Electric-field penetration depth and dielectric spectroscopy observations of human skin.

BACKGROUND: The dynamic behavior of water molecules remains an important subject for understanding human skin. The change in the dynamics of water molecules from those in bulk water can be effectively observed by dielectric spectroscopy. To study water in the human skin in vivo, non-invasive and non-destructive measurements are essential. Since many unknowns remain from previous research, in this report we employ a two-layer dielectric model to evaluate the penetration depth of the electric field and use the results in measurements on human skin. MATERIALS AND METHODS: We used open-ended coaxial probes with different diameters to perform time-domain reflectometry (TDR) measurements for an acetone-Teflon double-layer model and for human skin from various parts of the body. RESULTS: The electric-field penetration depth obtained from model measurements increases with the increasing outer diameter of open-ended coaxial electrodes. For skin measurements, the relaxation strength corresponding to the water content shows a clear dependence on the epidermal thickness of the measured body parts. CONCLUSION: We determined the depth distribution of the water content of skin from results of dielectric measurements obtained using electrodes with various electric-field penetration depths. We found exponential decays with the thickness of the epidermis of each body part for several examinees. This study suggests an effective method for detailed evaluations of human skin.

Universal Behavior of Fractal Water Structures Observed in Various Gelation Mechanisms of Polymer Gels, Supramolecular Gels, and Cement Gels.

So far, it has been difficult to directly compare diverse characteristic gelation mechanisms over different length and time scales. This paper presents a universal water structure analysis of several gels with different structures and gelation mechanisms including polymer gels, supramolecular gels composed of surfactant micelles, and cement gels. The spatial distribution of water molecules was analyzed at molecular level from a diagram of the relaxation times and their distribution parameters (τ-ß diagrams) with our database of the 10 GHz process for a variety of aqueous systems. Polymer gels with volume phase transition showed a small decrease in the fractal dimension of the hydrogen bond network (HBN) with gelation. In supramolecular gels with rod micelle precursor with amphipathic molecules, both the elongation of the micelles and their cross-linking caused a reduction in the fractal dimension. Such a reduction was also found in cement gels. These results suggest that the HBN inevitably breaks at each length scale with relative increase in steric hindrance due to cross-linking, resulting in the fragmentation of collective structures of water molecules. The universal analysis using τ-ß diagrams presented here has broad applicability as a method to characterize diverse gel structures and evaluate gelation processes.

Factors affecting levels of ferulic acid, ethyl ferulate and taste-active pyroglutamyl peptides in sake.

Factors affecting ferulic acid, ethyl ferulate and taste-active pyroglutamyl (pGlu) peptides levels in sake were analyzed using small-scale sake brewing tests on eighteen rice samples with differing cultivar variety, cropped year and area, and polishing rate. Ferulic acid concentration in sake was highly positively correlated with its content in rice (r = 0.782**, double asterisk indicates 1% significance level), feruloylesterase (FE) activity (r = 0.804**) and feruloylated saccharide forming activity (FSFA) (r = 0.619**) in the rice koji. The results suggested that ferulic acid in rice induced FE activity and FSFA, and these two enzymes accelerated the formation of ferulic acid in sake mash. The concentration of bitter-tasting peptides in sake was highly positively correlated with crude protein content in rice (r = 0.786**), and negatively correlated with acid carboxypeptidase (ACP) activity to (pGlu)LFGPNVNPWH (r = -0.612**), fermentation length (r = -0.820**), and pyroglutamyl leucine ((pGlu)L) concentration in sake (r = -0.502*; 5% significance level). The observation suggested that bitter-tasting peptides are initially formed in sake mash in accordance with protein content in rice, and are then hydrolyzed to smaller peptides, such as (pGlu)L. An ACP specific to the hydrolysis of bitter-tasting peptides was suggested by the observation that ACP activity to (pGlu)LFGPNVNPWH was significantly correlated (-0.612**) to their formation whereas an ACP to Cbz-Glu-Tyr was not (r = 0.220). It was suggested that (pGlu) oligo-peptide ethyl esters were formed during the decomposition of bitter-tasting peptides to which the ACP to (pGlu)LFGPNVNPWH might contribute.

Formation of Guaiacol by Spoilage Bacteria from Vanillic Acid, a Product of Rice Koji Cultivation, in Japanese Sake Brewing.

The formation of guaiacol, a potent phenolic off-odor compound in the Japanese sake brewing process, was investigated. Eight rice koji samples were analyzed, and one contained guaiacol and 4-vinylguaiacol (4-VG) at extraordinarily high levels: 374 and 2433 µg/kg dry mass koji, respectively. All samples contained ferulic and vanillic acids at concentrations of mg/kg dry mass koji. Guaiacol forming microorganisms were isolated from four rice koji samples. They were identified as Bacillus subtilis, B. amyloliquefaciens/subtilis, and Staphylococcus gallinarum using 16S rRNA gene sequence. These spoilage bacteria convert vanillic acid to guaiacol and ferulic acid to 4-VG. However, they convert very little ferulic acid or 4-VG to guaiacol. Nine strains of koji fungi tested produced vanillic acid at the mg/kg dry mass koji level after cultivation. These results indicated that spoilage bacteria form guaiacol from vanillic acid, which is a product of koji cultivation in the sake brewing process.