Dry Skin and the Environment

J. Fluhr
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引用次数: 11

Abstract

On the other hand, an increase in environmental humidity also induced abnormalities in permeability homeostasis [9] . In this issue of Exogenous Dermatology, environmental factors on dry skin are discussed by fi ve distinguished experts (or their groups) in this fi eld: Wertz (this issue) gives an integrated overview of the epidermal barrier function and their regional variations. His contribution focuses on lipids of the SC and the relationship of SC hydration and barrier function. Furthermore, the pathophysiological aspects of hyperproliferative epidermal conditions with a decreased SC water content, increased transepidermal water loss and an altered skin surface are discussed. Rawlings (this issue) reports about water and SC biomechanics. The state of SC hydration depends on the supplied water from deeper parts of the skin, the evaporation rate at the surface and the water-binding capacity of the SC. The desquamation and proliferation process is highly dependent on both enzyme activity and the integrity of the intercellular lipid matrix. At high humidity, the epidermal synthesis of lipids and natural moisturizing factor is switched off. The reduction in natural moisturizing factor levels together with lipid composition induces changes in the water content in the different layers of the SC. Subsequently this leads to local secretion of proinfl ammatory cytokines that can, either directly or indiIt is well documented that climatic changes infl uence skin conditions, e.g. epidermal structure and functions. A dry environment for example has an impact on epidermal parameters [1] . Improvement of the stratum corneum (SC) homeostasis can ameliorate skin damage induced by barrier disruption in a dry environment [2] . Furthermore, a dry environment directly increases the epidermal level of pro-infl ammatory cytokines [3] . Thus, epidermal homeostasis is very vulnerable when exposed to dry environmental conditions. Histamine H 1 and H 2 receptor antagonists accelerate skin barrier repair and prevent epidermal hyperplasia induced by barrier disruption in a dry environment [4] . Furthermore, a dry environment increases the epidermal mast cell number and histamine content [5] . A recent publication showed the modulation of gene expression induced in human epidermis by environmental stress [6] : the authors could show a general overexpression of MRP8 and MRP14 (both members of the S100 family) as markers for stressed skin being involved in epidermal repair pathways. Loeffl er and Happle [7] reported an increased susceptibility against irritant patch tests during cold climatic conditions during winter and spring. The climatic impact on epidermal functions could be prevented with the application of a moisturizing cream [8] . The daily treatment is effective in improving mild subclinical infl ammation that is induced on the facial skin by the winter environment [8] . Published online: June 30, 2005
干燥的皮肤和环境
另一方面,环境湿度的增加也会引起透气性稳态的异常。在本期《外源性皮肤病学》中,五位杰出的专家(或他们的团队)讨论了干燥皮肤的环境因素:Wertz(本期)对表皮屏障功能及其区域差异进行了综合概述。他的贡献集中在SC的脂质和SC水合作用和屏障功能的关系。此外,还讨论了SC含水量降低、经皮失水增加和皮肤表面改变的超增生性表皮疾病的病理生理方面。罗林斯(本期)报道了水和SC生物力学。SC的水合状态取决于皮肤深层提供的水、表面的蒸发速率和SC的水结合能力。脱皮和增殖过程高度依赖于酶活性和细胞间脂质基质的完整性。在高湿度下,表皮脂质和天然保湿因子的合成被关闭。天然保湿因子水平的降低以及脂质组成导致SC不同层含水量的变化。随后,这导致局部分泌促炎性细胞因子,这可以直接或间接地影响皮肤状况,例如表皮结构和功能。例如,干燥的环境对表皮参数[1]有影响。改善角质层(SC)稳态可以改善干燥环境中屏障破坏引起的皮肤损伤。此外,干燥的环境直接增加了促炎性细胞因子[3]的表皮水平。因此,当暴露在干燥的环境条件下,表皮的稳态是非常脆弱的。组胺h1和h2受体拮抗剂加速皮肤屏障修复,防止干燥环境中屏障破坏引起的表皮增生。此外,干燥的环境会增加表皮肥大细胞的数量和组胺含量。最近发表的一篇文章显示了环境胁迫诱导的人类表皮基因表达的调节:作者可以证明MRP8和MRP14(都是S100家族的成员)普遍过表达,作为应激皮肤参与表皮修复途径的标记。Loeffl er和apple[7]报告说,在冬季和春季寒冷的气候条件下,对刺激性斑贴试验的敏感性增加。使用保湿霜[8]可以防止气候对表皮功能的影响。日常治疗可有效改善冬季环境对面部皮肤引起的轻度亚临床炎症。出版日期:2005年6月30日
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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