science and technology and the release of the “Regulations on Supervision and Administration of Cosmetics” in 2020, efficacy evaluation has become one of the key links in the research and development and marketing of cosmetics. Melanocytes produce melanin, which is transfered from the dendrites of melanocytes to keratinocytes, and finally follows the movement of epidermal cells to the stratum corneum to form color spots or to affect the skin color. Based on the mechanism of melanin synthesis and transportation, the evaluation methods of whitening efficacy were summarized and its development trend was put forward. The evaluation methods of whitening efficacy can be divided into physicochemical method, biochemical method, cell biology method and in vivo experiment. The principle and characteristics of 3D skin model, multiphoton imaging technology and other cutting-edge technologies are emphatically introduced, as well as some improvements in the original whitening efficacy evaluation model or method. In general, the evaluation methods of whitening efficacy will develop towards the combination of biotechnology, computer technology, high-tech instruments and skin physiology that are not easily affected by individual differences in the future, and will develop from single to multiple methods guided by mechanism. In addition, cosmetic producers should also improve their own technology and innovate more products. In the future, more and more excellent technologies and models are also needed to be applied to the whitening efficacy evaluation, so as to create a good development environment for the whole industry.

Key words: whitening, whitening efficacy evaluation, melanin synthesis, melanin transport, regulations

中图分类号:

TQ658

薛婉婷,李丽,董银卯,郭苗苗. 美白功效评价现状及发展趋势[J]. 日用化学工业, 2021, 51(9): 890-896.

Xue Wanting,Li Li,Dong Yinmao,Guo Miaomiao. Status and new development tendency of cosmetics whiteningefficacy evaluation[J]. China Surfactant Detergent & Cosmetics, 2021, 51(9): 890-896.

