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Analysis of impedance models of interface : skin/measuring electrodes
Języki publikacji
Abstrakty
Analiza bioimpedancyjna jest metodą rozpowszechnioną w diagnostyce medycznej, umożliwiającą strukturalną charakterystykę wybranych obszarów ciała, w tym skóry. Do wyznaczenia składowych impedancji skóry konieczne jest określenie układu zastępczego, czyli modelu tego obszaru, w postaci dwójnika zawierającego rezystory R i pojemności C. W artykule przedstawiono analizę właściwości tych układów i ich przydatności do detekcji wydzielania się potu oraz zaproponowano własny, rozbudowany model impedancyjny skóry i granicy faz: skóra/elektrody pomiarowe, obejmujący również znane z literatury schematy zastępcze, który, po optymalizacji, zostanie wykorzystany w opracowywanym systemie do oceny wysiłku fizycznego i stresu psychicznego. Podano opis matematyczny zaproponowanego impedancyjnego schematu zastępczego. Opis ten ma modułową strukturę, która jest przystosowana do analiz komputerowych.
Bioimpedance analysis is a method widely used in medical diagnostics, enabling the structural characterization of selected areas of a human body, including skin. Usually the skin structural models are based on impedance measurements that are used for determination of the electrical equivalent circuit consisting of two-terminal circuits comprising resistors R and capacitances C. The paper presents an analysis of the properties of the equivalent circuits and their suitability to detect secretion of sweat, and proposed by authors’ extended skin/measuring electrodes interface models, comprising also equivalent circuits known from the literature. This model, after optimization, will be used in the system under development to assess the physical and mental stresses. The mathematical description of the proposed model based on electrical equivalent circuits with a modular structure adapted for computer analysis is presented.
Wydawca
Rocznik
Tom
Strony
102--106
Opis fizyczny
Bibliogr. 38 poz., rys.
Twórcy
autor
- Instytut Biocybernetyki i Inżynierii Biomedycznej im. Macieja Nałęcza PAN, Warszawa
autor
- Instytut Biocybernetyki i Inżynierii Biomedycznej im. Macieja Nałęcza PAN, Warszawa
Bibliografia
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- [3] T. Uchiyama et al., Multi-frequency bioelectrical impedance analysis of skin rubor with two-electrode technique, J. of Tissue Viability, 17 (2008) 110-114.
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- [5] F. D. Coffman, S. Cohen, Impedance measurements in the biomedical sciences, Analytical Cellular Pathology 35 (2012) 363-374
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- [10] I. Bodén et al., Characterization of healthy skin using near infrared spectroscopy and skin impedance, Med Biol Eng Comput, 46 (2008) 985-995.
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- [14] E. Barsoukov, J. R. Macdonald (eds.), Impedance Spectroscopy, Theory, Experiment, and Applications, A John Wiley & Sons, Inc., Publication, New Jersey, 2005.
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- [18] F. Gómez-Aguilar et al., Frequency response of an electric equivalent circuit for a skin type system, Revista Mexicana de Ingenieria Biomédica, 32 (2011) 93-99.
- [19] S. Huclova et al., Modeling and validation of dielectric properties of human skin in the MHz region focusing on skin layer morphology and material composition, J. of Physics D: Applied Physics, 45 (2012) 025301 (17pp).
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- [31] Y. N. Kalia et al., Homogeneous transport in a heterogeneous membrane: water diffusion across human stratum corneum in vivo, Biophysical J. 71 (1996) 2692-2700.
- [32] E. Jonathan, In vivo sweat film layer thickness measured with Fourier-domain optical coherence tomography (FD-OCT), Optics and Lasers in Engineering, 46 (2008) 424-427.
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- [35] S. Gierlotka, Human body impedance in climatically bad conditions, Przegląd Elektrotechniczny, 2008, 84, nr 11, 94-98.
- [36] K. Atkins, M. Thompson, Effect of textile hygroscopicity on stratum corneum hydration, skin erythema and skin temperature during exercise and skin temperature in the presence of wind and no wind, J. Exercise Science and Fitness, 9 (2011) 100-108.
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- [38] P. Zoltowski, On the electrical capacitance of interfaces exhibiting constant phase element behavior, J. of Electroanalytical Chemistry, 443 (1998) 149-154.
Typ dokumentu
Bibliografia
Identyfikator YADDA
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