Advanced epidermal electronic devices, capable of real‐time monitoring of physical,
physiological, and biochemical signals and administering appropriate therapeutics, are …

With the rapid development of wearable electronic skin technology, flexible strain sensors
have shown great application prospects in the fields of human motion and physiological …

Flexible tactile sensors show promise for artificial intelligence applications due to their
biological adaptability and rapid signal perception. Triboelectric sensors enable active …

Non‐invasive electrodes for recording and delivering electric signals to the human body are
crucial for health monitoring and rehabilitation applications. However, high‐fidelity signal …

Tattoo-like electronics heralds the amalgamation of electronics with the human body,
representing a breakthrough in healthcare by empowering continuous monitoring and …

Collecting electrophysiological (EP) signals (eg, electrocardiogram (ECG), electromyogram
(EMG)) during exercises is crucial for feedback of cardiac health and muscle injuries …

Bedridden patients are at high‐pressure injuries risk, and timely turning or moving a
bedridden patient is crucial to release localized pressure and reduce pressure injury risk …

Abstract Electronic tattoos (E-tattoos), imparting electrical functions to skin imperceptibly, are
attractive for future biomedical engineering applications. However, it is still challenging to …

Tattoo sensors, known for the ultrathin and highly flexible nature and excellent adhesion to
human skin, have attracted significant attention in recent years. In this study, a flexible …

Bioelectronics based on regular hydrogels containing conductive components severely
suffer from inferior structural compatibility, impaired signal accuracy, and fatigue failure …