Abstract

Regional differences in skin barrier properties are common in mammals, as some exterior surfaces are fairly impermeable and others are leakier. Neural-induced changes in skin physiology and temperature have the potential to alter skin barrier properties, but the circumstances and mechanisms are unclear. We hypothesized that increasing methylcholine (MCh) or acetylcholine (ACh) concentration would decrease the transepithelial resistance (an index of the skin barrier) measured across mouse paw pad skin jacketed at neutral skin (32°C) or internal (37°C) temperature. Additionally, we hypothesized that paw pads would have lower transepithelial resistance compared to mouse tail skin, and subjecting samples to 40°C (local cutaneous heat stress) would lower transepithelial resistance compared to paw pad skin tested at 32°C. 30 C57BL/6 mouse rear paw pads (containing sweat glands) and 7 mouse tail skins (no sweat glands) were dissected and mounted into a vertical Ussing chamber filled with Kreb’s bicarbonate buffer, gassed with 95% O₂ & 5% CO₂, and encased in a temperature jacket. Transepithelial resistance utilized a current clamp and was measured with Ag-AgCl2 electrodes placed in both epidermal and hypodermal baths during hypodermal-side-only cholinergic dosing (5 min/dose). ACh (0, 0.0833, 0.1666, 0.2499, 0.4166, 0.58323, and 0.74989 M) significantly decreased transepithelial resistance in paw pads clamped at 37°C in a dose-dependent manner. Tail skin had significantly higher transepithelial resistance than paw pad skin. However, transepithelial resistance decreased significantly with MCh (same dosing as ACh) at both skin sites. Increasing jacket temperature to 40°C did not alter the magnitude of decrease in transepithelial resistance to MCh in paw pads compared to 32°C. Transepithelial resistance observations were similar when data were expressed as absolute or relative changes to baseline. Increased ion movement in murine skin (signifying a leakier epithelium) occurred with cholinergic stimulation but not with local hyperthermia, suggesting that neural influences can suffciently affect skin function to directly alter regional skin barriers. P30ES026529 with additional support from TL1TR001997 and R25ES027684. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

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