Abstract

Wearable biosensors provide continuous, real-time physiological monitoring of biochemical markers in biofluids such as sweat, tears, saliva, and interstitial fluid. However, achieving high stretchability and stable biochemical signal monitoring remains challenging. Here, we propose a hybrid microstructure (HMS) strategy to fabricate highly stretchable multifunctional biosensors capable of detecting sweat electrolyte concentrations, pH levels, and surface electromyography (EMG) signals. By integrating a HMS, stable conductivity under large strains is ensured. Stretching tests up to 5000 cycles demonstrated the electrodes’ stretchable stability and reliability. The high-performance electrodes were used for EMG monitoring on human skin. Additionally, active materials were coated onto the stretchable electrodes to create multifunctional sweat sensors capable of monitoring pH as well as calcium, sodium, and potassium ions (Ca 2+ , Na + , K + ). The electrodes reliably maintained their functionality under 60% strain, providing new insights into the fabrication of stable, highly stretchable biosensors. • A hybrid microstructure is developed to enhance electrical stability during stretching for a high-performance electrode. • Multifunctional sensing of calcium, sodium, and potassium ions, as well as pH and electromyography signals, is achieved with hybrid microstructure electrodes, which maintain stable performance under high strains. • Real-time monitoring of multi-physiological parameters is enabled by the biosensors, advancing personalized health monitoring in wearable technology.