Soft bioelectronic devices can be interfaced with anatomically curved organs, such as the
heart, brain and skin, to provide continuous analysis of physiological information. However …

Gallium-based liquid metal (LM) exhibits exceptional properties such as high conductivity
and biocompatibility, rendering it highly valuable for the development of conformal …

Muscle contraction and relaxation inherently contains valuable information crucial for
monitoring physical states, rehabilitation, and injury prevention. However, the majority of …

The rapid development of wearable and implantable electronics has enabled the real-time
transmission of electrophysiological signals in situ, thus allowing the precise monitoring and …

Monitoring and analyzing the state of human muscle is becoming a focus of research in
exercise and medicine. Traditional devices (EMG, MRI, X-ray, etc.) cannot provide long-term …

Skin‐interfaced electronics have emerged as a promising frontier in personalized
healthcare. However, existing skin‐interfaced patches often struggle to simultaneously …

Flexible and stretchable electronic devices are subject to failure because of vulnerable
circuit interconnections. We develop a low-voltage (1.5 to 4.5 V) and rapid (as low as 5 s) …

Flexible sensors simultaneously with property of hydrogel-like low modulus/room
temperature ultra-fast self-healing and with elastomer-like durability/environmental stability …

Robotic skins that integrate artificial tactile sensing elements can substantially complement
the perception dimension of social robots, presenting an indispensable part in human‐robot …

Bioelectronics is an exciting field that bridges the gap between physiological activities and
external electronic devices, striving for high resolution, high conformability, scalability, and …