The present study has 2 aims. First, the method of spectral reflectance was used to measure evaporation rates of thin (∼25-300 μm) films of neat liquid volatile organic chemicals exposed to a well-regulated wind speed u. Gas-phase evaporation mass transfer coefficient (kevap) measurements of 10 chemicals, 9 of which were measured at similar u, are predicted (slope of log-log data = 1.01; intercept = 0.08; R2 = 0.996) by a previously proposed mass transfer correlation. For one chemical, isoamyl alcohol, the dependence of kevap on u0.52 was measured, in support of the predicted exponent value of ½. Second, measured kevap of nicotine was used as an input in analytical models based on diffusion theory to estimate the absorbed fraction (Fabs) of a small dose (5 μL/cm2) applied to human epidermis in vitro. The measured Fabs was 0.062 ± 0.023. Model-estimated values are 0.066 and 0.115. Spectral reflectance is a precise method of measuring kevap of liquid chemicals, and the data are well described by a simple gas-phase mass transfer coefficient. For nicotine under the single exposure condition measured herein, Fabs is well-predicted from a theoretical model that requires knowledge of kevap, maximal dermal flux, and membrane lag time.
Keywords: diffusion; in vitro model(s); mathematical model(s); passive diffusion; percutaneous; skin; solvent evaporation; transdermal.
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