Effect of red light on epidermal proliferation and mitochondrial activity.

BACKGROUND/PURPOSE: We previously demonstrated that irradiation with red light accelerates recovery of the epidermal water-impermeable barrier, whereas blue light delays it, and white and green light have no effect. Here, we aimed to examine in detail the effects of red and blue light in a human epidermal-equivalent model and in human skin. METHODS: We used light-emitting diodes (red light, 630 nm, 6.2 mW/cm2 ; blue light, 463 nm, 6.2 mW/cm2 ) for irradiation of an epidermal-equivalent model and human skin. Cell proliferation was evaluated by means of BrdU and Ki-67 staining, and mitochondrial activity was quantified with an extracellular flux analyzer. RESULTS: Irradiation of the epidermal-equivalent model with red light for 2 h (44.64 J/cm2 ) increased both epidermal proliferation in the basal layer and mitochondrial activity. Blue light had no effect on epidermal proliferation. Furthermore, irradiation with red light for 2 h on three consecutive days increased epidermal proliferation in human skin tissue in culture. CONCLUSION: These results suggest that red light accelerates epidermal proliferation in both an epidermal-equivalent model and human skin, and may promote epidermal homeostasis.

Polyoxyethylene/polyoxypropylene dimethyl ether (EPDME) random copolymer improves lipid structural ordering in stratum corneum of an epidermal-equivalent model as seen by two-photon microscopy.

BACKGROUND/PURPOSE: Topical application of polyoxyethylene/polyoxypropylene dimethyl ether (EPDME) random copolymer improves the barrier function of skin, whereas polyethylene glycol (PEG) and polypropylene glycol (PPG) are ineffective. The aim of this work was to examine the interaction between these polymers and lipid molecules in the stratum corneum in order to establish whether EPDME-specific changes in the structural ordering of lipids might account for the improvement of barrier function. METHODS: We used two-photon microscopy to evaluate the effects of EPDME, PEG, and PPG on the structural ordering of lipids in an epidermal-equivalent model in terms of the fluorescence changes of Laurdan, a fluorescent dye that responds to changes of membrane fluidity. The generalized polarization (GP) value, a parameter that reflects lipid ordering, was measured at various depths from the surface of the stratum corneum. RESULTS: EPDME increased the GP value to a depth of about 3 µm from the surface, indicating that lipid ordering was increased in this region, while PEG and PPG of the same molecular weight had no effect. Diffusion of Lucifer yellow into the epidermis was reduced after application of EPDME, indicating that the barrier function was improved. CONCLUSION: These results support the view that EPDME improves barrier function by increasing the ordering of lipid structures in the stratum corneum. The methodology described here could be useful for screening new compounds that would improve the structural ordering of lipids.

Live imaging of alterations in cellular morphology and organelles during cornification using an epidermal equivalent model.

The stratum corneum plays a crucial role in epidermal barrier function. Various changes occur in granular cells at the uppermost stratum granulosum during cornification. To understand the temporal details of this process, we visualized the cell shape and organelles of cornifying keratinocytes in a living human epidermal equivalent model. Three-dimensional time-lapse imaging with a two-photon microscope revealed that the granular cells did not simply flatten but first temporarily expanded in thickness just before flattening during cornification. Moreover, before expansion, intracellular vesicles abruptly stopped moving, and mitochondria were depolarized. When mitochondrial morphology and quantity were assessed, granular cells with fewer, mostly punctate mitochondria tended to transition to corneocytes. Several minutes after flattening, DNA leakage from the nucleus was visualized. We also observed extension of the cell-flattening time induced by the suppression of filaggrin expression. Overall, we successfully visualized the time-course of cornification, which describes temporal relationships between alterations in the transition from granular cells to corneocytes.

Can simple physicochemical studies predict the effects of molecules on epidermal water-impermeable barrier function?

Improvement of the water-impermeable barrier function of skin is clinically important, because barrier abnormality is associated with various skin diseases, such as psoriasis or atopic dermatitis. We have shown that topical application of fatty acids, sex hormones, hexoses, polyols and polymers influences barrier homeostasis, but the effects are highly dependent on even small variations of molecular structure. Moreover, the effects appear within one hour after application and thus are likely to be non-genomic (physicochemical) phenomena. Secretion of lipids from lamellar bodies into the intercellular space between stratum granulosum and stratum corneum is a crucial step in epidermal water-impermeable barrier homeostasis, especially at the early stage of barrier recovery after damage, and phase transition of the lipid lamellar structure in the epidermis is an important part of this process. Therefore, we evaluated the effects of the above molecules on the physicochemical properties of phospholipid monolayers and liposomes as models of the lamellar body membrane and cell membrane. Molecules that influenced the barrier recovery process also altered the stability of liposomes and the air-water surface pressure of phospholipid monolayers. Studies using attenuated total reflection Fourier-transform infrared spectroscopy (ATR FT-IR), differential scanning calorimetry (DSC) and 13 C nuclear magnetic resonance (NMR) spectrometry suggested that molecules influencing barrier recovery interact specifically with phospholipids. The idea that molecules interacting with phospholipids may influence barrier homeostasis should open up new approaches to the treatment of a variety of skin diseases.

Modulation of lipid fluidity likely contributes to the fructose/xylitol-induced acceleration of epidermal permeability barrier recovery.

We previously showed that topical application of hexoses such as fructose accelerates barrier recovery after disruption. We also showed that various hexoses and polyols interact with phospholipid and alter the phase transition temperature. Thus, we hypothesized that the improvement of barrier recovery by hexoses and polyols might be related to the interaction with phospholipid. Here, we tested this idea by examining the effects of xylitol (a component of some skin-care products) and fructose on lipid dynamics in an epidermal-equivalent model at the single-cell level by means of two-photon microscopy after staining with Laurdan, a fluorescent dye sensitive to the physical properties of its membrane environment. First, we confirmed that topical application of xylitol aqueous solution on tape-stripped human skin accelerated barrier recovery. Then, we examined changes of lipid fluidity in the epidermal-equivalent model after application of water or an aqueous solution of xylitol or fructose. Application of xylitol and/or fructose increased the lipid fluidity in the uppermost part of the stratum granulosum layer, compared to treatment with water alone, and accelerated the exocytosis of lamellar bodies to the intercellular domain between stratum corneum and stratum granulosum. Our results support the idea that the improvement of epidermal barrier homeostasis upon topical application of xylitol or fructose is due to increased lipid fluidity in the uppermost layer of the stratum granulosum, which enables accelerated release of lipid from the stratum granulosum, thereby improving the lamellar structure and accelerating epidermal permeability barrier recovery.