What question did this study set out to answer?

The aim is to develop a high-performance conductive hydrogel for flexible electronic sensors.

May 8, 2026

Pearl-Inspired Gelatin/Chitosan-Reinforced Conductive Hydrogel with High Strength, Freeze Resistance, and Stability for Flexible Wearable Sensors

Key Points

The aim is to develop a high-performance conductive hydrogel for flexible electronic sensors.
Evaluated Young's modulus and electrical conductivity of the hydrogel.
Assessed freeze resistance, water retention, and long-term stability.
Tested sensor response to various human motion activities.
Achieved a Young's modulus of 0.69 MPa and electrical conductivity of 0.83 S/m.
Demonstrated a linear response over a strain range of 0-500% with outstanding cyclic stability for 2000 cycles.
Displayed a rapid dynamic response time of 336 ms for real-time monitoring.

Abstract

, a Young's modulus of 0.69 MPa, and an electrical conductivity of 0.83 S/m, along with excellent freeze resistance, water retention, and long-term stability. As a flexible sensor, the hydrogel demonstrates a linear response over a broad strain range (0-500%), outstanding cyclic stability (2000 cycles), and a rapid dynamic response (336 ms). Even under frigid conditions, it enables real-time, precise monitoring of human motions such as finger, wrist, elbow, and knee joint movements, as well as gesture changes, and enables the accurate capture of dynamic writing trajectories. This work presents a novel and effective strategy for designing high-performance resilient hydrogels, offering a promising route for developing flexible electronic sensors with high strength and stability.

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Pearl-Inspired Gelatin/Chitosan-Reinforced Conductive Hydrogel with High Strength, Freeze Resistance, and Stability for Flexible Wearable Sensors

Key Points

Abstract

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