Using electron microscopy, we investigated the effect of (i) a dilute surfactant and of water alone on the ultrastructure of stratum corneum lipids in pig skin exposed in vitro at 46 degrees C, and (ii) of water alone on human skin exposed in vivo at ambient temperature. For pig skin, the surfactant sodium dodecyl sulfate disrupts stratum corneum intercellular lamellar bilayers, leading to bilayer delamination and "roll-up" in a water milieu after 1 h, extensive bilayer disruption after 6 h, and nearly complete dissociation of corneocytes after 24 h. Corneodesmosomes show progressive degradation with exposure time. Water alone also disrupts the stratum corneum, but with a slower onset. Alterations in intercellular lamellar bilayers, but not intercellular lamellar bilayer roll-up, are detected after 2 h. Intercellular lamellar bilayer roll-up occurs after 6 h. Extensive dissociation of corneocytes occurs after 24 h of water exposure. Unlike sodium dodecyl sulfate, water exposure results in the formation of amorphous intercellular lipid. Corneodesmosome degradation parallels intercellular lamellar bilayer disruption; calcium appears to offer some protection. Similar disruption of intercellular lamellar bilayers occurs in human skin in vivo at ambient temperature. Our studies show that water can directly disrupt the barrier lipids and are consistent with surfactant-induced intercellular lamellar bilayer disruption being due at least in part to the deleterious action of water. Intercellular lamellar bilayer disruption by water would be expected to enhance permeability and susceptibility to irritants; accordingly, increased attention should be given to the potential dangers of prolonged water contact. For common in vitro procedures, such as skin permeation studies or isolation of stratum corneum sheets, exposure to water should also be minimized.
The mechanism of bismuth's bactericidal activity against Helicobacter pylori was investigated using transmission electron microscopy (TEM) and analytical electron microscopy (AEM); time-kill kinetic methods evaluated the effect of excess divalent cations. TEM analysis of untreated H. pylori revealed a normal morphology. In contrast, H. pylori exposed to bismuth salts had swollen, distorted cells with membrane-cell wall blebbing and a cytoplasm containing electron-dense, sometimes crystalline aggregates. By AEM, swollen cells contained bismuth at the cell periphery, whereas bacillary forms contained cytoplasmic bismuth localizations. Time-kill studies showed that the bactericidal activity of bismuth could be prevented by pretreatment with divalent cations. The effects of bismuth salts on the glycocalyces-cell walls of H. pylori with reversal of bactericidal activity by divalent cations are identical to those produced by other polycationic agents on various gram-negative bacilli. We conclude that disruption of the glycocalyces-cell walls of H. pylori is one mechanism of action for bismuth salts.
Water content is an important parameter in many biological and medical investigations, such as volume regulation in cell biology, osmotic adaptation in physiology, and cell injury in pathology. Of existing methodologies for quantitative water measurements, analytical electron microscopy offers unique opportunities for absolute quantitation of water in subcellular volumes within any region of a tissue. Water quantitation by AEM analysis is typically done by measuring the x-ray continuum intensity in a freeze-dried specimen and comparing the continuum with that from a standard of known water content using the Hall or Rick approach. However, this AEM data is obtained at great cost in time, usually by stationary probe measurements. Often large numbers of analyses must be averaged to obtain meaningful results. Mass loss (etching) or mass gain (contamination) during analysis seriously complicates the water measurement. We have developed an alternative technique that eliminates or minimizes these problems. Our technique is similar to the Rick procedure, and similar assumptions apply.
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