PEER-REVIEWED PUBLICATION

2025

Systematic Benchmarking of a Noise-Tolerant Conductive Hydrogel Electrode for Epidermal Bioelectronics

Alsaafeen N, Ziogas I, et al.

Advanced Science

Khalifa University, Foundation for Research and Technology - Hellas (FORTH - IESL), Khawaja Medical Technologies GmbH

RESEARCH SUMMARY

This study systematically benchmarks a crosslinker-free PEDOT:PSS-based conductive hydrogel electrode designed to overcome signal instability, motion artifacts, and impedance variability common in epidermal bioelectronic interfaces. Two formulations—PPSCF and PPHG—were fabricated using a gelatin–chitosan–glycerol matrix to promote mixed ionic–electronic conduction and enhance skin conformity. Through physicochemical characterization, dielectric spectroscopy, and long-term stability testing, the optimized PPHG hydrogel demonstrated superior electrochemical capacitance, high mechanical compliance, and stable performance under diverse environmental and physiological conditions. Human-subject testing across 39 participants revealed that PPHG consistently improved surface electrophysiology recordings (ECG, EEG, EMG, EOG), yielding enhanced signal-to-noise ratio, reduced motion artifacts, and improved extraction of clinically relevant features compared to Ag/AgCl electrodes. The work establishes a sustainable, reusable hydrogel electrode with robust electromechanical coupling suited for next-generation wearable biosensing.

Mechanical durability testing of the conductive hydrogel electrodes was performed using a CellScale BioTester 5000. Dumbbell-shaped specimens were subjected to controlled cyclic tensile loading at 10% and 50% strain for 100 cycles. The BioTester 5000 provided precise force–displacement data to quantify elastic recovery, hysteresis, and structural integrity under repeated deformation. These measurements validated that the hydrogel’s conductivity and mechanical robustness were maintained under physiologically relevant strains, supporting its suitability for long-term epidermal bioelectronic applications.

AUTHORS

Nazmi Alsaafeen, Ioannis Ziogas, Shirina Alsaedi, Mouza Alshehhi, Shahd Almheiri, Adil Rehman, Khulood Al Shehhi, Hani Saleh, Ahsan Khandoker, Charalampos Pitsalidis, Antoun Khawaja, Anna-Maria Pappa.

PUBLICATION DETAILS

JOURNAL

Advanced Science

YEAR

2025

INSTITUTIONS

Khalifa University, Foundation for Research and Technology - Hellas (FORTH - IESL), Khawaja Medical Technologies GmbH

COUNTRIES

Germany, Greece, United Arab Emirates

INSTRUMENT USED

BioTester

TESTING METHODS

Fatigue TestingTensile Testing

RESEARCH APPLICATIONS

Hydrogel Mechanical TestingPolymers and Elastomers TestingWearable Bioelectronics

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