“…With the advancement in intelligent technology, smart wearable devices have penetrated our daily life in diverse kinds of forms such as glass, watch, shoes, and wristband, which can precisely track the wearer’s body exercises, physiological health, temperature, and heart rate in real-time. − However, as the paramount component of wearable electronic devices, the conventional conductive sensor is normally constructed by integrating a conductive filter (e.g., metal, carbon materials, and semiconductors) into a flexible substrate to form the conductive network, which causes discomfort when wearing and is challenging to achieve accurate signals. , Therefore, the flexibility and higher sensitivity of sensors are the current research focus. In addition, the continuous advancement in personalized demands has put forward higher standards and requirements for the application of flexible sensors in different conditions. , Moreover, to meet the requirement of fast development of next-generation flexible sensors, the combination of high conductivity, excellent mechanical performance (such as toughness, stretchability, and strength), great antifatigue capability, and self-adhesiveness in an electronic sensor are highly desirable. , Hence, it is of paramount importance but remains a great challenge to fabricate flexible sensors with multifunctionality and eminent performance stability. , …”