Ultrastretchable, Highly Conductive, Rapid Self-Recovery, and Antiswelling Hydrogels as Multifunctional Wearable Electronic Devices

Abstract: The development of wearable electronic devices requires stretchable, highly conductive, self-recovery, and ideally environmentally resistant sensors. Hydrogels are ideal candidates for fabricating flexible sensors due to their stretchability and unique ionic conduction pathways. However, the intrinsic incompatibility of the conductive and elastic networks in hydrogels and the high hydrophilicity of the hydrogel network led to difficulties in obtaining hydrogels with strong mechanical properties, high conductiv… Show more

“…5,6 However, most of FSDs have shortcomings such as poor fatigue resistance, single functionality, poor portability, and contradiction between mechanical strength and toughness, resulting in reduced accuracy and stability of the sensor, and greatly shortened service life. 7–9 In recent years, conductive hydrogels (CHs) have become ideal materials for manufacturing FSDs due to their excellent mechanical flexibility, conductivity, wearability, and multi-responsiveness. 10,11 However, in practical applications, hydrogel-based flexible sensors inevitably have some limitations.…”

Collagen fiber-reinforced, tough and adaptive conductive organohydrogel e-skin for multimodal sensing applications

“…5,6 However, most of FSDs have shortcomings such as poor fatigue resistance, single functionality, poor portability, and contradiction between mechanical strength and toughness, resulting in reduced accuracy and stability of the sensor, and greatly shortened service life. 7–9 In recent years, conductive hydrogels (CHs) have become ideal materials for manufacturing FSDs due to their excellent mechanical flexibility, conductivity, wearability, and multi-responsiveness. 10,11 However, in practical applications, hydrogel-based flexible sensors inevitably have some limitations.…”

Collagen fiber-reinforced, tough and adaptive conductive organohydrogel e-skin for multimodal sensing applications

“…Miniaturization and portability are major trends in the future development of flexible wearable electronic devices. 1,2 Graphene and its derivatives have wide application potential in electrode materials due to their excellent physical and chemical properties. 3–5 In recent years, researchers have employed various strategies to modify graphene-based materials to enhance their physical and chemical properties.…”

A label-free H1N1 influenza virus immunosensor based on an N-LIG/Au laser induced graphene microelectrode

Fully Physically Crosslinked PNIPAM Ionogels with High Mechanical Properties and Temperature‐Managed Adhesion Achieved by H₂O/Ionic Liquid Binary Solvents