About 50% of the sunlight reaching the Earth's surface is visible light (400-700 nm). Other sources of visible light (VL) include lasers, light-emitting diodes and flash lamps. Photons from VL are absorbed by photoreceptive chromophores (e.g., melanin, heme, and opsins), altering the skin function by activating and imparting energy to chromophores. Additionally, VL penetrates the full thickness of the skin and induces pigmentation and erythema.(1)
In recent years, studies have increasingly shown the negative impact of VL on skin, particularly in individuals with skin of color (SOC; Fitzpatrick skin types IV-VI), including the exacerbation of hyperpigmentation disorders, such as melasma and postinflammatory hyperpigmentation, as well as induction of the former.(2) Differences between dark skin and light skin include:
- Larger, more melanized melanosomes, distributed individually within the keratocytes rather than in aggregates, in skin phototypes (SPTs) IV to VI;
- Melanin in SOC can filter 2 to 5 times more UV than melanin in light-skinned individuals;
- Epidermis of SPTs V to VI has an intrinsic sun protection factor (SPF) of 13.4 compared to a SPF of 3.3 in light phototypes.
The mechanism of VL-induced hyperpigmentation is thought to be different from that of UVA.(3) Free radicals can be generated in the skin by sunlight, and 50% of those are induced by visible light.(4, 5, 6) The induction of free radicals, leading to the generation of reactive species, is one driving mechanism of VL-induced skin pathologies, leading to the induction of melanogenesis and hyperpigmentation.
When comparing the effect of VL on the immediate pigmentation and delayed tanning of melano-competent skin with those induced by long-wavelength UVA (UVA1), VL-induced pigmentation is darker and more sustained, and UVA1 and visible light can synergistically induce pigmentation in skin types IV-VI.(7) No pigmentation is observed in skin type II. Furthermore, VL induces an immediate erythema in lightand dark-skinned individuals.(7, 8)
In dark skin-type melanocytes, the blue light (BL) component of VL is sensed by opsin (OPN)3, which ultimately leads to sustained upregulation of the key melanogenic enzymes tyrosinase and dopachrome tautomerase.(3) Moreover, the stimulation of OPN3 by BL induces tyrosinase complexes that stabilize tyrosinase activity, which explains the longlasting hyperpigmentation observed after VL exposure.(3) This multimeric tyrosinase/ tyrosinase-related protein complex is mainly formed in dark-skinned melanocytes and induces a sustained tyrosinase activity.(3, 9)
The VL + UVA1 combination may play a role in conditions worsened by sun exposure, such as post-inflammatory hyperpigmentation and melasma, especially in dark-skinned individuals. The combination of VL + UVA1 induces erythema in light-skinned individuals. The photobiologic effects of sunlight are given in Table 1. Currently available organic (chemical) UV filters are not sufficient to protect the skin from the effects of VL. However, data are emerging on the efficacy of topical and oral antioxidants, tinted sunscreens, and novel filters against VL-induced effects.
Recently, there has been increased recognition regarding tinted sunscreens, as they offer good protection against the effects of VL. Public interest in sunscreen searches using Google trends increased greatly between 2016 and 2021, particularly for tinted and mineral vs. chemical sunscreens.(10) A practical guide to tinted sunscreens, including a comprehensive list of 53 tinted sunscreens with SPF ≥ 30 containing iron oxide, has recently been made available on Mendeley (http://dx.doi.org/10.17632/dtb4y9b684). (11)
These tinted sunscreens are listed according to average price per ounce. There may be a role for antioxidants (AO) and free radical quenchers in skin protection, and initial clinical studies have demonstrated the effectiveness of topical sunscreen with antioxidant. Topical AO (2%), compared to control, decreased erythema in SPT I-III and reduced pigmentation (immediate pigment darkening, persistent pigment darkening, and delayed tanning response) in SPT IV-VI caused by VL+ UVA1.(12) In another study, sunscreen SPF 50 with 5 antioxidants had the same protective effect as tinted sunscreen SPF 20 on skin exposed to VL + UVA1.(13)
Polypodium leucotomos extract (PLE) has properties that may offer protection against VL. In subjects with Fitzpatrick skin phototype IV-VI who received a 28-day oral supplementation of PLE (480 mg daily), a statistically significant difference in the amount of relative pigment was observed when comparing persistent pigment darkening and delayed tanning pre- and post-PLE.(14) In addition, PLE was shown to prevent UV- and VL-induced extracellular matrix degradation by:
- Stimulating tissue inhibitor of metalloproteases;
- Inducing expression of collagen and elastin;
- Inhibiting the expression and enzymatic levels of matrix metalloproteinases (MMPs);
- Functioning as an antioxidant.(15)
PLE could therefore potentially be used as an adjuvant to traditional means of photoprotection, to protect against the effects of VL.
Different sunscreens are needed for different phototypes, a concept termed “personalized photoprotection”. Using an artificial intelligence-based algorithm validated by dermatologists, marked differences were observed in the skin ageing process between 2 very large groups of European and Chinese women, both in the prevalence of each facial ageing sign and their kinetics.(16) Thus, photoprotection should be recommended according to skin phototype and dermatoses. Protection against ultraviolet (UV)B is especially important for light skin as there is a high risk of sunburn, DNA damage and skin cancers. Darker skin may be naturally better protected against UVB, but it is more prone to hyperpigmentation induced by visible light (VL) and UVA.
Protection against UVA, VL and infrared A can be helpful for all skin phototypes, as they penetrate deeply and cause photoaging. Long-wave UVA1 plays a critical role in pigmentation, photoaging, skin cancer, DNA damage and photo-dermatoses. Adapting the formulation and texture of the sunscreen to the type of skin and dermatosis is therefore essential.
Practical recommendations from an expert panel for suitable sunscreens for Fitzpatrick prototype I to VI were issued in 2021 to support the clinician in daily practice.(17) The absorption profile of sunscreen recommended for healthy individuals with different skin phototypes for the prevention of skin cancers and photoaging is shown in Figure 1.(17) The latitude of where the individual lives should also be taken in consideration.(17)
