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‐...

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Bibliographic Details
Published in:Skin research and technology 2020-03, Vol.26 (2), p.255-262
Main Authors: Maruyama, Yuko, Kamata, Hayato, Watanabe, Seiei, Kita, Rio, Shinyashiki, Naoki, Yagihara, Shin
Format: Article
Language:English
Subjects:
Acetone
Adult
Body parts
Body Water - chemistry
Destructive testing
Diameters
dielectric measurement
Dielectric Spectroscopy - instrumentation
Dielectric Spectroscopy - methods
Dielectrics
Electric fields
Electrodes
Epidermis
Equipment Design
Evaluation
Female
human skin
Humans
In vivo methods and tests
Male
Moisture content
Original
Penetration depth
Polytetrafluoroethylene
Reflectometry
Skin
Skin - chemistry
Skin Physiological Phenomena
Spectroscopy
Spectrum analysis
Thickness measurement
Water chemistry
Water content
Water depth
Young Adult
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Summary: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.
ISSN:0909-752X
1600-0846
DOI:10.1111/srt.12788