Previous reports suggested that ion gradients of ions such as calcium and magnesium in the epidermis play a crucial part in skin barrier homeostasis. We hypothesized that external electric potential affects the ionic gradient and skin barrier homeostasis. We demonstrated here that application of a negative electric potential (0.50 V) on hairless mice skin accelerated the barrier recovery approximately 60.7% of the original level within 1 h compared with control (37.5%) after barrier disruption by acetone treatment. Even after the application of a negative potential, the skin showed accelerated repair for 6 h. On the contrary, the skin that was applied a positive potential for 1 h showed a significant delay in barrier recovery (25.3%) than the control. Ultrastructural studies by electron microscopy suggested that the extent of lamellar body exocytosis into the stratum corneum/stratum granulosum interface increased under a negative potential. Magnesium and calcium ion concentrations in the upper epidermis were relatively higher in the negative portion than in the portion where the positive potential was applied. Topical application of these ions on mice skin also accelerated the barrier recovery. These results suggest that the external electric potential affects the ionic gradients in the epidermis and also influences the skin barrier homeostasis.
We previously demonstrated that the skin surface electric potential, which has been long recognized as a parameter of emotional or physiological state, is generated by epidermal keratinocytes and is strongly associated with the ion concentration gradient in the epidermis. Thus, at temperatures below the threshold of sweating, the potential provides a measure of the epidermal ion concentration gradient, which in turn is related to epidermal homeostasis and pathology. In the present study, we established a new, non-invasive method to measure skin surface electric potential. In healthy skin, calcium ion was localized in the uppermost epidermis and the gradation disappeared by tape stripping. Skin surface potential was also disappeared by tape stripping. Moreover, environmental humidity affected the potential, whereas temporary hydration of the stratum corneum did not affect it. These results suggest that the skin surface electric potential may be an indicator of the pathophysiology of the living layer of epidermis, and thus may be useful as a new parameter to evaluate skin condition.
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