Hydrogel-based conductive materials for smart wearable devices have attracted increasing
attention due to their excellent flexibility, versatility, and outstanding biocompatibility. This …

Conductive hydrogels can be prepared by incorporating various conductive materials into
polymeric network hydrogels. In recent years, conductive hydrogels have been developed …

Inspired by the human skin, electronic skins (e‐skins) composed of various flexible sensors,
such as strain sensor, pressure sensor, shear force sensor, temperature sensor, and humility …

To date, ionic conducting hydrogel attracts tremendous attention as an alternative to the
conventional rigid metallic conductors in fabricating flexible devices, owing to their intrinsic …

Flexible wearable devices have achieved remarkable applications in health monitoring
because of the advantages of multisignal collecting and real-time wireless transmission of …

The complexity of application environment stimulates the development of wearable devices
based on functional hydrogels. Among all the promising performances, self-healing and self …

Conductive hydrogels have drawn significant attention in the field of stretchable/wearable
sensors due to their intrinsic stretchability, tunable conductivity, biocompatibility, multistimuli …

Conductive hydrogels are emerging as an appealing material platform for flexible electronic
devices owing to their attractive mechanical flexibility and conductive properties. However …

The application of wearable sensors in domains related to healthcare systems, human
motion detection, robotics, and human–machine interactions has attracted significant …

Conductive hydrogels are attracting tremendous interest in the field of flexible and wearable
soft strain sensors because of their great potential in electronic skins, and personalized …