Flexible tactile sensors capable of measuring mechanical stimuli via physical contact have
attracted significant attention in the field of human‐interactive systems. The utilization of …

Efforts to design devices emulating complex cognitive abilities and response processes of
biological systems have long been a coveted goal. Recent advancements in flexible …

Transition metal carbides/nitrides (MXenes) show great potential for preparing wearable,
flexible multifunctional e‐textiles due to the exceptional electrical and mechanical properties …

Reproducing ion channel–based neural functions with artificial fluidic systems has long
been an aspirational goal for both neuromorphic computing and biomedical applications. In …

Neuromorphic computing memristors are attractive to construct low-power-consumption
electronic textiles due to the intrinsic interwoven architecture and promising applications in …

The effective mimicry of neurons is key to the development of neuromorphic electronics.
However, artificial neurons are not typically capable of operating in biological environments …

Neuromorphic perception systems inspired by biology have tremendous potential in
efficiently processing multi-sensory signals from the physical world, but a highly efficient …

Developing e-skins that can perceive stimuli with high sensitivity and material recognition
functionality at low cost is of great importance to intelligent perception. Here, a hybrid e-skin …

Brain–machine interfaces typically rely on electrophysiological signals to interpret and
transmit neurological information. In biological systems, however, neurotransmitters are …

Skin is the largest organ, with the functionalities of protection, regulation, and sensation. The
emulation of human skin via flexible and stretchable electronics gives rise to electronic skin …