图/表 2

表 1

表 2

参考文献 34

[1]	Ma Xue, Song Yanqing, Pan Yao, et al. Efficacy evaluation of cosmetics(Ⅻ): application of cutaneous biological test in efficacy evaluation of cosmetics[J]. China Surfactant Detergent ＆ Cosmetics, 2020, 50(1): 14-19.
[2]	D’Mello Stacey A N, Finlay Graeme J, Baguley Bruce C, et al. Signaling pathways in melanogenesis[J]. International Journal of Molecular Sciences, 2016, 17(7): 1144. doi: 10.3390/ijms17071144
[3]	Cheng Shujun, Bu Li, Pan Fang. In vitro detection of whitening cosmetics efficacy based on melanin formation mechanism[J]. Chinese Journal of Health Laboratory Technology, 2012, 22(3): 665-668.
[4]	Liao Fei, Liu Dong, Xu Limin. Research progress on transport mechanism of melanosomes[J]. Chinese Journal of Dermatovenereology of Integrated Traditional and Western Medicine, 2009, 8(2): 125-127.
[5]	Jie Shihai, Ma Pengcheng, Chen Zhiqiang. Research progress of melanin transport mechanism[J]. Foreign Medical Sciences (Section of Dermatology and Venereology), 2004 (3): 179-181.
[6]	Scott Glynis. Demonstration of melanosome transfer by a shedding microvesicle mechanism[J]. The Journal of Investigative Dermatology, 2012, 132(4): 1073-1074. doi: 10.1038/jid.2012.20
[7]	Jie Shihai. The study on the in vitro model of human epidermal melanocytes and keratinocytes co-culture system and on the effects of 11 compounds on pigmentation[D]. Beijing: Chinese Academy of Medical Sciences & Peking Union Medical College, 2006.
[8]	Yin Lanlan, Coelho Sergio G, Valencia Julio C, et al. Identification of genes expressed in hyperpigmented skin using meta-analysis of microarray data sets[J]. The Journal of Investigative Dermatology, 2015, 135(10): 2455-2463. doi: 10.1038/jid.2015.179
[9]	Chen Zhuoyi, Liu Xiaoying, Zheng Yating, et al. Mechanism of skin melanin formation and its intervention[J]. China Surfactant Detergent & Cosmetics, 2019, 49(2): 113-117.
[10]	Tao Lili, Liu Yang, Wu Jinhao, et al. Research progress on evaluation methods of whitening efficacy of cosmetics[J]. Detergent & Cosmetics, 2015, 38(3): 15-21.
[11]	Du Xiaoyuan, Liu Wei, Shi Fei, et al. Tyrosinase inhibition test and its application in efficacy evaluation of whitening cosmetics[J]. Chinese Journal of Aesthetic Medicine, 2005 (6): 740-742.
[12]	Zhao Hua, Wang Nan. Efficacy evaluation of cosmetics (Ⅲ): scientific supports for whitening cosmetic efficacy claims[J]. China Surfactant Detergent ＆ Cosmetics, 2018, 48(3): 129-133.
[13]	Guo Songhe, Gao Heyi, Zeng Sa, et al. Progress in evaluation method of cosmetic whitening effect in vitro cellular level[J]. Flavour Fragrance Cosmetics, 2016 (5): 59-62.
[14]	Cheng Yan, Dong Yiayang, Wang Chao, et al. Health safety and efficacy evaluation of whitening cosmetics[J]. Environment and Occupational Medicine, 2006, 23(6): 520-522.
[15]	Li Chengxin, Wang Ling. New recognition and biological research progresses of skin pigmentation[J]. Chinese Journal of Aesthetic Medicine, 2009, 18(9): 1372-1375.
[16]	Wu Xiaohui, Zhou Jie, Wang Zheng, et al. Efficacy assessment of lightening cosmetics and their future prospect[J]. Flavour Fragrance Cosmetics, 2007 (3): 33-36.
[17]	Pan Yao, Zhao Hua. Efficacy evaluation of cosmetics (Ⅵ): experimental design of cosmetics human efficacy evaluation[J]. China Surfactant Detergent ＆ Cosmetics, 2018, 48(6): 314-321.
[18]	Zhou Zhaoqing, Cao Rui, Wang Nan, et al. Application of sensory evaluation in cosmetics[J]. Detergent & Cosmetics, 2015, 38(10): 10-13.
[19]	Li Xiao, Zhang Xiaoe, Lu Yongbo, et al. Evaluation of cosmetic efficacy (Ⅷ): application of 3D skin model in cosmetic efficacy evaluation[J]. China Surfactant Detergent ＆ Cosmetics, 2018, 48(9): 489-494.
[20]	Brohem C A, Laura B da Silva Cardeal, Tiago M, et al. Artificial skin in perspective: concepts and applications[J]. Pigment Cell & Melanoma Research, 2011, 24(1): 35-50.
[21]	Wan Jinjin, Liu Ruixue, Lengqunying, et al. Preparation and efficacy evaluation of human-skinwhitening cream[J]. China Surfactant Detergent ＆ Cosmetics, 2017, 47(9): 512-516.
[22]	Qiu J, Chen M, Liu J, et al. The skin depigmenting potential of paeonia lactiflora root extract and paeoniflorin: in vitro evaluation using reconstructed pigmented human epidermis[J]. International Journal of Cosmetic Science, 2016: 444-451.
[23]	Dancik Y, Favre A, Loy C J, et al. Use of multiphoton tomography and fluorescence lifetime imaging to investigate skin pigmentation in vivo[J]. Journal of Biomedical Optics, 2013, 18(2): 22-26.
[24]	Pena A M, Aguilar L, Azadiguian G, et al. Multiphoton imaging in cosmetics research[C]// Visualizing and Quantifying Drug Distribution in Tissue III. Xi’an: International Society for Optics and Photonics, 2019: 1-7.
[25]	Ying Yachen, Zhang Guangjie, Jia Huilin, et al. Multi-photon skin tissue imaging technology and its applications[J]. Chinese Optics, 2019, 12(1): 107-114.
[26]	Shi Yujie, Zhang GuangJie, Lu Zhengyuan, et al. Advances in multiphoton microscopy technologies[J]. Chinese Optics, 2018, 11(3): 296-306. doi: 10.3788/co.
[27]	Liu Chao, Zhou Yan, Wang Xinwei, et al. Fluorescence lifetime imaging technology and its research progress[J]. Progress in Laser and Optoelectronics, 2011, 48(11): 50-55.
[28]	Su Ning, Liu Hongmei, Hu Nan, et al. In vivo exploring study of melanin content and distribution in human skin based on multiphoton tomography[J]. Flavour Fragrance Cosmetics, 2020 (1): 71-74.
[29]	Tian Y, Hoshino T, Chen C J, et al. The evaluation of whitening efficacy of cosmetic products using a human skin pigmentation spot model[J]. Skin Research & Technology, 2010, 15(2): 218-223.
[30]	Li Xiangzi, Zheng Yue, Ye Congxiu, et al. Minimal erythema dose, minimal persistent pigment dose which model for whitening products evaluation is better?[J]. Skin Research and Technology, 2019, 25(2): 204-210. doi: 10.1111/srt.12639 pmid: 30357919
[31]	Zhang Junsheng, Li Chunyi, Wang Xiaoli, et al. Application of ultraviolet absorption spectrum in organic chemistry[J]. Inner Mongolia Petrochemical Industry, 2010, 36(9): 27-28.
[32]	Li Sasa. The application researches of tchebichef moment methods in the analysis of chemical[D]. Lanzhou: Lanzhou University, 2019.
[33]	Li Sasa, Yin Bo, Zhai Honglin, et al. An effective approach to the quantitative analysis of skin-whitening agents in cosmetics with different substrates based on conventional uv-vis determination[J]. Analytical Methods, 2019, 11(11): 1500-1507. doi: 10.1039/C9AY00007K
[34]	Siddiqui M F, Jeon S, Kim M M. Monitoring of whitening agent for skin analysis using tyrosinase gold nanoparticle-based colorimetric assay[J]. Asia-Pacific Journal of Chemical Engineering, 2021, 16(2): 25-33.

方法类型		常用检测方法	检测指标	特点及适用条件	发展趋势
物理化学法		高效液相色谱等仪器	吸收峰	只能针对已知特定功效成分的美白原料,不适用于多种功效成分组合	局限性大,结合其他方法联用
生物化学法	生化酶学法	酪氨酸酶抑制实验	吸光度	操作简单便捷,但不能反映美白功效成分是否到达有效作用位点,适合初筛和高通量筛选	有一定局限性,结合其他方法联用
生物化学法	DPPH自由基清除实验	自由基清除率检测	吸光度	操作简单便捷,适合初筛和高通量筛选	有一定局限性,结合其他方法联用
细胞生物学法		光镜、电镜/四唑盐比色法（MTT）	黑素细胞的形态、存活率和含量^[14]/吸光度	一定程度上模拟人体内环境;对实验条件、环境要求较高且操作复杂;适合初筛和机制的研究^[15]	结合细胞图像分析技术,向着模拟更准确的人体内环境和人表皮组织结构的模型发展

方法/模型	常用检测方法	特点及适用条件	发展历程及趋势
动物模型	肉眼或组织学方法	动物的个体差异会引起误差;适用于在初筛的基础上明确待测物作用效果	检测方式从肉眼观察到仪器检测,动物模型常与仪器结合,但因为伦理原因,受到限制或禁止
人体评价方法	肉眼或者光学仪器测定	可得到待测物较为全面的、客观的综合作用效果,但也存在个体差异的影响	检测方式从目测到利用照片的灰度值再到目前使用的Lab色度系统;人体评价向着高效、精准的数据化方向发展