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A Wearable Molecularly Imprinted Electrochemical Sensor for Cortisol Stable Monitoring in Sweat

Yitao Chen, Zidong He, Yuanzhao Wu, Xinyu Bai, Yuancheng Li, Weiwei Yang, Yiwei Liu, Run‐Wei Li

2025Biosensors35 citationsDOIOpen Access PDF

Abstract

Cortisol, a steroid hormone, is closely associated with human mental stress. The rapid, real-time, and continuous detection of cortisol using wearable devices offers a promising approach for individual mental health. These devices must exhibit high sensitivity and long-term stability to ensure reliable performance. This study developed a wearable electrochemical sensor based on molecularly imprinted polymer (MIP) technology for real-time and dynamic monitoring of cortisol in sweat. A flexible gold (Au) electrode with interfacial hydrophilic treatment was employed to construct a highly stable electrode. The integration of a silk fibroin/polyvinylidene fluoride (SF/PVDF) composite membrane facilitates directional sweat transport, while liquid metal bonding enhances electrode flexibility and mechanical anti-delamination capability. The sensor exhibits an ultrawide detection range (0.1 pM to 5 μM), high selectivity (over 100-fold against interferents such as glucose and lactic acid), and long-term stability (less than 3.76% signal attenuation over 120 cycles). Additionally, a gradient modulus design was implemented to mitigate mechanical deformation interference under wearable conditions. As a flexible wearable device for cortisol monitoring in human sweat, the sensor's response closely aligns with the diurnal cortisol rhythm, offering a highly sensitive and interference-resistant wearable solution for mental health monitoring and advancing personalized dynamic assessment of stress-related disorders.

Topics & Concepts

Wearable computerMaterials scienceMolecularly imprinted polymerElectrochemical gas sensorElectrodeNanotechnologyComputer scienceElectrochemistryChemistryEmbedded systemSelectivityBiochemistryCatalysisPhysical chemistryAdvanced Sensor and Energy Harvesting MaterialsTranscranial Magnetic Stimulation StudiesConducting polymers and applications