TY - GEN
T1 - Development of interdigital electrodes for detecting skin impedance
AU - Liang, Guomin
AU - Han, Xiao
AU - Li, Qin
AU - Zou, Ting
N1 - Publisher Copyright:
© 2025 Copyright held by the owner/author(s).
PY - 2026/5/12
Y1 - 2026/5/12
N2 - Skin electrical impedance represents a critical parameter for non-invasive health monitoring, though conventional fixed spacing electrodes exhibit limited sensitivity in detecting localized impedance variations. To address this constraint, this study introduces interdigital electrodes (IDEs) for high-sensitivity localized detection. A systematic evaluation combining finite element simulations and in vivo murine experiments was conducted to assess their performance. Simulation results demonstrated that when local dielectric properties of the skin were altered, the IDE model achieved a relative impedance change of 11.73%, significantly surpassing the 2.45% observed with fixed spacing electrodes. Experimental data further validated this superior sensitivity: within the 20 Hz-5 kHz frequency range, IDEs captured an impedance variation ratio of approximately 96%, markedly higher than the 40% recorded using fixed spacing electrodes. These consistent findings confirm the distinct advantage of IDEs in detecting localized skin impedance changes, offering valuable theoretical and practical foundations for developing high-precision impedance detection systems applicable to wound monitoring, early lesion diagnosis, and related fields.
AB - Skin electrical impedance represents a critical parameter for non-invasive health monitoring, though conventional fixed spacing electrodes exhibit limited sensitivity in detecting localized impedance variations. To address this constraint, this study introduces interdigital electrodes (IDEs) for high-sensitivity localized detection. A systematic evaluation combining finite element simulations and in vivo murine experiments was conducted to assess their performance. Simulation results demonstrated that when local dielectric properties of the skin were altered, the IDE model achieved a relative impedance change of 11.73%, significantly surpassing the 2.45% observed with fixed spacing electrodes. Experimental data further validated this superior sensitivity: within the 20 Hz-5 kHz frequency range, IDEs captured an impedance variation ratio of approximately 96%, markedly higher than the 40% recorded using fixed spacing electrodes. These consistent findings confirm the distinct advantage of IDEs in detecting localized skin impedance changes, offering valuable theoretical and practical foundations for developing high-precision impedance detection systems applicable to wound monitoring, early lesion diagnosis, and related fields.
KW - COMSOL simulation
KW - Interdigital electrode
KW - Skin impedance
UR - https://www.scopus.com/pages/publications/105039922748
U2 - 10.1145/3789938.3789959
DO - 10.1145/3789938.3789959
M3 - Conference contribution
AN - SCOPUS:105039922748
T3 - ICCBB 2025 - 2025 9th International Conference on Computational Biology and Bioinformatics
SP - 154
EP - 159
BT - ICCBB 2025 - 2025 9th International Conference on Computational Biology and Bioinformatics
PB - Association for Computing Machinery, Inc
T2 - 2025 9th International Conference on Computational Biology and Bioinformatics, ICCBB 2025
Y2 - 21 December 2025 through 23 December 2025
ER -