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Journal of Lipid Research, Vol 24, 120-130, Copyright © 1983 by Lipid Research, Inc.
MA Lampe, AL Burlingame, J Whitney, ML Williams, BE Brown, E Roitman and PM Elias
The lipids of mammalian stratum corneum are known to be important
regulators of skin permeability. Since the human stratum corneum displays
remarkable regional variations in skin permeability, we assessed the total
lipid concentration, the distribution of all major lipid species, and the
fatty acid composition in Bligh-Dyer extracts from four skin sites
(abdomen, leg, face, and sole) that are known to display widely disparate
permeability. Statistically significant differences in lipid weight were
found at the four sites that were inversely proportional to their known
permeability. In all four sites, among the polar lipids, the stratum
corneum contained negligible phospholipids, but substantially more
cholesterol sulfate (1-7%) than previously appreciated. As in the stratum
corneum from other mammals, the bulk of the lipids consisted of neutral
(60-80%) and sphingolipids (15-35%). Of the neutral lipids, free sterols
(4- to 5-times greater than esterified sterols), free fatty acids,
triglycerides, and highly nonpolar species (n-alkanes and squalene)
predominated. n-Alkanes, which were present in greater quantities than
previously appreciated, comprised a homologous series of odd- and
even-chained compounds ranging from C19 to C34. The sphingolipids comprised
over 80% ceramides vs. lesser quantities of glycosphingolipids. In all four
sites, the sphingolipids were the major repository of long-chain, saturated
fatty acids. The neutral lipid:sphingolipid ratio generally was
proportional to the known permeability of each site: higher neutral lipids
and lower sphingolipids generally were associated with superior barrier
properties. These studies provide: 1) the first detailed, quantitative
analysis of human stratum corneum lipids and 2) information about the
variability in lipid composition at four skin sites with known differences
in permeability. The latter results suggest that variations in neutral
lipids, rather than sphingolipids, may underlie local variations in skin
permeability.
ARTICLES
Human stratum corneum lipids: characterization and regional variations
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