Pigmentation Effects of Blue Light Irradiation on Skin and How to Protect Against Them

Overview

Journal Int J Cosmet Sci

Specialty Dermatology

Date 2020 Jun 2

PMID 32478879

Citations 20

Authors

R Campiche

S J Curpen

V Lutchmanen-Kolanthan

S Gougeon

M Cherel

G Laurent

M Gempeler

R Schuetz

Affiliations

Soon will be listed here.

Abstract

Background: Visible light, in particular blue light, has been identified as an additional contributor to cutaneous photoageing. However, clinical studies demonstrating the clear effect of blue light on photoageing are still scarce, and so far, most studies have focused on broad-spectrum visible light. Although there is evidence for increased skin pigmentation, the underlying mechanisms of photoageing in vivo are still unclear. Furthermore, there is still a need for active ingredients to significantly protect against blue light-induced hyperpigmentation in vivo. Our study had two aims: to detect visible changes in skin pigmentation following repeated irradiation of the skin with LED-based blue light and to reduce pigmentation using suitable active ingredients.

Method: We conducted a randomized, double-blind and placebo-controlled clinical study on 33 female volunteers with skin phototypes III and IV. We used a repetitive blue light (4 × 60 J cm , 450 nm) irradiation protocol on the volunteers' inner forearms. Using hyperspectral imaging, we assessed chromophore status. In addition, we took chromameter measurements and photographs to assess visible hyperpigmentation.

Results: We measured significant changes in chromophore status (P < 0.001 vs baseline), that is of melanin, haemoglobin and oxygen saturation, immediately after blue light irradiation. In addition, we found visible skin colour changes which were expressed by a significant decrease in ITA° values (delta ITA° = -16.89, P < 0.001 vs baseline for the placebo group) and an increase in a* (delta a* = +3.37, P < 0.001 vs baseline for the placebo group) 24 h post-irradiation. Hyperpigmentation and skin reddening were mitigated by both a formulation containing 3% of a microalgal product and a formulation containing 3% niacinamide.

Conclusion: Our study sets out an efficient and robust protocol for investigating both blue light-induced cutaneous alterations, such as changes in skin chromophores, and signs of photoageing, such as hyperpigmentation. Moreover, we have shown evidence that both an extract of the microalga Scenedesmus rubescens and niacinamide (vitamin B3) have the potential to protect against blue light-induced hyperpigmentation.

Citing Articles

Photoaging: Current Concepts on Molecular Mechanisms, Prevention, and Treatment.

Kaltchenko M, Chien A Am J Clin Dermatol. 2025; .

PMID: 40072791 DOI: 10.1007/s40257-025-00933-z.

Biological and Nutritional Applications of Microalgae.

Saritas S, Kalkan A, Yilmaz K, Gurdal S, Goksan T, Witkowska A Nutrients. 2025; 17(1.

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Screens, Blue Light, and Epigenetics: Unveiling the Hidden Impact on Skin Aging.

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PMID: 39497903 PMC: 11532803. DOI: 10.1093/asjof/ojae088.

Niacinamide: a review on dermal delivery strategies and clinical evidence.

Ong R, Goh C Drug Deliv Transl Res. 2024; 14(12):3512-3548.

PMID: 38722460 DOI: 10.1007/s13346-024-01593-y.

Blue light protection factor: a method to assess the protective efficacy of cosmetics against blue light-induced skin damage in the Chinese population.

Zhang R, Pu W, Zhang X, Di Y, Xu J, Zhu M Photochem Photobiol Sci. 2024; 23(4):711-718.

PMID: 38430370 DOI: 10.1007/s43630-024-00546-1.

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